The present invention relates to dispensers of washing agents for washing machines, in particular household dish-washing machines, and more in particular to dispensers that are designed to be mounted on one of the walls that define a washing chamber of a dish-washing machine. The invention has been developed with particular reference to multi-dose dispensers of at least one washing agent in liquid form or semisolid (gel) form, i.e., provided with a rechargeable tank, which is able to contain an amount of the aforesaid washing agent sufficient to execute a plurality of washing programs by the dish-washer.
US2006157086 A1 discloses a dispenser device for a dish-washing machine, which comprises a multi-dose tank for a liquid washing agent and a pump housed within the door of the dish-washing machine. Extending through the wall of the door of the dish-washing machine that faces the inside of the corresponding washing chamber are a passage for recharging the tank and a nozzle for delivery of the liquid detergent, with the delivery nozzle that is connected in fluid communication with the tank and with the pump via a duct. In one embodiment, the pump is of a reversible type in order to enable flushing of the duct and prevent any possible clogging thereof.
The above solution proves complicated, far from efficient, and inconvenient to use for a user.
U.S. Pat. No. 7,845,361 B1 discloses a dispenser system for a dish-washing machine, comprising a multi-dose tank for a liquid washing agent and a piston dispensing pump that defines a dosing chamber, which is designed to receive from the tank a pre-set amount of the liquid additive, to be delivered in the course of an operating program of the dish-washing machine. The tank and the dispensing pump are mounted in a front recess of the wall of the door of the dish-washing machine that faces the inside of the corresponding washing chamber, and are coupled in a separable way via respective fluidic attachments to enable removal of the tank for the purposes of recharging. In one embodiment, housed in the front recess of the wall of the door of the dish-washing machine are two distinct tanks of the type referred to, each of which associated in a separable way to a respective piston pump of the type mentioned, where each piston pump can be driven by a corresponding solenoid actuator.
Also this solution proves complicated, far from efficient, and inconvenient to use for a user, also in view of risks of undesired exit of a washing agent from the corresponding tank, when the latter is handled.
EP 2138088 A1 discloses a dispenser device for dish-washing machines having a dispenser body, defined in the front of which is a compartment that is able to contain a tablet of a washing agent. The compartment is provided with a sliding hatch, via which the compartment itself can be closed after the tablet has been inserted. Operatively associated to the hatch is an electrically controlled release system to bring about opening of the hatch in the course of a washing program. The hatch has a substantially grid-shaped lateral extension so that, when the hatch slides into its open position, the lateral extension comes to be located in front of the compartment, to withhold the tablet inside it during continuation of the washing program.
Also this solution proves complicated, far from efficient, and inconvenient to use for a user, also in view of risks of undesired exit of a washing agent from the corresponding tank, when the latter is handled.
EP0691101 A1 discloses an integrated dispenser device for a dish-washing machine, having a dispenser body, which is to be partially inserted into an opening of the inner side of a tiltable door of the dish-washing machine, i.e., the side that is to face the inside of the corresponding washing chamber. The dispenser body defines at the front a housing, hinged in which is a multi-dose containing tank for a powder detergent, mounted for being displaceable between an inclined position of partial extraction, which enables filling of the containing tank, and an insertion position, where the front of the containing tank is substantially aligned with the front of the dispenser body. The containing tank is provided at the front with a transparent window, which enables a visual check on the amount of powder detergent present.
With solutions of this sort, checking of the content of the tank is awkward, both on account of possible steaming-up of the transparent window and on account of the fact that, since the dispenser is mounted on a tiltable door, visual check on the level can be carried out practically only with the door open, and hence substantially set horizontal: with such a plane of lie of the dispenser, however, the information that can be gleaned through the window may not be significant.
In addition, more in general, in solutions where a removable or displaceable tank is provided (for example, as described in the aforementioned U.S. Pat. No. 7,845,361 B1 and EP0691101), level checking is entrusted entirely to the user, who is thus altogether responsible for carrying out a visual check on the amount of washing agent contained in the tank.
Furthermore, in solutions of the type described in the aforementioned document U.S. Pat. No. 7,845,361 B1, possible errors of loading or topping-up, with a liquid washing agent, of the corresponding tank are not infrequent; in particular, it may happen that detergent is put into a tank that should contain a rinsing additive, or conversely a rinsing additive is put into a tank that should contain a washing detergent. Such errors, in particular those of the second type referred to, may have consequences such as to jeopardise operation of the dispenser or of the entire dish-washer.
In its general terms, the present invention is aimed at overcoming at least one or more of the drawbacks referred to above. This and other aims still, which will emerge more clearly hereinafter, are achieved according to the present invention by a dispenser of washing agents having the characteristics specified in the annexed claims. The claims form an integral part of the technical teaching provided herein in relation to the invention.
According to a first inventive aspect, the present invention is aimed at providing a dispenser of washing agents for washing machines, in particular dish-washing machines, that is convenient to use for a user and in which check on delivery of a number of washing agents in liquid or semisolid form is both efficient and inexpensive.
According to a second inventive aspect, the present invention is aimed at providing a dispenser of washing agents for washing machines, in particular dish-washing machines, in which the risks of dispersion in the environment of a liquid or semisolid washing agent, following upon actions performed by a user on the dispenser itself, is reduced or prevented.
According to a third inventive aspect, the present invention is aimed at providing a dispenser of washing agents for washing machines, in particular dish-washing machines, in which use of detergent in tablet form is convenient for a user, and production of the dispenser is economically advantageous.
According to a fourth inventive aspect, the present invention is aimed at providing a dispenser of washing agents for washing machines, in particular dish-washing machines, in which, even in the presence of displaceable parts that are designed to contain washing agents, a user is provided with clear and efficient indications regarding the content of these movable parts, and more in general, regarding conditions that pertain to operation of the dispenser, in a simple and safe way.
According to a fifth inventive aspect, the present invention is aimed at providing a dispenser of washing agents for washing machines, in particular dish-washing machines, in which, in a simple and efficient way, the risks of error by a user in use of the dispenser are limited, in particular as regards operations of charging of washing agents.
According to a sixth inventive aspect, the present invention is aimed at providing a dispenser of washing agents for washing machines, in particular dish-washing machines, in which, even in the presence of displaceable parts that are to contain washing agents, it is possible to make available in a simple and safe way precise information regarding the content of the dispenser and/or of the aforesaid movable parts.
According to a seventh inventive aspect, the present invention is aimed at providing a dispenser of washing agents for washing machines, in particular dish-washing machines, in which, in a simple and safe way, it is possible to prevent or, if necessary, correct any malfunctioning due to errors of a user regarding use of a washing agent, and/or a to enable more efficient check on a treatment program carried out by the dish-washer on which the dispenser is installed.
Further aims, characteristics, and advantages of the invention will emerge clearly from the ensuing detailed description, with reference to the annexed drawings, which are provided purely by way of non-limiting example and in which:
Reference to “an embodiment” or “one embodiment” in the framework of the present description is intended to indicate that a particular configuration, structure, or characteristic described with reference to the embodiment is comprised in at least one embodiment. Hence, phrases such as “in an embodiment”, “in one embodiment”, “in various embodiments”, and the like that may be present in various points of this description, do not necessarily refer to one and the same embodiment. Moreover, particular conformations, structures, or characteristics defined in the framework of the present description may be combined in any adequate way in one or more embodiments, even different from the ones represented. The reference numbers and spatial references (such as “upper”, “lower”, “top”, “bottom”, etc.) used herein are provided merely for convenience and hence do not define the sphere of protection or the scope of the embodiments. Where not otherwise specified, in the description and in the ensuing claims, the term “detergent” is intended to designate a detergent substance to be used during washing steps in a strict sense of an operating program of a dish-washing machine, i.e., steps aimed mainly at removal of dirt from the dishes, whereas the term “additive” is intended to designate an accessory liquid or semisolid substance, used in steps different from the washing steps or in purposely provided programs, such as a rinsing additive (or brightener), or a perfuming substance, or a water-softening substance, or a hygienizing substance; the term “washing agent” is intended to designate indifferently the detergent substance or the accessory substance. Where not otherwise specified, the term “liquid”, when associated to terms such as “detergent”, “additive”, “washing agent” (single and plural), is intended in any case to designate—in addition to a liquid substance—also a semiliquid/semisolid substance, such as a gel.
In the figures, the same reference numbers are used to designate elements that are similar or technically equivalent to one another. In various figures, the representation of some components is omitted, when these are not necessary for understanding specific characteristics described with reference to the aforesaid figures; for this reason, for example, in various figures connection leads that belong to electrical parts of the dispenser, in particular to its sensors and actuators, are not represented.
Shown schematically in
The dish-washing machine 1 has a cabinet or structure 2 defining inside it a washtub or washing chamber 3. Designated as a whole by 4 is a front door of the dish-washing machine 1, associated to the cabinet 2 so that it can be moved between an open position and a closed position. In various embodiments, such as the one exemplified, the door 4 can be moved angularly between the aforesaid positions, preferably but not necessarily about a substantially horizontal axis. The dish-washing machine 1 could, however, be of some other type, for example, with at least one door that can translate or slide on purposely provided guides, for example, as in FR-A-2.674.426 A, or else with a rack for containing the dishes configured as a sliding tray, the front wall of which forms a door of the machine, for example, as in WO9833426 A.
The inner face of the door 4 includes a movable tub wall 5 (also known as “counter-door”), having an outer side 5a that constitutes the front surface of the tub 3. The tub 3 is also delimited by a plurality of fixed tub walls, one of which designated by 6, which typically comprise two side walls, a rear wall, an upper wall or roof, and a lower wall or bottom. In various embodiments, the walls that delimit the tub 1 are plate-like walls, made at least in part of sheet metal, such as stainless steel. Not excluded, however, from the scope of the invention is the case of walls made at least in part of plastic material, for example, via injection moulding of a thermoplastic material.
In various embodiments, mounted on one of the walls that delimit the tub 3—here the wall 5—is a dispenser of washing agents, designated as a whole by 10 and represented only schematically in
Installation of the dispenser 10 on the wall 5 of the door 4 is to be understood as being provided merely by way of example in so far as, in other embodiments, the dispenser 10 can be installed on any of the walls of the tub 3, including a stationary wall, such as the side wall designated by 6. Consequently, what is described hereinafter regarding installation of the dispenser 10 on the wall 5 is to be understood as exemplifying also installation of the dispenser 10 on any other wall of the tub 3, in particular a fixed vertical wall thereof. The side 5a defined herein as “outer” side of the mounting wall 5 of the dispenser 10 (whether this is a movable wall or a fixed wall) indicates the surface of the wall that faces the inside of the tub 3, whereas the side defined herein as “inner” side (hereinafter designated by 5b) indicates the surface of the wall itself opposite to the outer side 5a, for example, corresponding to the inner side of a gap of a wall of the machine.
In various embodiments, the dispenser, i.e., its body as a whole, comprises at least two main functional parts, amongst which at least one first removable part that is configured so that it can be coupled in a releasable way to at least one second part, which is fixed on the mounting wall 5, in particular at the aforesaid through opening. Each of the two main parts of the dispenser body in turn comprises a number of elements, described hereinafter. In
The removable dispenser part and the fixed dispenser part, which form as a whole the dispenser body, are designated, respectively, by 100 and 200 in
With reference in particular to
It should be noted that the terms “removable part” or “tank”, when referred to the component designated as a whole by 100, are understood to designate a rechargeable component that stably equips the dispenser, constituting an essential part thereof, and that is provided with at least one loading passage provided with a respective removable closing means to enable a user to top it up periodically. The body part 100 does not hence represent a disposable component, such as a cartridge previously filled with the washing agent in the production stage and marketed in this ready-to-use version, which typically presupposes perforation or tearing of its body for the purposes of use, and then disposal thereof when it is empty.
The hollow body 101 is preferentially made of plastic material, for example, a thermoplastic material. In various embodiments, the body 101 is made up of at least two pieces or parts sealed together, for example, a front piece 1011 and a rear piece 1012. The body pieces 1011 and 1012 may, for example, be moulded using thermoplastic material and sealed together at corresponding interface surfaces, for example, welded using a hot-blade system.
In various embodiments, identified in the hollow body 101 are an upper portion 101a, that is as a whole deeper (dimension Z) and shorter (dimension Y), and a lower portion 101b, that is as a whole thinner (dimension Z) and taller (dimension Y). The two portions 101a and 101b may have the same width (dimension X). The fact that the portion of the hollow body 101 having a larger surface (i.e., the lower portion 101b) is thinner enables limitation of the front dimensions of the dispenser 10, in particular when it is on the door 4 of the dish-washing machine. In this way, for example, the dispenser 10 can advantageously be mounted in a position of the tub wall 5 such that—with the door closed—only the lower portion 101b will come to be located in front of a dish rack housed in the tub 3, thus preventing the need to provide shorter racks and hence ones that have a smaller loading capacity. The presence of a deeper upper portion 101a may prove convenient to facilitate definition of a loading passage for topping-up of the corresponding tank with the washing agent, with a corresponding closing element that is operable by a user, such as a plug or a hatch.
Both of the portions 101a and 101b are hollow, at least for a substantial part thereof. Preferentially, the maximum depth (dimension Z) of the hollow body 101 in each area thereof is smaller than its width (dimension X) and its height (dimension Y). Once again preferentially, the height (dimension Y) of the hollow body 101 is smaller than its width (dimension X). Obviously, these relative dimensions could be different, for example, according to the loading requirements and/or the position of installation of the dispenser.
As has been said, in various embodiments, the at least one tank R1 and/or R2 of the removable dispenser part 100 has a respective loading passage, i.e., a respective passage for filling the respective tank, associated to which is a suitable closing element that can be opened and closed by a user, such as a plug or, as in the examples illustrated, a hatch. It is possible to provide also a plug in an area subtended by a movable hatch.
With reference in particular to
Once again with reference to the example of
In the example, each hatch 1041, 1042 is hinged, in a lower region thereof (with reference to the dimension Y), to the hollow body 101, but this does not constitute an essential characteristic: at least one hatch could be hinged in a side region thereof, or else it could be a hatch of a type that slides in a direction transverse to the corresponding loading passage, according to known technique in the field of dispensers for dish-washing machines. Designated by 104c in
Preferentially, when the hatch operates directly as closing element, between the hatch itself and the corresponding loading passage sealing means are provided, which are able to co-operate when the hatch is in the closed position. In the example of
Once again preferentially, defined in the front of the hollow body 101 is a receiving seat, designated by 103c in
In various embodiments, the dispenser is mounted on a tiltable door of the dish-washing machine, and associated to the at least one tank is a system for taking in the respective washing agent that bases its own operation on the movements of the door. Such an intake system is preferably associated to the tank of smaller capacity R2, which is in any case able to contain an amount of washing agent sufficient for execution of a number of treatment programs performed by the dish-washing machine 1. In this perspective, in various embodiments defined in the tank R2 is a sub-chamber or intake volume, which is able to contain at least one amount of the washing agent sufficient to execute a single treatment program. The intake system comprises, or has associated to it, valve means, which include, in particular, an open/close element operating at the corresponding outlet passage of the washing agent. The aforesaid valve means can be controlled to enable outflow of at least one dose of washing agent coming from the intake volume towards the inside of the washtub 3 of the dish-washing machine 1, through the outlet passage referred to previously. In various embodiments, the intake system is devised so that, when the door 4 of the dish-washing machine 1 is brought into the substantially horizontal open position, the intake volume is filled by a corresponding part of the content of the tank R2, and when the door 4 is subsequently brought into the substantially vertical closed position, the intake volume is able to withhold the corresponding content, at least until activation of the aforesaid valve means.
Partially represented in
Defined within the hollow body 101 is a first set of walls, designated as a whole by 106 (see also
Likewise defined within the hollow body 101 is a second set of walls, designated as a whole by 107 (see also
The volume R2a is configured for being filled with the aforesaid fraction of the washing agent of the tank R2 when the plane of lie of the dispenser 10 is substantially horizontal (i.e., when the door 4 of the dish-washing machine 1 is open) and withholding the fraction itself when the plane of lie of the dispenser 10 is substantially vertical (i.e., when the door 4 of the dish-washing machine is closed), for the purposes of subsequent delivery, as described hereinafter. As has been mentioned, in the example represented, the level of filling of the intake volume is defined by an upper edge 107a of the second set of walls, which functions as overflow.
In the subsequent
The next
Also visible in
With reference in particular to
There may be associated to the floating body 110 an element 110b for excitation of an electrical detector, set on the outside of the hollow body 101, in particular mounted on the fixed dispenser part 200 in a position to which the floating body 110 will come to correspond when the removable dispenser part 100 is mounted on the fixed dispenser part 200. Such a detector is designated by RD only in
When an amount of washing agent WA higher than a pre-set minimum level is present in the tank R2, the floating body 101 remains in its raised position, consequently exciting (or not exciting) the corresponding external electrical detector RD. Instead, when the amount of the washing agent WA drops below the aforesaid pre-set minimum level, the floating body 110 is brought to assume the corresponding lowered position, consequently no longer exciting (or starting to excite) the corresponding external electrical detector RD. The information on the level thus generated by the level sensor 110-RD may, for example, be used for activating a warning system, aimed at alerting a user of the dish-washing machine 1 to the need for topping-up of the tank R2 with the washing agent WA. After such a topping-up, of course, the floating body 110 will return to the respective raised position, thus causing the warning signal to cease.
Of course, the principle of detection of the displacement of the floating body 110 may be different from the one based upon detection of a magnetic field; for example, it may be a detection of an inductive or optical type (for example, the wall of the hollow body 101 that separates the floating body 110 from the corresponding external electrical detector may be transparent to optical radiation, at least in an area corresponding to the floating body, and the wall of the front of the fixed dispenser part 200 located behind which is a detector RD of an optical type is likewise transparent or has a transparent window, at least in an area corresponding to the detector).
It is clear that a floating system of the above sort can be used also for the tank R1. Measurement of the level in the tank R1 and/or R2 could be made using other detection techniques, such as a system based upon the use of an optoelectronic sensor, including a light emitter and a light receiver. In the case of a dispenser according to possible embodiments of the invention, such an optoelectronic sensor can be set on the fixed dispenser part 200 (for example, in a position corresponding to a transparent window provided in the front of the part 200) so that, when the removable dispenser part 100 is in the respective operating position, the optoelectronic sensor is in a position facing an optical prism defined by a transparent wall of the hollow body 101 (for example, its rear wall) that delimits a side of the corresponding tank R1 and/or R2. For instance, when the prism is immersed in the liquid washing agent, the light beam emitted by the emitter is in part reflected and in part refracted at the inclined walls of the prism immersed in the liquid, not reaching the receiver, or reaching it with limited intensity: in this way, the presence of the liquid washing agent at a level corresponding to the position of the sensor can be inferred. Instead, in the case where the prism is not immersed in the liquid washing agent, the light beam will be substantially completely reflected at the inclined walls of the prism, reaching the receiver, or reaching it with high intensity: in this way, the absence of the liquid washing agent at a level corresponding to the position of the sensor can be inferred.
In various embodiments, in which the removable dispenser part is provided with at least one hatch, the dispenser comprises at least one corresponding latching/releasing device, which can be switched manually between a latching position and releasing position, to enable displacement of the hatch itself between the closed position and the open position. For this purpose, there may also be a spring or similar elastic element associated to the hatch, according to a technique in itself known, operative for urging the hatch itself towards the respective open position.
In the example of
In various embodiments, as in the example of
Preferentially, the operable portion 105a defines, or has associated to it, a latching element 105b, which is able to co-operate with the corresponding hatch in order to keep it in the closed position. In the example illustrated, for this purpose, the body of the hatch 1041 and/or 1042 defines a seat 104b, in an area thereof opposite to the hinging side, where the engagement element 105b engages when the corresponding hatch is closed (see
In various embodiments, the at least one latching/releasing device 1051 and/or 1052 basically consists of a lever element, which is hinged to turn about a respective axis that substantially extends in the depth direction (dimension Z) of the dispenser 10. As may be seen, for example, in
In various embodiments, the lever element 1051 and/or 1052 is substantially in the form of a first-class lever, and hence also has another lever arm 105e, which extends at the part generally opposite to the lever arm 105d. The function of this possible further lever arm 105e will be explained hereinafter in relation to a locking/unlocking arrangement that can equip the dispenser according to various embodiments.
In various embodiments, defined in the front of the dispenser body is a housing, configured to receive a tablet including one or more washing agents, and hence also tablets of the type known as “two-in-one” or “three-in-one”. The term “tablet” is intended to designate both tablets in solid form and tablets—also known as “tabs” or “pods”—of the type in which one or more washing agents in liquid or semisolid form are enclosed in a casing consisting of a water-soluble film (typically a polymer, such as polyvinyl acetate—PVA).
The housing referred to is directly exposed as a whole, at the front of the dispenser, i.e., without hatches or similar movable closing elements. The housing has a front containment portion that is directly exposed at the front of the dispenser body, and has a bottom that extends in a direction transverse to the height dimension Y and that has at least one drainage passage. Preferentially, the at least one drainage passage is defined between the front containment portion and the bottom of the housing. Once again preferentially, the front containment portion has a perforated structure, i.e., defining one or more openings, for example, a grid structure.
In various embodiments, the containment portion defines a front of the housing and, preferentially, also at least part of at least one of two opposite lateral sides of the housing. Preferentially, the housing has an upper opening, i.e., generally opposite to the bottom, configured to enable insertion of a tablet in the housing itself. This facilitates considerably loading and dissolving of a tablet.
Such a housing is designated by 300 in
As may be appreciated, a tablet T can be inserted in the housing 300 prior to execution of a washing program. In the course of this program, part of the water sprayed into the tub 3 of the dish-washing machine 1, for example, by means of a known rotating-sprinkler system, can reach the housing 300, favouring dissolving of the tablet T and outflow of the corresponding mixture of water and washing agent towards the inside of the tub 3. This effect is made possible by the presence of the at least one drainage passage 303, defined between the front containment portion 301 and the bottom 302.
The effect of dissolving the tablet T and pouring the washing agent into the tub is further favoured by the presence of the front containment portion 301 provided with openings, preferably comprising an alternation of full and empty spaces, such as a substantially grid-like structure, as in the case exemplified. The presence of one or more openings at the front of the housing 300 facilitates the passage of the water sprayed at inlet and of the water-detergent mixture at outlet. One or more jets of water can also arrive with a certain energy at the opening or openings of the portion 301, hitting directly part of the tablet T with a certain energy, which favours dissolving thereof. In various embodiments, a rotating sprinkler of the dish-washing machine 1 can be pre-arranged for directing at least one jet of water to a height corresponding to that of the housing 300 (for this purpose, a thrust nozzle of the sprinkler could, for example, be used). Obviously, it is also possible to equip the hydraulic system of the dish-washing machine with a purposely provided fixed nozzle in order to direct a jet of water towards the housing 300.
Of course, the jets of water can strike the tablet T directly via the upper opening or at the top of the containment portion 301, when this forms a sort of “parapet” for the tablet itself. In other words, the front containment portion can have a height (dimension Y) even smaller than the overall height of the housing 300 or of the tablets of various shapes that it can receive, and in particular a height sufficient to withhold effectively a tablet T within the housing 300 notwithstanding the typical vibrations of the dish-washing machine 1 during operation and notwithstanding the energy of the possible incident jets of water. The withholding function is performed by the portion 301 also in the course of the movement of closing and engagement of the door 3 of the dish-washing machine 1, when the dispenser 10 is mounted on the wall 5.
The presence of one or more drainage passages 303 between the containment portion and the bottom 302 is likewise aimed at enabling outflow of the water and/or of the mixture of water and washing agent from the housing 300 in order to prevent any stagnation inside the housing itself. For this purpose, in various preferential embodiments, the bottom 302 of the housing 300 extends generally inclined downwards from its back towards its front (see also
The bottom 302 is preferably defined by a non-perforated surface of the dispenser body. In the bottom 302 there may possibly be defined reliefs, which extend in the dimension Y for localized resting of the tablet T, and/or recesses, which extend in the dimension Z in order to obtain drainage channels. The bottom 302 itself could have a structure with one or more through openings or drainage passages: in embodiments of this sort, the bottom 302 may hence be in the form of a substantially cantilever wall, and possibly, the front of the hollow body 101 may be shaped so as to define a sort of chute underneath a bottom wall of this sort in order to favour outflow of the mixture of water and washing agent into the tub 3.
In various embodiments, the containment portion 301 defines at least one front of the housing 300. In various preferential embodiments, the containment portion 301 defines at least part of one of two opposite lateral sides of the housing. In the example illustrated, the portion 301 defines both the front and part of both of the lateral sides of the housing, such a part being designated by 304 in
At least one part of the two opposite sides of the housing 300 can be defined by respective non-perforated surfaces of the dispenser body, i.e., of the hollow body 101, in the example. In the example, these non-perforated lateral surfaces are designated by 305 in
Preferentially, the housing is defined integrally by a part of the dispenser body 10, here the removable dispenser part 100, i.e., its hollow body 101. However, in possible variants, the housing may be at least in part defined by walls or a structure associated to the dispenser body 10, such as a perforated or grid-like structure moulded separately and then fixed to the dispenser body 10, for example, via slotting, hooking, or welding.
In various preferential embodiments, the perforated structure of the front containment portion 301 (and/or of the bottom 302) is formed by one or more transverse parts (i.e., ones that extend according to the dimension X) and/or by one or more upright parts (i.e., ones that extend according to the dimension Y). In the case where both transverse parts and upright parts are provided, these can be connected together or cross over one another. This type of embodiment makes it easier to produce the housing 300 via moulding of the dispenser body, at the same time making it possible to obtain a robust structure distinguished by sufficiently wide empty areas, preferably a substantially grid-like structure.
The aforesaid transverse and upright parts—some of which are designated in
Obviously, the front containment portion could have a structure different from the one exemplified, without prejudice to its function of withholding the tablet T within the housing and facilitating passage of the water and outflow of the mixture of water and washing agent. In possible variant embodiments, the front containment portion, preferably comprising at least part of at least one of the lateral sides of the housing, is partially obtained via moulding of plastic material, and subsequently associated or welded to the corresponding part of the dispenser body in which the remaining part of the housing is defined.
Once again preferentially, the housing 300 is defined in an upper region of the dispenser body, here the removable dispenser part 100, i.e., its hollow body 101, in particular with the corresponding upper opening for loading the tablet T closer to the upper edge (with reference to the dimension Y) of the dispenser body; however, the housing 300 could also be defined in a lower region of the dispenser body 10.
If at the front of the dispenser body two loading openings 103 are provided, with corresponding closing elements, such as the hatches 1041, 1042 of the case exemplified, the housing 300 is preferentially defined in an intermediate position between them, and in any case in a position such as not to constitute a hindrance to their displacements; however, the housing 300 could also be defined in a lateral region of the dispenser body 10.
Of course, the shape and position of the housing 300, as well as the shape of the tablet T, can vary from what is illustrated by way of example. In general terms, the housing will have dimensions such as to be able to receive and effectively withhold tablets of various shapes and dimensions, as are available on the market, without necessarily involving a pre-set direction of introduction. Indicatively, the housing 300 may have a useful width (dimension X) comprised between 50 and 60 mm, a useful depth (dimension Z) comprised between 20 and 30 mm, and a height (dimension Y) of the grid structure 301 comprised between 30 and 40 mm.
The presence of the housing 300 enables use of tablets T in combination with the dispenser 10, without, however, having to equip the latter with a specific compartment closed by a hatch with associated thereto a corresponding automatic opening system, as occurs, instead, in traditional dispensers for dish-washing machines, where a compartment for containing a dose of a washing agent in powder form, provided with a hatch of its own having associated thereto an electrically controlled opening system has to be used to contain the tablet.
As has already been mentioned, in various embodiments, the at least one tank R1 and/or R2 provided in the removable dispenser part 100 has a respective outlet, defined at the back of the hollow body 101.
Visible in
In various embodiments, the back of the removable dispenser part 100, i.e., of the hollow body 101, is shaped so as to be able to couple with, or receive, at least a corresponding portion of the front of the fixed dispenser part 200. In addition and/or as an alternative, the front of the fixed dispenser part 200 can be shaped so as to be able to couple with, or receive, at least a corresponding portion of the back of the removable dispenser part 100.
For instance, with reference once again to
The rear wall 111 of the hollow body 101 can be conveniently shaped to house at least partially a component of the fixed dispenser part that is particularly cumbersome in the depth dimension Z. For instance, once again with reference to
In the rear wall 111 of the hollow body 101 there may be defined one or more further seats or recesses suitable for receiving corresponding parts of the front of the fixed dispenser part 200. For instance, once again with reference to
In various embodiments, two shaped lateral seats 117a-117b are provided, in particular in substantially opposite diametral positions of the peripheral surface 114b of the recess 114, each of these seats preferentially comprising two appropriately shaped different areas 117a and 117b.
The seats 117a-117b are designed to receive and enable movement of respective angularly movable engagement elements (designated, for example, by 220c in
Designated by 118 is a lower shaped seat or recess, which is designed to receive and enable angular movement of an element that is manually operable (designated by 220d in
Other seats or recesses that extend from the peripheral surface 114b of the recess 114 as far as the lower edge of the hollow body 101 may be provided, in possible embodiments, for example, for housing partially a duct for delivery of a washing agent (such as the stretch of tube designated by 403c1 in
It will be appreciated in any case that, irrespective of the conformation chosen for the interface walls between the removable part 100 and the fixed part 200, operation of the dispenser 10 in the course of a treatment program does not imply any movement of the removable part 100, which is hence coupled in a stationary position on the fixed part 200.
The fixed dispenser part 200 is visible in
With initial reference to
With reference, in particular, to
In various embodiments, in the mounted condition, a front portion of the main body 201, designated as a whole by 203 in
In various embodiments, extending forwards from the bottom wall 201a is a further hollow projection, designated by 204. In the non-limiting example illustrated, this further projection 204 is designed for coupling with the recess 115 (
In various embodiments, associated to the dispenser are at least one of a signalling arrangement and a locking/unlocking arrangement, possible embodiments of which will be described hereinafter: in various embodiments, at least one first functional element of such an arrangement is mounted on the fixed dispenser part and is designed to co-operate with at least one second functional element mounted on the removable dispenser part. In these embodiments, the at least one first functional element is accessible in the front area of the fixed dispenser part so that it can be operatively coupled to, or uncoupled from, the at least one second functional element. The front portion of the fixed dispenser part can be shaped for supporting and/or guiding and/or positioning an aforesaid first functional element.
For this purpose, in various embodiments, defined in the front portion 203 is at least one positioning and/or guiding formation 205, preferably formed integrally with the main body 201. Provided in the example of
Once again with reference to
Once again with particular reference to
In various embodiments, the dispenser has a dispensing arrangement for the washing agent contained in a tank of the removable dispenser part, comprising a pump that is preferably mounted on the fixed dispenser part. In various embodiments of this sort, at least part of the pump is set within a corresponding housing defined at the front of the fixed dispenser part. In various preferential embodiments, at least part of this housing extends towards the inside of the washtub 3; i.e., it extends beyond a plane identified by the mounting wall 5 of the dispenser 10. In this way, the housing, and hence at least part of the pump, can be located on the outside of the door 3 of the dish-washing machine 1 or in any case in an easily accessible position, which proves useful, for example, for the purposes of maintenance/repair/cleaning.
In the example represented in
The housing 214 is preferentially closed by a corresponding removable lid, designated by 215, for example, in
More in general, in various embodiments, at least part of the pump is mounted or accessible at a front portion of the fixed dispenser part, which in the example is represented by the front projecting portion 203 (as has been seen, the portion 203 can be received in the corresponding seat 114 defined in the back of the removable dispenser part 100).
In various embodiments, the part of peripheral wall 201b2 of the main body 201, which extends behind the flange 201c and is to be inserted through the corresponding through opening of the mounting wall 5, is pre-arranged for coupling with at least one retention element for fixing the fixed dispenser part 200 to the wall itself. With reference in particular to the example of
The bottom wall 201a and the peripheral wall 201b1-201b1 of the main body 201 define a cavity, designated as a whole by C, for example, in
In various embodiments, the dispenser comprises an arrangement operable by a user to cause coupling and uncoupling of the removable dispenser part to/from the fixed dispenser part. In various embodiments, the coupling/uncoupling arrangement comprises at least one element that, albeit mounted on the fixed dispenser part, is operable in the front area of the dispenser, i.e., its part that is designed to project towards the inside of the washtub of the machine 1.
In various embodiments, the aforesaid arrangement includes a movable coupling/uncoupling member. With reference, in particular, to
As may be seen in
In various embodiments, the rotating member 220 has at least two coupling elements 220c, in particular in the form of wings, preferably in opposite diametral positions, which project in a radial direction, preferably starting from the peripheral wall 220a. In various embodiments, radially projecting from the rotating member 220, in particular from its flange 220b if envisaged, is a manually operable element, like a lever, designated by 220d. Preferably, the operable element 220d extends downwards (with reference to the dimension Y) substantially at its bottom dead centre, at an angular distance of approximately 90° with respect to each coupling element 220c. Once again preferentially, the element 220d has a length and conformation such that it can be operated from the front of the dispenser 10 even when the removable dispenser part 100 is coupled on the fixed dispenser part 200 (see, for example,
In various embodiments, the member 220 has one or more undercuts or recesses in order to prevent, in the course of its angular displacement, possible interference with one or more corresponding fixed elements of the main body part 201. These recesses can extend on the peripheral wall 220a and/or on the flange 220b.
For instance, with reference to
Once again with reference to
Exemplified in
In this coupled condition, as represented in
As shown in
It will be appreciated that, starting from the condition of
In various preferential embodiments, the movements for coupling and uncoupling the removable dispenser part and the fixed dispenser part occur in a substantially linear direction, in particular in the dimension of depth Z of the dispenser. In these embodiments, a coupling/uncoupling arrangement of the type exemplified is particularly advantageous in view of its simplicity.
It should be noted in any case that the coupling/uncoupling arrangement operating between the parts 100 and 200 of the dispenser 10 may be different from the one exemplified, according to modalities that will appear clear to the person skilled in the field. It is pointed out, for example, that a mechanism with bayonet coupling could have an opposite configuration with respect to the one exemplified, i.e., with a rotating member functionally similar to the one designated by 220 that is mounted on the back of the movable dispenser body part 100 and with the respective coupling seats defined at the front of the fixed dispenser part. In other embodiments, the coupling/uncoupling arrangement operating between the parts 100 and 200 could be based upon the use of at least one linearly movable coupling/uncoupling member, instead of an angularly movable one, for example, comprising a slider.
As has been seen, in various embodiments the removable dispenser part includes at least one tank, having a respective outlet in a lower part thereof, at the back of the hollow body, which is to face the front of the fixed dispenser part, and with the outlet that can be coupled in a separable way to a corresponding inlet that is at the front of the fixed dispenser part. In embodiments of this sort, the inlet is connected in fluid communication with a corresponding dispensing arrangement, configured to deliver dosed amounts of the washing agent coming from the corresponding tank. In particularly advantageous embodiments of this sort, mounted on the hollow body is at least one retention valve, at the outlet of the tank, which is configured to assume a respective open position following upon coupling between the outlet and the inlet and to assume a respective closed position following upon uncoupling between the outlet and the inlet. The retention valve is hence a valve that automatically switches from the open position to the closed position when the movable dispenser part is removed from the fixed dispenser part, and switches from the closed position to the open position when the movable dispenser part is coupled to the fixed dispenser part. In this way, it is possible to prevent undesired leakages of the washing agent when the removable dispenser part is removed.
In various embodiments, such as the ones exemplified in the figures, the hollow body defines two tanks, each with an outlet of its own, and with two corresponding inlets on the fixed dispenser part: in these cases, one said retention valve can be mounted at each outlet.
The concept, with reference to the examples so far described, is illustrated schematically in
The tubular arrangement of the outlets 112 and 123 and the inlets 210 and 211 is preferably such as to facilitate a respective seal, for example, via respective sealing elements, in particular in annular form, where the aforesaid seal could be of an axial type or of a radial type. For instance, for a seal of an axial type there could be provided an annular sealing element operating between the head of each outlet and a contrast wall in the corresponding inlet, whereas in the case of a seal of a radial type there could be provided an annular sealing element operating between the tubular wall of the outlet and the tubular wall of the corresponding inlet. Preferably, the outlets 112 and 123 and the inlets 210 and 211 have a circular section, i.e., a substantially cylindrical shape, to which there can be associated respective circular annular sealing elements, for example, in the form of an O-ring; however, the tubular shape of the outlets and the inlets could have a different section (for example, polygonal), but preferably with rounded corners.
The aforesaid first and second retention valves are visible only partially in
The retention valves 2301 and 2302 are each configured to assume a respective open position following upon coupling between the outlets 112 and 113, on one side, and the inlets 210 and 211, on the other side, and to assume a respective closed position following upon uncoupling between the outlets 112 and 113, on one side, and the inlets 210 and 211, on the other side. In the example, the non-return valves 2301 and 2302 bring about automatic closing and/or opening of the outlets 112 and 113 of the tanks R1 and R2: in the case of further tanks, further retention valves can be provided on the respective outlets.
A possible structure of the retention valves 2301 and 2302 is visible in
In the example, each valve 2301 and 2302 comprises a valve member 231 that is inserted at least partially within the corresponding tubular outlet part 112a or 113a and is urged by an elastic element 232, in particular a spring, towards the closed position of the outlet itself. Preferentially, the spring 232 extends in the corresponding tank R1 or R2 and has a first end bearing upon an inner surface of the tank itself, opposite to the corresponding tubular outlet part 112a or 113a; possibly, within the tank there can be defined a resting formation for the first end of the spring 232, as exemplified for the valve 2302.
The valve member 231 has a first portion 233 generally opposite to the spring 232, which extends axially through the corresponding tubular outlet part 112a or 113a and defines an actuation end 233a of the valve member 230. Preferentially, the first portion 233 of the member 231 has a series of radial wings (not designated by any reference number, but clearly visible, for example, in
The valve member 231 is provided with sealing means, which are able to interact with the corresponding tubular outlet part 112a or 113a to bring about opening or closing thereof. In the example, for this purpose, the valve member 231 defines in its part inside the respective tank R1 or R2 a flange 234, projecting radially outwards. In the example, mounted on the side of the flange 234 facing the corresponding outlet 112 or 113 is a seal gasket, designated by 235, preferably a sealing ring, which has a diameter greater than the internal diameter of the corresponding outlet, and which is able to provide a front or axial seal with respect to the area of the inner surface of the tank R1 or R2 that surrounds the mouth of the outlet itself.
In the example, the member 231 of the non-return valve 2302 has a second portion 236, which extends axially from the flange 234, in the direction opposite to the first portion 233, on which a part of the corresponding spring 232 can be conveniently fitted, and consequently guided, the second end of the spring preferably bearing upon the side of the flange opposite to the corresponding gasket 235. Once again with reference to the example, the flange 234 of the member 231 defines, on its side opposite to the gasket 235, a seat—not indicated—received, and hence guided, in which is a part of the corresponding spring 232, the second end of the spring bearing upon the bottom of the seat.
Of course, the non-return valves 2301 and 2302 could also be built in a similar way. In the example, the reason for the different embodiment is that the valve 2302 is mounted in a deeper area (dimension Z) of the hollow body, i.e., of the tank R2, with the valve member 231 that is axially longer and for which it is thus advisable to envisage an axially extended portion 236 for guiding the spring 232.
The contrast surface bearing upon which is the actuation end 233a of the valve member 231 is preferably defined within the corresponding inlet 210 or 211 of the fixed dispenser part 200. For instance, this surface may be represented by the inner surface of a bottom of the inlet 210 or 211 (the bottom of the inlets 210 and 211 is visible in
As may be seen, instead, in
In various preferential embodiments, such as the ones exemplified in the figures, at least two tanks R1 and R2 are defined in a single body 101, but in possible variant embodiments, two or more tanks could be distinct from one another, i.e., each belong to a respective removable hollow body: in embodiments of this sort, the fixed dispenser part would have a structure suited accordingly in order to enable separable mechanical and fluidic coupling of the hollow bodies, using, for example, means of the type already described above. Also in solutions of this sort each hollow body could be provided with a retention valve of the type described at a corresponding outlet.
In various embodiments, the removable dispenser part includes a first tank and a second tank for a first washing agent and a second washing agent, respectively, and the dispenser includes a first dispensing arrangement and a second delivery arrangement, each configured for dispensing dosed amounts of the respective first washing agent or second washing agent, respectively. In particularly advantageous embodiments of this sort, the first dispensing arrangement comprises a peristaltic pump, which has associated to it a command arrangement of the second dispensing arrangement, the peristaltic pump being configured to be driven in a first direction to cause dispensing of first dosed amounts of the first washing agent, and to be driven in a second direction to drive the command arrangement so as to cause dispensing of second dosed amounts of the second washing agent, in particular via the second dispensing arrangement.
In the above embodiments, each dispensing arrangement preferentially comprises a dispensing duct, which extends between the outlet of the corresponding tank and a dispensing outlet for the dosed amounts of the first and second washing agents, respectively, with at least one part of the dispensing duct of the first arrangement of the peristaltic pump that is deformable.
A possible embodiment of such a peristaltic pump is visible, for example, in
The peristaltic pump is designated as a whole by 400 in
In the example, the intermediate portion of tube 403a is defined between a first portion of tube 403b, here defined as “ascending”, and a second portion of tube 403c here defined as “descending”, these two portions of tube 403b, 403c preferentially extending at least in part substantially parallel, in particular in the height dimension Y of the dispenser 10. The delivery capacity o flow-rate of the pump 400, or the amount of washing agent delivered, can be determined according to a technique in itself known, as a function of parameters such as the number of compression elements 402, the dimensions of the circumference according to which the elements are arranged, the section of passage of the deformable tube 403, the r.p.m. of the motor 404, and/or the number of revolutions of the motor 404.
In the non-limiting example described, the lower end of the ascending portion of tube 403b is coupled to a corresponding attachment 218 defined by the main body 201 of the fixed dispenser part 200, in particular within the housing 214, with the attachment 218 that is in fluid communication with the tubular inlet 210, via the opening designated by 218a, defined on the tubular wall of the aforesaid inlet (see, for example, also
The lower end of the descending portion of tube 403c defines, instead, a dispensing opening 219 for the first washing agent. In the example, the portion of tube 403c passes through the peripheral wall 201b1 of the main body 201, which is provided for this purpose with a corresponding recess, not indicated, with the stretch of tube 403c1 projecting beyond the peripheral wall that is designed to be at least partially received in the recess 118a of the back of the hollow body 101 (see
In various preferential embodiments in which a peristaltic pump of the type exemplified with reference to
In operation of the pump 400, rotation of the assembly 401 causes pumping of the first washing agent through the tube 403, with the compression elements 402 that squeeze and release progressively consecutive stretches of the portion of tube 403a, with respect to the curved contact surface 214a.
Rotation of the assembly 401 is brought about by an electric actuator having an angularly rotatable shaft, such as the motor designated as a whole by 404 in
Preferentially, the motor 404 has a drive shaft that is able to rotate according to an axis substantially parallel to an axis of rotation of the rotary assembly 401, there being provided one or more transmission members between the drive shaft and the rotating assembly. With reference to the example illustrated, the drive shaft of the motor 404 is partially visible in
Keyed to the shaft 404a of the motor 404 is a first gear wheel 405 and keyed to the shaft 401b of the rotating assembly 401 is a second gear wheel 406, the two gear wheels 405 and 406 mutually meshing so that rotation of the shaft 404a brings about a rotation of the shaft 401b, and hence of the rotating assembly 401. In the example, the wheel 405 has a diameter, and hence a number of teeth, that is smaller than the diameter, and hence the number of teeth, of the wheel 406.
As has been said, the pump 400 belongs to the arrangement for dispensing the first washing agent, which likewise includes a dispensing duct, which extends between the outlet of the corresponding tank R1 and the delivery outlet 219. In the example, the dispensing duct is defined on the fixed dispenser part 200 and includes the inlet 210, the attachment 218, and the deformable tube 403. As has been said, alternatively, the dispensing outlet of the duct could be defined by a tubular part of the main body 201, to which the outlet of the tube 403 is connected.
In various embodiments, the dispensing arrangement for the second washing agent contained in the second tank, i.e., the tank R2, includes a dosing valve, which is operative along the respective dispensing duct. With reference, in particular, to
A possible embodiment of the dosing valve 410 is exemplified in
Fitted on at least part of the portion of the member 412 that extends in the dosing chamber 411 is a sealing element 413 made of resilient material, for example, an elastomer. The sealing element 413 includes a flange portion 413a, designed to provide a seal with respect to a valve seat 411 defined within the chamber 411. An end portion 413b of the sealing element 413 coats, instead, the end of the member 412 opposite to the lid 411a in order to close in a sealed way an inlet 411e of the dosing chamber 411. This inlet is formed by a through opening of a wall that belongs to a lower hollow extension 411c of the rear part of the inlet 211 defined in the fixed dispenser part 200. The sealing element 413 is likewise shaped to define a bellows portion 413c, at the end opposite to the portion 413b. The bellows portion 413c has the purpose of providing a seal with respect to the inner side of the lid 411a (and thus prevent outlet of liquid from the opening of the lid 411 passing through which is the valve member), and at the same time enabling linear displacements of the valve member 412. Housed within the bellows portion 413c is a spring (not visible), which tends to push the member 422 into a closed position of the valve seat 411e.
As mentioned previously, also the inlet 211 preferably comprises at least one cylindrical tubular portion to enable coupling of the corresponding tubular outlet 113 of the tank R2.
The dosing chamber 411 likewise has an outlet 411f, which is defined in a peripheral wall thereof and is in fluid communication with a corresponding duct 240 present on the main body 201 of the fixed dispenser part 200. The outside of this duct 240 is partially visible in
For the purposes of dispensing of a dose of the second washing agent, the valve member 412 is made to recede countering the action of the corresponding bellows portion in such a way that the inlet 411e of the chamber 411 is opened, and at the same time the flange portion 413a of the sealing element displaces towards the corresponding valve seat 411d. In this way, a certain amount of the second washing agent can penetrate into the dosing chamber 411. Preferentially, recession of the member 412 proceeds in any case for a certain stretch even after the flange portion 413a has reached the valve seat 411d, possibly bringing about a “concertina” folding of the sealing element 413 on the valve member 412 (see, for example,
Next, the valve member 412 is allowed to return to the initial condition illustrated in
In the example, then, also the delivery duct of the second delivery arrangement is defined on the fixed dispenser part 200 and includes the inlet 211, the extension 211c, the dosing chamber 411 of the valve 410, the duct 240, as well as—preferably—the recess 213 and the recess 220g.
As explained previously, in advantageous embodiments, the peristaltic pump, or else at least one of its parts, is used to obtain delivery of both of the washing agents, and for this purpose the pump is of a reversible type; i.e., its actuator can be driven in a first direction to enable delivery of the first washing agent, and can be driven in a second, opposite, direction to enable delivery of the second washing agent, thanks to the command arrangement set between the pump and the second dispensing arrangement, which in the example includes the dosing valve 410. The command arrangement can be driven by a corresponding rotating member associated to the pump, as in the example described hereinafter, or else the command arrangement can be shaped so as to be driven by, or comprise, one of the parts of the pump 400, for example, its rotating assembly 401 and/or one of its compression elements 402 and/or one of its transmission members set between the rotating assembly 401 and the motor 404.
In various embodiments, the command arrangement comprises a transmission lever that can turn through an angle about a respective axis and is operatively associated to a valve member of a dosing valve forming part of the aforesaid second dispensing arrangement, such as the member 412 of the valve 410. This transmission lever is configured in such a way that:
According to what has been described above, the transmission lever could be driven by one of the parts of the peristaltic pump, such as its rotary assembly or one of its compression elements. However, in other embodiments, driving of the aforesaid dosing valve could be obtained by way of a member associated to the peristaltic pump, such as a cam member that defines a cam profile and that is able to be set in rotation by means by the actuator of the pump.
In the example of
Preferentially, the cam member 420 is coaxial and fixed in rotation with respect to the rotary assembly 411 of the peristaltic pump 400, even though this does not constitute an essential characteristic. The cam member 420—visible in isolation in
In various embodiments, the aforementioned transmission lever belonging to the command arrangement has a first portion that defines a cam-follower configured to interact with the cam profile of the cam member, and a second portion that is constrained or associated to the valve member of the dosing valve. Such a transmission lever is designated as a whole by 430 in
In the example, the transmission lever 430 comprises a first lever arm 430a and a second lever arm 430b, which extend in directions generally opposite to the axis of rotation identified by the pin 431. A first end portion, defining the aforesaid cam-follower—designated by 430c in
In various embodiments of this sort, the cam profile 420a of the cam member 420 and the transmission lever 430 are configured in such a way that:
The concept is exemplified in
In this condition, the transmission lever 230 is in an angular position such that the cam-follower end of the lever arm 430a is on a straight stretch of the cam profile 410a, while the opposite end of the lever arm 430b is against the widened head 412b of the valve member 412 of the dosing valve 410, but without exerting any pulling action thereon. This valve member 412 is thus held by the corresponding spring in the closed position of the inlet 411e of the corresponding dosing chamber (see
After start of rotation of the motor 400 in a clockwise direction, with the consequent counter-clockwise rotation of the cam member 410, the cam-follower end of the lever arm 430a will come to be in contact with a curved stretch of the cam profile 420a, such as to induce an angular movement in the clockwise direction of the transmission lever 430: the end of the lever arm 430b will hence move away from the widened head 412b of the valve member 412, possibly arriving in the proximity of the front surface of the lid 411a of the valve 410, and hence without exerting any pulling action on the valve member 412. This condition is illustrated in
The transmission lever 430 is preferably made of substantially rigid polymeric material or plastic material. However, with a particular shape and type of the material, the lever itself could possibly be able to bend slightly in an elastic way and then return to its original shape. In other words, the substantially rigid structure of the transmission lever 430 may be such as to enable the corresponding driving function, but can allow, if so required, slight elastic bending, for example, to compensate for dimensional tolerances which might cause mechanical interference. In the course of sliding of the cam profile 410a on the cam-follower end of the arm 430a, the latter (and/or the lever arm 430b) could be temporarily bent in an elastic way, in the case where the opposite end of the lever arm 430b were to be pressed on the lid 411a of the valve 410.
The angular displacement of the lever 430 hence does not cause a displacement of the valve member 412 or any action thereon, hence without causing any dispensing of the second washing agent by the dosing valve 410. As has been said, the end of the arm 230b can be constrained in a slack way on the portion of the valve member 412 that projects on the outside of the dosing chamber of the valve. The effect can be obtained by providing the lever arm 230b for example with a forklike shape, as may be seen, for example, in
When delivery of a dose of the second washing agent coming from the second tank R2 is required, the motor 404 of the pump is driven in a direction opposite to the previous one, i.e., in a counter-clockwise direction. After start of rotation of the motor 404, with consequent rotation in a clockwise direction of the cam member 420, the cam-follower end of the lever arm 430a comes into contact with a rectilinear stretch of the cam profile 420a such as to induce an angular movement in the counter-clockwise direction of the transmission lever 430: the end of the lever arm 430b then comes back to resting on the widened head 412b of the valve member 412, without causing movement of the latter. This condition is illustrated in
As rotation of the member 420 proceeds, the cam-follower end of the lever arm 430a comes into contact with a curved stretch of the cam profile 420a, such as to induce a further angular movement in the counter-clockwise direction of the transmission lever 430. In this way, the end of the lever arm 430b exerts a pulling action on the widened head 412b of the valve member 412, thereby bringing about recession of the valve member 412 against the action of the corresponding spring. This condition is illustrated in
Further rotation of the member 420 causes the cam-follower end of the lever arm 430a to come back into contact with a rectilinear stretch of the cam profile 420a, now inducing an angular movement in the clockwise direction of the transmission lever 430, and hence enabling advance of the valve member 412 under the action of the corresponding spring. This condition is illustrated in
It will be appreciated, with reference to the example illustrated, that to a rotation through 360° in the clockwise direction of the cam member 420 there corresponds dispensing of a number of dosed amounts of the second washing agent (three, in the specific example).
It will likewise be appreciated that, in the course of rotation in the counter-clockwise direction of the motor 404, there will occur a corresponding rotation of the rotating assembly 401 of the peristaltic pump 400, which, however, will not bring about any delivery of the first washing agent from the tank R1.
This rotation of the motor in the secondary direction, as against the primary direction of pumping into the washtub, is, however, useful also as regards the tank R1 in so far as pumping in the secondary direction can enable re-balancing of the volume of “air-washing agent” in the tank, i.e., compensation of the volume of a first dose of the first washing agent previously delivered by means of a rotation in the primary direction of the motor 404. Thanks to this characteristic, the tank R1 may possibly be without any venting openings.
Advantageously, pumping in the secondary direction enables pumping, into the aforesaid tank, of at least a fair share of the washing agent that has remained in the tube 403, in particular in the stretches 403a and 403b, in this way preventing any stagnation, which, for example, in the case of prolonged disuse, could cause faults, such as clogging of the tube.
It will therefore be appreciated that, in various embodiments, the function of re-balancing of the pressure inside the tank and/or of emptying the dispensing tube of a dispensing arrangement is obtained simultaneously with driving of another dispensing arrangement, in particular thereby enabling overall reduction of the times of activation of the pump, also with the advantage of a reduction in energy consumption.
It will moreover be appreciated that the rotating assembly 401 of the pump 400, and in particular at least one element 402 thereof, is configured so as to keep a portion of the deformable tube 403 constantly compressed even when the pump 400 is inactive, in this way preventing risks of faults, such as an undesired passage of the washing agent WD. This characteristic prevents, for example, any accidental emptying of the tank R1 and/or consequent washing anomalies due to the excess of agents WD accidentally poured into the washtub. Continuous compression of the tube 403 also prevents the undesired inlet of air into the tank, which may prove useful for reducing the risks of degradation of the washing agent.
The actuator 404 of the pump 400 is hence preferentially a reversible electric motor, operation of which can be managed by means of a suitable circuit arrangement, for example, a control circuit or controller, in itself known, implemented on an electronic card mounted on the fixed dispenser part 200, in particular within the cavity C of its main body 201. Such a card is, for example, designated by 250 in
It should be noted, on the other hand, that a control circuit arrangement of the dispenser could be implemented totally or in part in the control system CS of the dish-washing machine 1. In various embodiments, a circuit arrangement on board the dispenser 10 is configured for connection to the control system CS of the dish-washing machine on which the dispenser itself can be installed, and the circuit arrangement of the dispenser is configured to enable control of the actuator of the pump as a function of electrical signals supplied by the aforesaid control system CS. For instance, the card 250 of the dispenser 10 may be provided with communication means in order to receive and/or transmit electrical signals from/to a controller of the control system CS of the dish-washing machine 1, for example, to receive data and parameters for controlling the motor 404, for the purposes of dosage of the washing agents, and/or to send electrical signals supplied by sensor devices on board the dispenser, and/or receive commands for other actuation devices on board the dispenser. The circuit arrangement on board the dispenser could in any case include even just a wiring and/or electrical connectors, electrically connected to at least one actuation device and/or a sensor device on board the dispenser, for direct control of the dish-washing machine 1 by the control system CS.
As has been seen previously, in various embodiments, the dispenser has a dispenser body, defined in which is at least one containment volume, which is able to contain a washing agent in liquid or semisolid form, as well as a dispensing arrangement, configured to dispense one or more dosed amounts of the washing agent, as well as a circuit arrangement, configured for connection to a control system of a dish-washer on which the dispenser itself can be installed. In various embodiments of this sort, the dispenser further comprises at least one operable part, configured to be displaced manually by a user at least from a first position to a second position. With reference, for instance, to the examples described previously, such an operable part may be represented by a plug or a hatch for opening or closing the inlet passage of a tank R1, R2, or by a driving element 220 (
In particularly advantageous embodiments of this sort, the dispenser further comprises a locking/unlocking arrangement, which includes a locking mechanism that can be driven by a corresponding electric actuator to assume at least one operative condition and at least one inoperative condition, in which the locking mechanism prevents or enables, respectively, displacement of the aforesaid operable part from its first position to its second position. The aforementioned electric actuator is configured to be controllable as a function of an electrical signal supplied by at least one of a sensor device belonging to the circuit arrangement of the dispenser and the control system of the dish-washer on which the dispenser is installed, in order to cause passage of the locking mechanism from the at least one operative condition to the at least one inoperative condition.
The electrical signal used for managing the locking/unlocking arrangement may, for example, be a signal representing a level of the washing agent in the corresponding containment volume, supplied by a purposely provided sensor of the dispenser 10, or else representing a purposely provided command generated by the control system CS of the machine 1 (for example, a purposely provided key on the control panel of the dish-washing machine for enabling or preventing removal of the dispenser part 100 from the dispenser part 200 via the coupling/uncoupling arrangement described above).
As has been seen, the at least one volume for containing the washing agent, such as one of the tanks R1, R2, has a loading passage, and the aforesaid operable part may comprise a closing element associated to the loading passage. This closing element may be a plug or else, as in the examples illustrated, a hatch associated to which is an latching/releasing device. A possible embodiment of a locking/unlocking arrangement will now therefore be described with reference to a dispenser 10 according to various examples so far described, where the removable part 100 of the dispenser 10 includes two tanks R1 and R2, each having a loading passage 103 of its own provided with a corresponding hatch 1041 and 1042, respectively, associated to which is a respective latching/releasing device 1051 and 1052. As has been seen, to the tanks R1 and R2 there can be associated respective level sensors, for example, of the type described with reference to
In the example, the cam profile is defined by two opposite stretches that extend each according to a respective arc of circumference, the two circumferences being one larger than the other; for example, the stretch of a profile 452a may extend for more than 180° of a respective smaller circumference, whereas the stretch of a profile 452b may extend for less of 180° of a larger circumference. In general terms, the cam member 451 has at least one part of its peripheral cam profile that is suitable for bringing about displacement of at least one slider 4531o 4532, and at least one other part of the peripheral cam profile that is suitable for not bringing about displacements of the sliders 4531 and 4532. The cam member 451 could hence also be of a lobed type, for example, with three similar lobes, two of which opposite to one another and the third at 90° with respect to each of the others.
Each slider 4531 and 4532 is urged by a corresponding elastic element, such as a helical spring 454 (see
Each slider may be made up of a number of parts. In the non-limiting example illustrated, the slider 4531 is made up of two parts coupled together, designated by 4531a and 4531b only in
The locking mechanism further comprises a locking member, configured to interact with a respective movable member of the latching/releasing device 1051 or 1052 of a corresponding hatch 1041 or 1042. With reference to the case illustrated, there are hence provided two locking members, designated by 2061 and 2062, already previously mentioned with reference to
Each blocking member 2061 and 2062 is displaceable between a blocking position and an unblocking position, with respect the respective movable member, here represented by the latching/releasing device 1051 and 1052 that are manually operable. As mentioned previously, in various embodiments, each latching/releasing device 1051 and 1052 basically consists of a lever member that can be turned through an angle about a respective fulcrum or axis 105c and that defines a first lever arm 105e and a second lever arm 105d, the second lever arm defining or having associated to it a respective element that is operable by a user. In embodiments of this sort, each locking member 2061 and 2062 has an end—designated by 206a in the figures—configured to interact with an end portion of a respective first lever arm 105e, to prevent or enable, respectively, an angular movement of the lever member that forms the latching/releasing device 1051 and 1052. In preferred embodiments, the aforesaid end 206a of the locking member 2061 or 2062 is an upper end.
Preferentially, each locking member 2061 and 2062 is mounted so that it can turn about the respective longitudinal axis. For this purpose, with reference to the examples illustrated, each member 2061 and 2062 is constrained in a rotatable way in a through seat defined in the respective positioning and/or guiding formation 205, with its upper end portion 206a and its lower end portion that project at the two ends of the formation 205.
In various embodiments, in order to obtain rotation of the locking member, the locking mechanism includes a transmission comprising toothed parts meshing with one another, preferably for a transmission of a pinion-rack type. For this purpose, preferentially each member 2061 and 2062 includes a respective toothing that extends according to a circumference or a part thereof and that meshes with a corresponding toothing of a respective slider 4531 or 4532. In the example represented, the lower end portion of each locking member 2061 and 2062 has a respective gear wheel 206b that meshes with a lateral toothing 453b of the respective slider 4531 or 4532, substantially with a transmission of a pinion-rack type. In this way, as may be appreciated, a linear displacement of each slider 4531 or 4532 causes rotation of the respective locking member 2061 and 2062 about the respective longitudinal axis.
In various preferential embodiments, the end portion 206a of each locking member 2061 and 2062, designed to interact with the respective first lever arm 105e of the corresponding latching/releasing device 1051 or 1052, has a substantially semi-cylindrical profile, with the locking member that presents an angular travel between the blocking position and the unblocking position of approximately 90°. It should be noted that the semi-cylindrical shape of the profile of the end portion 206a of each locking member 2061 and 2062 is to be understood as being provided merely by way of preferential example in so far as the end portion could also have a profile having the shape of a circular sector with an extension of less than 180° (for example, an extension of just 90°), without prejudice to the functions described hereinafter.
In
In the example represented, in this condition the cam member 451 is in an angular position such that both sliders 4531 and 4532 are held by the member itself in the respective retracted conditions, with a maximum compression of the corresponding springs 454. The simultaneous retracted position is determined by the fact that the cam-followers 453a of both of the sliders 4531 and 4532 interact with one and the same stretch of the cam profile, namely its more extensive stretch 452a of smaller radius.
Corresponding to this position of the sliders 4531 and 4532 is an angular position of the locking members 2061 and 2062 such that the corresponding upper ends 206a are arranged with their semi-cylindrical portion that extends underneath the end area of the first lever arms 105e of the latching/releasing devices 1051 and 1052. As may be appreciated, in this condition the devices 1051 and 1052 cannot be operated manually; i.e., an angular movement cannot be imparted thereon sufficient to enable release of the corresponding hatch 1041 or 1042. The condition illustrated is obtained via appropriate positioning of the shaft 450a of the electric motor 450, which may, for example, be a stepper motor, or else a different motor, possibly provided with a position sensor, such as a sensor of an encoder or resolver type. For this purpose the circuit or card 250 may comprise a circuit for control of the motor 405 and/or a circuit for control of the corresponding position sensor.
Control of the motor 405, i.e., of the cam member 451, in the position illustrated in
In
In the example represented, in this condition the cam member 451 is in an angular position such that the slider 4532 is held by the member itself in the respective retracted condition, with a maximum compression of the corresponding spring 454. Instead, the slider 4531 is pushed by the action of the corresponding spring 454 into a respective advanced condition. These different positions are determined by the fact that the cam-followers of the two sliders interact with different stretches of the cam profile: in particular, the cam-follower 453a of the slider 4532 interacts with the stretch of profile 452a that is more extensive and of smaller radius, whereas the cam-follower 453a of the slider 4531 interacts with the stretch of a profile 452b that is less extensive an of greater radius. Corresponding to this position of the sliders 4531 and 4532 is an angular position of the locking members 2061 and 2062 such that the upper end 206a of the member 2062 is set with its semi-cylindrical portion that extends underneath the end area of the lever arm 105e of the engagement/release device 1052, whereas the upper end 206a of the member 2061 is set with its semi-cylindrical portion that is staggered with respect to the end area of the lever arm 105e of the engagement/release device 1051. As may be appreciated, in this condition, it is only the device 1052 that cannot be operated manually, as already described above, whereas the device 1051 can be operated manually, i.e., an angular movement can be imparted thereon sufficient to enable release of the corresponding hatch 1041.
Also in this case, the condition illustrated is obtained via appropriate positioning of the shaft 405a of the electric motor 450, as a function of the signal supplied by the level sensors that equip the two tanks R1 and R2. As has been said, in the specific case illustrated, the signal of the sensor that equips the tank R2 will be indicative of the presence within the tank itself of an amount of washing agent that exceeds the corresponding pre-set minimum level, whereas the signal of the sensor that equips the tank R1 will be indicative the presence inside the tank itself of an amount of washing agent lower than the corresponding pre-set minimum level. The hatch 1041 of the tank R1 can thus be opened by acting on the latching/releasing device 1051 and topping-up with the corresponding washing agent can be carried out.
Finally, in
Consequently, in the example represented the cam member 451 is in an angular position opposite to that of
In this way, the device 1051 cannot be operated manually, whereas the device 1052 can be operated manually to enable opening of the corresponding hatch 1042. Of course, also this condition illustrated can be obtained via appropriate positioning of the shaft 450a of the electric motor 450 as a function of the electrical signal supplied by the level sensors. In the specific case illustrated, the signal of the sensor that equips the tank R1 will be indicative of the presence within the tank itself of an amount of liquid that exceeds the corresponding pre-set minimum level, whereas the signal of the sensor that equips the tank R2 will be indicative of the presence within the tank itself of an amount of liquid lower than the corresponding pre-set minimum level. The hatch 1042 of the tank R2 can thus be opened by acting on the latching/releasing device 1052 and topping-up with the corresponding washing agent can be carried out.
As mentioned previously, the closing element that equips the loading passage of a tank, i.e., the part that can be operated with which the locking/unlocking arrangement interacts, could be a plug, instead of a hatch (without ruling out possible combinations of the two elements). For such a case, the locking/unlocking arrangement could be of a conception similar to the one described above: for example, a latching/releasing system similar to one of those designated by 1051 and 1052 may be provided, where an latching element of the type designated by 105b in
As explained previously, in various embodiments, the dispenser comprises a fixed dispenser part and a removable dispenser part, which is couplable in a removable way to the fixed dispenser part and defines at least one tank for a washing agent. In embodiments of this sort, the dispenser may also comprise a signalling arrangement, which includes at least one emitter device mounted on the fixed dispenser part, which is able to emit visible radiation and includes a light source, as well as at least one light-guide element configured to transfer the visible radiation emitted by the emitter device towards an area of the dispenser designed to face inside the washing chamber, the at least one light-guide element being on the removable dispenser part and being optically coupled in a separable way to the emitter device mounted on the fixed dispenser part. Preferentially, the light-guide element extends between a front and a back of the removable dispenser part, very preferably within a corresponding passage or mounting seat defined in the hollow body.
The dispenser may comprise at least one sensor device, configured to supply an electrical signal representing at least one condition of the content of the at least one tank, such as a level thereof or, as described also hereinafter, a characteristic different from the level thereof, in particular a qualitative characteristic thereof, such as a chemico-physical characteristic or a characteristic linked to its composition and/or type.
In the aforesaid embodiments, the signalling arrangement may be controllable as a function of the electrical signal supplied by the at least one sensor device. However, the signalling arrangement may belong to a circuit arrangement of the dispenser, which is configured for connection with a control system of a dish-washer on which the dispenser itself can be installed: in these cases, the circuit arrangement on board the dispenser may be configured to enable control of the signalling arrangement as a function of an electrical signal supplied by the aforesaid control system of the dish-washer.
A possible embodiment of the aforesaid signalling arrangement will be described with reference to a dispenser 10 according to various examples described so far, where the removable part 100 of the dispenser 10 includes two tanks R1 and R2, associated to which are respective level sensors, for example, of the type described with reference to
With reference in particular to
In various embodiments, each emitter device may also comprise a respective light-transmitting element on the fixed dispenser part 200, such as the elements already designated previously by 207, for example, in
As may be seen in
The signalling arrangement includes a first light-guide element, designated as a whole by 261 in
Each first light-guide element 261 is mounted on the removable dispenser part 100, and in particular on its hollow body 101. For this purpose, in various embodiments, provided on the hollow body 101 is a corresponding through mounting seat, preferably substantially cylindrical, which extends between the front and the back of the hollow body 101. Such a seat is designated by 262a-262b in
Advantageously, each first light-guide element 261 is designed to be optically coupled in a separable way with respect to the emitter device 260, 207. For this purpose, with reference to
The entry end 261a of the first light-guide element 261 is preferably an inclined surface in the case where the axis of emission of the emitter device extends in a direction transverse with respect to the axis of the light-guide element. In the case exemplified, the emitter 260, 207 has an axis of emission that extends as a whole substantially vertically, whereas the light-guide element 261 substantially extends horizontally between its entry end and its exit end: for such a case, the exit end 207b of the element 207 may be substantially plane, and the entry end 261a of the element 261 may have an inclination of approximately 45°. Obviously, in the case where the transmission element 207 were to extend further up than the case represented in the figures, and the light-guide element 261 were at the same time shorter than what is represented, a reverse configuration would be possible, i.e., with the exit end 207b of the element 207 inclined and the entry end 261a of the element 261 substantially plane. Of course, the exit end 207b and the entry end 261a could also both be inclined. In general terms, at least one of the entry end 261a and the exit end 207b is shaped to enable optical coupling between the element 261 and the element 207.
As may be appreciated, the fact that each light-guide element 261 is optically coupled in a separable way with respect to the emitter device 260, 207 enables free removal of the removable dispenser part 100 from the fixed dispenser part 200, ensuring, instead, an efficient and precise transmission of light indications when the two parts in question are, instead, coupled together.
As already mentioned, management of the light source 260 of the emitter device can be carried out by a controller that equips the dispenser 10, such as the card 250 referred to previously, as a function of the signals supplied by the level sensor and/or quality sensor that equips each tank R1 and/or R2, or else can be carried out by the control system CS of the dish-washing machine 1.
In advantageous embodiments, the source 260 of the emitter device may be controllable for emission of radiation at different frequencies and/or different intensities, and hence with different colours and/or different light intensities in order to supply indications of a diversified type according to the information that is to be made available to a user of the dish-washing machine. For instance, emission of a green light could be understood as meaning the presence of an amount of washing agent greater than a pre-set minimum level and/or the presence of a proper washing agent in the tank (in the case where the sensor that equips the tank is able to detect the quality and/or type of washing agent), emission of a yellow light could be understood as meaning the need to top up with the washing agent, and emission of a red light could be understood as meaning the presence within the tank of a wrong washing agent and/or a washing agent that is contaminated (consider the case where a user fills or tops up the tank R1 dedicated for a washing detergent with a rinsing additive). Alternatively or in addition, for these or other indications, it might also be possible to use lights of the same colour that vary in intensity, for example, with more or less intense lights or flashing lights, or else that alternatively increase and decrease the light intensity.
It will thus be appreciated that, in various embodiments, one and the same signalling arrangement may be used for carrying information of a different type, via at least two different signalling modes (colours/flashing).
In various embodiments, the signalling arrangement that equips the dispenser comprises at least one second light-guide element, preferably located at a front of the removable dispenser part, with the second light-guide element that is optically coupled to the at least one first light-guide element and is configured to diffuse the visible radiation received by the at least one first light-guide element.
An embodiment of this sort is illustrated in
In the example illustrated in
To return to the example illustrated, the second light-guide element 263 hence extends at least in part in a gap existing between lateral facing surfaces of the seat 103c and of the hatch 1041 or 1042 so as to have at least one respective surface directly exposed, even when the hatch is in the closed position within the corresponding seat. It will consequently be appreciated that in embodiments of this sort it is not necessary for the exit end of each first guide element 260 to be directly visible at the front of the removable dispenser part 100, as, instead, in the case represented in
In preferential embodiments, the second light-guide element 263 extends along a number of contiguous sides of the seat 103c and hatch 1041 or 1042, for example, in the form of a frame. Obviously, the shape chosen may vary widely with respect to the one exemplified, also according to the position chosen for the second light-guide element 263 (for example, U-shaped, L-shaped, circular, semicircular, polygonal, etc.).
The upper transverse part 263b is at the upper end of the seat 103c, set up against its bottom, in any case with an exposed surface at the upper edge of the hollow body 101. The lower transverse part 263b is, instead, at the lower end of the seat 103c, set up against its bottom, which is also with its lower surface possibly exposed between the seat 103c and the hatch 1041 or 1042, at the step D (
Visible in isolation in
In embodiments of this sort, and as may be seen in
In various embodiments, the first light-guide element 261 and the second light-guide element 263 substantially extend in a direction transverse with respect to one another, as in the case exemplified in
With reference, for example, to
It should be noted that, albeit preferable, the emitter device set on the fixed dispenser part 200 does not necessarily have to include a light-transmitting element of the type designated by 207, in particular if the light source 260 is mounted on the aforesaid fixed part directly facing the entry end 261a of the first light-guide element 261.
The configurations exemplified in
As also mentioned previously, in various embodiments, the dispenser includes at least one tank, preferentially operatively associated to which is a level sensor; in addition or an alternative, in various preferential embodiments, there may be operatively associated to the at least one tank a sensor for detecting at least one characteristic of the substance contained in the tank other than the level, and in particular a qualitative characteristic thereof. In the present description and in the attached claims, by “qualitative characteristic” is meant a characteristic or property linked to the type or composition of the substance, such as a chemical or physical or electrical characteristic. Detection of a qualitative characteristic may prove useful for the purposes of recognition of the type of substance, or of a possible contamination thereof or mixing thereof with another substance, or a possible deterioration thereof. This detection may, for example, enable limitation of possible risks that could derive from incorrect operations carried out by a user when topping up a tank, which could result in damage to the dispenser or in damage to the dish-washer, or in a poor washing result.
A quality sensor proves, for example, useful for recognising whether the substance contained in the tank is the right one, i.e., whether it corresponds to the one to which the tank in question is effectively dedicated. Consider, for example, the case where a user introduces, by mistake and without realizing, a liquid rinsing additive (brightener) into a tank dedicated, instead, for a liquid washing detergent: the possible subsequent starting of a dish-washing program in this condition would entail extremely negative effects, both in terms of low washing efficiency and in terms of an abundant production of foam, which is difficult to eliminate, within the tub 3, which could even jeopardise operation of the dish-washing machine 1 (the foam could infiltrate into ventilation ducts, until it penetrates into the door of the dish-washing machine, where the foam formed by an electrically conductive liquid—as is a brightener—could create short-circuits between electrical components of the dish-washing machine, or else this foam could come out into the domestic environment. Similar considerations may be made as regards mixing in one and the same tank of two different washing agents, or again as regards contamination of a washing agent with a different substance, for example, dilution thereof with water, which could reduce the washing efficiency, or else mixing with two different washing agents, where uncontrolled reaction between different chemical compounds could produce harmful substances. It should in any case be noted that such a quality sensor is associated to the dispenser body and is designed to detect characteristics of a substance contained therein, prior to its dispensing.
The signal supplied by a quality sensor of the type referred to can be conveniently used by a circuit arrangement of the dispenser or of the dish-washing machine to provide a suitable indication for the user (obviously with the machine supplied electrically), such as a warning of an audible type (for example, via a buzzer) and/or a warning of a visual type (for example, using a light warning system of the types exemplified previously).
In various embodiments, the quality-sensor device comprises a sensing element having at least two electrodes, prearranged for being in contact with the respective washing agent, and a circuit arrangement configured to measure the value of at least one electrical quantity between the at least two electrodes. The circuit arrangement, implemented on board the dispenser or in the control system of the machine, is configured to compare the value of the at least one electrical quantity measured with at least one respective reference value, and consequently generate information representing a qualitative characteristic of the washing agent. Such a sensor may possibly be pre-arranged to obtain also a measurement of level, as will be exemplified hereinafter.
A possible embodiment of a quality sensor of the type referred to is illustrated schematically in
As mentioned previously, the inlet 210 preferably comprises at least one cylindrical tubular portion, to enable coupling of the corresponding tubular outlet 112 of the tank R1 (see, for example,
In the example, the sensing element 270 comprises at least two electrodes 2701 and 2702, which project into the volume of the inlet 210. The electrodes are preferably made of metal and designed to come into direct contact with the washing agent, for example, when the electrical quantity being detected is the impedance or the conductivity or the capacitance.
Preferably, the at least two electrodes 2701 and 2702 each have a respective axis that substantially extends in the depth dimension Z of the dispenser 10; in these embodiments, the electrodes substantially extend parallel to one another. The axes of the at least two electrodes are preferentially at a distance comprised between 2 and 20 mm from one another, preferably comprised between 3 and 7 mm. In various embodiments, such as the one exemplified, the sensing element 270 comprises two electrodes 2701 and 2702 substantially at one and the same height, with reference to the height dimension Y of the dispenser 10. Of course, the length and the position the electrodes 2701 and 2702 is such that they occupy in depth (dimension Z) only a part of the inlet 210 in order not to constitute a hindrance to insertion in the inlet itself of the tubular portion (112a,
In the example, the electrodes 2701 and 2702 are driven in a fluid-tight way into respective through holes provided in the bottom 210b of the inlet, and have for this purpose an abutment flange 271, which can also possibly perform sealing functions. In addition or as an alternative to the flange, the electrodes 2701 and 2702 could be provided with respective seal rings. Instead of driving, fixing between the body of the dispenser and the electrodes could be obtained by overmoulding the former on the latter. The electrodes 2701 and 2702 could comprise an electrically conductive polymer, such as a polymer with electrically conductive fillers, for example powders or metal fibres and/or containing carbon fibres. The electrodes 2701 and 2702 could also have a shape different from the one exemplified. Possibly, the electrodes could be isolated from the liquid substance, for example, coated with a layer of electrically insulating material, if they are designed for measurement of an electrical quantity that does not imply a direct contact with the substance, for example, a measurement of capacitance: in such a case, it is sufficient for the coated electrodes to be arranged so that they can at least partially be immersed in the substance.
In other embodiments still, the sensing element could be configured like a stand-alone module, coupled in a sealed way to the rear part of the inlet, for this purpose provided with a suitable mounting opening (variants of this sort will be described hereinafter).
Once again with reference to the example illustrated in
In various embodiments, the value of the electrical quantity measured between the electrodes 2701 and 2702 of the sensing element 270 is used by the circuit arrangement of the dispenser 10 or by the control system CS of the dish-washing machine 1 for assessing the correctness or quality of the substance present at the inlet 210 or else of the washing agent contained in the corresponding tank. For this purpose, the aforesaid circuit arrangement of the dispenser or of the control system CS of the machine 1 preferentially includes memory means, stored in which are values or ranges of reference values (for example, in tabulated form) of the electrical quantity in question, representing those washing agents that are considered correct for the specific tank, here the tank R1.
The circuit arrangement hence compares the value of the quantity detected via the sensing element 270 with the reference values stored, and consequently controls generation of a suitable audible and/or visual warning, as mentioned previously. For instance, in the case where the washing agent detected corresponds to one of those encoded in the memory means, the warning system is not activated, or is activated in a first mode (for example, a short intermittent sound or a green light); in the opposite case, the warning system is activated, or is activated in a second mode (for example, a continuous sound or a red light). As has been said, the aforesaid circuit arrangement may, for example, be implemented in the card previously designated by 250, including the microcontroller 251, or else be implemented in the control system CS of the dish-washing machine 1.
In particularly advantageous embodiments, the electrical quantity detected between the at least two electrodes 2701 and 2702 of the sensing element 270 is the impedance. Some possible detection modes based upon measurement of impedance will be described hereinafter, also with reference to alternative sensor versions.
Of course, a quality sensor of the type described with reference to
As has been seen, in various embodiments the dispenser includes a fixed dispenser part and a removable dispenser part, the latter comprising a hollow body that defines at least one tank, where at least one first wall of the hollow body is designed to face at least partially at least one second wall of the fixed dispenser part, and the dispenser comprises at least one sensor device, configured to supply an electrical signal representing at least one of a level and a qualitative characteristic of the content of the at least one tank. In embodiments of this sort, the at least one sensor device is arranged at least in part on the fixed dispenser part. In preferential embodiments, the sensor device is entirely arranged on the fixed dispenser part.
In various embodiments, the at least one tank has, preferably in a lower part thereof, an outlet in a wall of the hollow body, which can be coupled in a separable way to a respective inlet present in a wall of the fixed dispenser part: in particularly advantageous embodiments, the sensor device is arranged substantially at the inlet, or in a corresponding housing in fluid communication with the inlet.
Such a solution may also be explained with reference to
The preferential version with at least one sensor device set on the fixed dispenser part makes it possible to facilitate and/or guarantee reliability of the corresponding electrical connections in so far as a fixed electrical connection is provided (for example, a wiring) between the dish-washer and the fixed dispenser part, albeit enabling detection of the content of the removable dispenser part, i.e., the content of the at least one tank R1 or R2. It is also clear that the concept of mounting of the entire sensor on the fixed dispenser part also applies as regards the already mentioned possibility of mounting a sensing element 270 at the inlet 211, for example, at the back of its tubular part 211c, 211c (see, for example,
The solution of providing a sensing element with at least two electrodes, which are designed to be at least partially immersed in the washing agent, can be advantageously used also for the purposes of production of a level sensor.
An embodiment of this sort is exemplified in
In the example of
Also in the case of the level sensor exemplified in
The aforesaid circuit arrangement can hence include memory means, stored in which is at least one reference value of the electrical quantity in question, for example, a value representing the simultaneous contact of both of the electrodes 2701 and 2703 with the washing agent in question (or, more in general, with a liquid or semisolid substance). The value representing the simultaneous contact of both of the electrodes 2701 and 2703 with the washing agent could hence indicate, for example, a level of the washing agent that exceeds a minimum value.
The circuit arrangement hence compares the value of the quantity detected via the electrodes 2701 and 2703 of the sensing element 270 with the at least one reference value stored. It will be appreciated that, when both of the electrodes 2701 and 2703 are in contact with the washing agent, the electrical quantity measured will have a first value; instead, when the level of the washing agent within the inlet 211 and the corresponding bottom extension 211c is at a lower height than the electrode 2703 or comprised between the two electrodes 2701 and 2703 (i.e., with the upper electrode 2703 in air), or else with both of the electrodes 2701 and 2703 in air, the electrical quantity measured will have a second value, clearly distinguishable from the first value.
This condition of intermediate level between the two electrodes, hence lower than the upper electrode, can be considered as representing a low level of the washing agent in the tank R2 (given that the outlet 113 is located in the lower area of the tank R2), and consequently of the need to proceed to topping-up. In this perspective, the lowest point of the electrode 2703, with reference to the height dimension (Y) identifies a minimum level of the washing agent, below which it will be necessary to carry out topping-up with the washing agent.
On the basis of the comparison may between the measured value and the at least one reference value, the control arrangement will accordingly control generation of a suitable audible and/or visual warning, like the one already mentioned previously. Also in the case of a level detection, the electrical quantity detected between the at least two electrodes 2701 and 2703 of the sensitive element 270 may be the impedance, or the conductivity, or the capacitance.
It will be appreciated that the level sensor described with reference to
As has been seen, in various embodiments the dispenser comprises a body, defined in which is at least one tank, which is able to contain a corresponding washing agent in liquid or semisolid form, and at least one sensor device, configured to provide information representative of at least one of a level and a qualitative characteristic of the washing agent. In advantageous embodiments of this sort, the sensor device comprises a sensing element that includes at least two electrodes, prearranged for being in contact with the washing agent, and a circuit arrangement, which is configured to measure a value of at least one electrical quantity between the at least two electrodes and compare the value of the at least one electrical quantity measured with at least one respective reference value in order to generate information representative of at least one of a level and a qualitative characteristic of the washing agent.
In various preferential embodiments, the sensing element of the sensor device includes at least three electrodes, and in particular a first electrode and a second electrode preferably at one and the same height, and a third electrode at a height higher than that of the first and second electrodes. In an embodiment of this sort, the circuit arrangement associated to the sensing element may be configured to:
As may be appreciated, a sensor device of the above sort can be obtained by combining the concepts expressed previously with reference to
A sensor device of the above sort is thus able both to detect an incorrect topping-up or filling of the tank (for example, introduction of an additive, instead of a detergent) and to detect running-out of the washing agent.
As may be seen in
The electrodes of the sensing element 270 can be obtained in various ways, for example, by means of elements as exemplified in the figures. However, in other embodiments, the at least two electrodes of the sensing element can be obtained by means of screen printing with metallic inks on a corresponding electrically insulating substrate (for example, of alumina, plastic, or vetronite), or else by means of typical techniques used in the production of circuits, for example, constituted by multi-layers of photo-etched copper, and vetronite. Alternatively, it is possible to use thin-film deposition techniques, such as vacuum evaporation, sputtering, and the like, on a suitable electrically insulating substrate. This applies, of course, also to the sensitive elements 270 of
As already explained, the electrical quantity measured between the two pairs of electrodes (2701-2702 and 2701-2703), for example, the impedance, will be different according to the fluid set between them so that the different characteristics of the fluid will cause a different response between the electrodes of each pair. The fluids considered are those typically of interest for a dispenser for dish-washing machines, such as detergent and liquid or semisolid (gel) additives, water, vinegar and air.
The graphs of
The graph of
It will thus be appreciated that a possible logic of level detection based upon the use of a sensing element of the type illustrated in
The circuit arrangement associated to the sensitive element 270 may comprise a microcontroller and at least one driving circuit for the sensitive element.
As illustrated in
According to the schematic example of
Each driving circuit can be obtained in various ways.
For instance,
The amplifier OA has an input (here, the inverting input −) to which the sensing element 270 is connected in series, and a known reference resistance Rr, is connected in parallel between the input (−) and the output of the operational amplifier OA. With such a scheme, Zx is the unknown impedance to be measured between the pair of electrodes of the sensitive element 270. The effective driving voltage generated by the microcontroller, designated by Vs is constant, whereas the voltage value at output from the operational amplifier OA will thus depend upon the value of Zx. The value of Vu may, for example, be read using an analog input of the microcontroller, which will calculate the ratio between Vs and Vu, proportional to Zx.
Instead, if the microcontroller 250 is not pre-arranged for generating a frequency output, it is possible to use an oscillating circuit, the resonance frequency of which is a function of an impedance value measured between the at least two electrodes of the sensing element 270, with the microcontroller pre-arranged to detect the impedance value on the basis of the aforesaid resonance frequency.
Such an oscillating circuit can be obtained in any known way, such as an RC network, an LC resonant circuit, or a crystal or dielectric resonator for defining the oscillation frequency thereof. RC oscillators are generally used at low frequency (up to hundreds of kilohertz). Forming part of this category are the following oscillators: Wien-bridge oscillators, bridged-T oscillators, twin-T oscillators network, and phase-shift oscillators (PSO). In LC oscillators, an LC network determines the oscillation frequency thereof. In this category there may belong, for example, Colpitts, Hartley, Clapp, Armstrong, and Meissner oscillators.
The electrical characteristics between two electrodes of the sensing element will cause variation of the resonance frequency of the resonant circuit, which may be read with an analog input or with a digital input of the microcontroller: in this case, the unknown impedance will be read on the basis of a frequency measurement.
In order to check whether it is possible to use the variation of the capacitive component of a sensing element 270, measurement tests were carried out by means of an impedance meter in parallel-capacitance mode, inserting in series to the sensing element 270 a 10-nF capacitance. The graphs of
With the electrodes described previously, it is thus possible to have an excellent differentiation for frequencies around 100 kHz. At these frequencies many circuit solutions are practicable, both with LC circuits suited also for higher frequencies and with RC circuits, or better still with solutions already integrated in the microcontrollers. It is also possible to use for this purpose quartz oscillators. In quartz-crystal oscillators a piezoelectric crystal is used, which is distinguished by a natural resonance frequency. The resonance frequency is determined by the type of cut and by the shape of the material in the feedback network. To control frequency stability, the crystal generally used is that of quartz (SiO2), which has the shape of a hexagonal prism and may be natural or artificial. From the crystal, dice are cut, according to different arrangements with respect to the crystallographic axes, with the different types of cut that bestow on the crystal different electrical and mechanical characteristics. A pair of electrodes of the sensitive element 270, set in series to a fixed and known capacitance, can be connected in parallel to the quartz. The variations of the type of washing agent and of level result in a variation of the oscillation frequency of the circuit.
For instance,
The circuit will resonate at the resonance pulsation of the parallel between L and C of the quartz and C0+C1·C2/(C1+C2). Since the capacitance C is smaller than the other three capacitances, it is dominant, and the resonance pulsation is consequently f=1/(LC)1/2.
A sensing element of any of the types designated previously by 270 may belong to a sensor module designed for being mounted on the body of the dispenser. In this perspective, the at least two electrodes of such a sensitive element can be associated to one and the same sensor body, configured for being mounted in a fluid-tight way on the dispenser body.
An example of this sort is illustrated in
In the example, the sensor body 280 has a tubular peripheral wall 280a, here substantially cylindrical, and a bottom wall 280b where the electrodes are mounted. The end of the peripheral wall 280a opposite to the bottom wall 280b may conveniently define a flange 280c radially projecting outwards, possibly provided with one or more polarization and/or coupling elements 280d, i.e., elements configured to enable mounting of the sensor body 280 with a pre-set orientation within the rear portion of the inlet 210 of the body part 201 of the dispenser.
In this case, the rear portion of the inlet 210 is without a bottom wall of its own and is preferably shaped for receiving a corresponding portion of the sensor body 280, possibly shaped also to define one or more engagement elements. One or more polarization and/or coupling elements, such as the one designated by 221 in
A substantially similar embodiment is illustrated in
Of course, a sensor body obtained according to the concepts expressed with reference to
Illustrated schematically in
As may be noted, the housing 222 is connected in fluid communication with the inlet 210, in particular via an opening in the bottom wall 222a. Between the sensor body 280 and the housing 222 there may be provided suitable sealing means: in the example, the body 280 is provided at the front with an annular sealing element 290a, to obtain axial or front sealing with respect to a corresponding seat 222c defined within the housing 222; in the example, the housing 222 is moreover shaped to define an annular part 222d bearing or resting on which is the front of the sensor device, here the layer 270c. The sensor body 280 can be fixed in the housing 222 according to any known modality.
In various embodiments, the set formed by the piezoelectric element and the corresponding electrodes is isolated from the washing agent. The isolation does not necessarily have to involve the entire front side of the substrate: in the case exemplified in
The layers that form the piezoelectric element 270a, the electrodes 270b, and the insulating coating 270c can be obtained with any known technique, for example, techniques of deposition normally used in the electronic field.
It should in any case be emphasised that the provision of the dielectric layer 270c is to be understood as optional, in so far as the ensemble formed by the piezoelectric element 270 could be envisaged for direct contact with the washing agent: an example in this sense is illustrated schematically in
A piezoelectric sensor of the type referred to can be used both for the purpose of level detection and for the purpose of quality detection.
In the case of a sensor having a sensitive element 270′ of the type referred to, an electrical value characteristic of the piezoelectric element 270a, which is, for example, its impedance, will be affected not only by the electrical characteristics of the medium in which it may be immersed, but also by the mechanical characteristics of the substance being detected, in particular by its viscosity and its density, this in consideration of the fact that the vibration frequency of the element 270a will be different according to whether the layer 270c, which is set up against the element 270a itself, is in contact with the liquid substance or not (in air), and according to the type of substance, i.e., more or less viscous or more or less dense. Consequently, on the basis of the inverse piezoelectric effect, also to a sensitive element of this sort the circuit considerations set forth previously may be substantially applied. For instance, in the case of use of a piezoelectric element of the type designated by 270a it will be possible to use the same piezoelectric element instead of a quartz, in a circuit configuration of any quartz oscillator, for example, the one represented in
Very schematically, then, the frequency of vibration of the piezoelectric element 270a will be different according to whether the front layer 270c of the sensor 270′ is in contact or not (or in contact to a greater or lesser extent) with the liquid substance, it thereby being possible to discriminate whether the level is higher or lower than a given threshold. On the other hand, on the basis of the frequency of vibration it will also be possible to discriminate whether the aforesaid layer 270c is in contact with a more dense/viscous substance or else with a less dense/viscous substance.
The graph of
As mentioned previously, provision of the layer of dielectric material 270c, albeit preferable, does not constitute an essential characteristic. The graphs of FIGS. 68-69 are similar to those of
In possible variant embodiments, a sensor may be provided, the sensing element 270′ of which exploits both the forward (direct) piezoelectric effect and the inverse piezoelectric effect. Such a case is illustrated schematically in
Use of a piezoelectric sensor may, for example, prove advantageous for the purpose of discriminating the type of washing agent on the basis of its physical characteristics, such as the viscosity or density, which, as has been said, affect the response of the sensor. In this way, for example, it is possible to discriminate whether a detergent WD or additive WA is of a liquid type or semisolid (gel) type. Such information may, for example, be used by the control system CS of the dish-washing machine 1 for adapting a washing program previously started by a user (this applies of course for any characteristic of a qualitative type that can be detected via the other types of sensor described herein).
Of course, a sensor of a piezoelectric type can equip each of the two tanks R1 and R2.
In various embodiments, at least one sensor device that equips the dispenser is a sensor of an optical type, i.e., having a sensitive element that comprises at least one emitter and at least one receiver of electromagnetic radiation.
A possible embodiment of this sort is illustrated schematically in
In the non-limiting example, the sensor body comprises two main parts, designated by 501 and 502, coupled together preferably in a sealed way and made, for instance, of plastic material. In the example, the body part 501 has a generally cylindrical conformation, possibly provided at a distal end with a flange 501b. Mounted on the proximal end of the body part 501 is a sensing element, including at least one emitter 270a′ of electromagnetic radiation, such as radiation in the visible, and at least one receiver of the radiation 270b′; the emitter may, for example, be an emitter diode, whereas the at least one receiver may comprise at least two distinct receivers, for example, photodetectors or photodiodes suitable for detecting the light emission generated by the emitter. In alternative embodiments, the receiver 270b′ may be a single receiver of the CMOS-array type, comprising a linear series or array of independent pixels, each constituted by a photo-detector.
In the example, the body part 502 performs mainly functions of casing, and for this purpose has a hollow cylindrical shape so as to be able to receive inside it the cylindrical portion of the body part 501. The part 502 then has a peripheral wall 502a and a bottom wall 502b, which is provided with a through opening 502c, The two body parts 501 and 502 are coupled together, preferably with interposition of sealing means. In the example, the coupling between the two parts is a threaded coupling, and for this purpose the cylindrical portion of the part 501 is provided on the outside with a male thread, designed for engagement with a corresponding female thread (not visible) provided on the inner side of the peripheral wall 502a of the body part 502.
At the top of the body part 501 an optical element 503 is provided, in particular having functions of optical prism. For this purpose, the body part 501 may be shaped so as to define positioning or spacer elements 501c for the optical element 503. The optical element 503 may, for example, be made of polycarbonate, or of other material transparent to the light radiation emitted by the emitter 270a′. In the example, the element 503 has a front wall 503a, a peripheral wall 503b, and a rear wall 503c, the latter being designed to face the emitter 207a′ and the receiver 207b′. In the example, the optical element has an at least approximately frustoconical shape, but this does not constitute an essential characteristic.
Designated by 504 is a shaped annular sealing element, which is designed to be set between the optical element 503 and the body part 502; the through hole of the sealing element 504 preferably has a profile congruent to that of the peripheral wall 503b of the optical element 503, and hence, in the example, a substantially frustoconical profile. As may be appreciated from the figures, in the assembled condition of the sensor 500, the sealing element 504 is arranged in such a way as to provide a seal between the body parts 501502 and the optical element 503, so that the front surface 503a of the element 503 can face a liquid, through the opening 502c in the body part 502, without any risks of infiltration towards the inside of the sensor 500.
In various embodiments, operation of the sensor 500 is based upon the optical laws linked to refraction/reflection of optical radiation, and in particular on the principle of the critical angle of total reflection. More in particular, such an operating principle is based on the dependence of the refractive index of the liquid substance upon its composition or concentration: the measurement is hence based on the jump of index between the liquid to be analysed, i.e., the washing agent, and the solid material of the optical element 503, exploiting the principle of total internal reflection at the interface between the two media.
In
In various embodiments, the emitter 270a′ and the receiver 270b′ have, instead, the respective active parts of emission and reception, respectively, that generally face one another, but are set at an angle with respect to one another, preferably in such a way that the respective axes intersect. The concept is illustrated schematically in
From
In operation, the emitter 207a′ illuminates the interface surface—represented by the front surface 503a of the element 503—at the angles of interest around the critical angle, and hence with an incidence greater and smaller than the critical angle. In this way, it is possible to identify two areas: an area affected by the totally reflected rays (linked to those with incidence greater than the critical angle), and an area affected at lower intensity, which is illuminated by the partially reflected rays (linked to those with incidence less than the critical angle). It is thus possible to obtain, at the exit, a field of intensity in which separation between the area markedly illuminated by total internal reflection and the area less illuminated (partial reflection) varies as a function of the concentration of the liquid.
The rays used for the merely explanatory and schematic representation appearing in
In the presence of a washing agent or other substance having a first composition or concentration, it is possible to have the case represented schematically in
As may be seen, in practice, the optical element 503 is configured to contribute to propagation of the optical radiation by refraction and/or reflection from the at least one emitter 270a′ to the at least one receiver 270b′, in such a way that the radiation is at least in part propagated through the element 503 towards the at least one receiver 270b′ with an angle and/or with an intensity that varies as a function of a qualitative characteristic of the liquid substance.
Of course, on the basis of the principles set forth above, the optical sensor 500 can also be used as level sensor. In fact, in the absence of liquid at the interface wall 503a, the light beam emitted by the emitter 270a′ will be practically completely reflected towards the receiver 270b′, whereas, in the presence of liquid at the interface, part of the light beam will be refracted in the liquid, striking the receiver 270b′ with reduced intensity. In this way, it is possible to discriminate whether the liquid substance is above or below a pre-set threshold level. Of course, the level-detection function could be obtained even without exploiting the principle linked to the critical angle of total reflection; i.e., it could be based upon the simple reflection/refraction of the optical radiation.
In various embodiments described previously, a device for detecting the level and/or at least one qualitative characteristic of a washing agent is set at least in part at an inlet of a dispenser part, or in a corresponding housing connected in fluid communication with the aforesaid inlet. In other embodiments, such a sensor device may, instead, be set at least in part in a corresponding detection chamber, even in a remote position with respect to such an inlet, and not directly connected to a corresponding arrangement for delivery of the washing agent. In embodiments of this sort, a tank has a detection opening, which may be coupled in a separable and fluid-tight way with respect to an inlet opening present in the fixed dispenser part, the inlet opening being in fluid communication with the detection chamber. The detection opening and the inlet opening of the detection chamber are defined in respective walls of the removable and fixed parts of the dispenser, respectively, which are designed to face one another in the operating condition of the dispenser.
Embodiments of this sort are exemplified in
In the case of
Of course, the idea of locating at least part of a sensor device in a detection chamber can be used also in the case of some other types of sensor, such as the piezoelectric sensors or the optical sensors described previously.
In various embodiments, a level-sensor device and/or quality-sensor device has a first part mounted on the removable dispenser part and a second part mounted on the fixed dispenser part, the first part and the second part preferably interacting by means of an electromagnetic or inductive signal or field.
An embodiment of this sort is illustrated schematically in
The housings 112″ and 210″ may have a tubular structure similar to the one described previously with reference to the outlets 112, 113 and to the inlets 210, 2011, and can hence be coupled in a releasable way so that—in the condition where the removable dispenser part 101 and the fixed dispenser part 200 are coupled together—the bottom walls 112b″ and 210b″ substantially face one another. As may be appreciated, in this case, the housings 112″ and 210″ are then closed at the rear and, given the presence of the bottom walls 112b″ and 210b″, the housings themselves are not connected in fluid communication and do not belong to an arrangement for dispensing of the washing agent contained in the tank R1.
The principle of transmission/reception of data between the sensing element 270″, i.e., its circuit 270a″, and the communication part 270b″, i.e., its circuit, may be of a type similar to that of passive electrical radio-frequency devices without autonomous supply, for example, RFID devices, which, for this purpose, comprise respective antennas. These radio-frequency devices are in themselves known and do not call for an in-depth description herein.
Here it will suffice to point out that the supply voltage of the circuit 270a″ is supplied by the circuit of the part 270b″, which is operative for generating in a known way an electromagnetic field, for example, via a 125-kHz signal; in practice, the electromagnetic field induces a supply voltage, which can in turn transmit data to the circuit of the part 270b″. On this basis, then, via the sensing element 270″ level and/or quality detections similar to the ones described previously may be made and communicated in wireless mode to the reading part 270b″, which in turn makes them available to the circuit arrangement on board the dispenser or the dish-washing machine 1.
As mentioned previously, in various embodiments, the dispenser includes at least a part that can be operated manually by a user, and a locking/unlocking arrangement, which is controllable to prevent or enable displacement of the operable part between two positions thereof. An embodiment of this sort has been exemplified previously for the hatches 1041, 1042 that equip dispensers according to various embodiments described.
Such a locking/unlocking system can advantageously be used also in order to preventing or enable, according to the cases, removal of the removable part of the dispenser with respect to its fixed part, the removable part providing the part that can be operated by the user. In this case, the locking mechanism of the arrangement includes at least one retaining element mounted on the fixed dispenser part in a displaceable way between a retaining position and a release position with respect to a retaining counter-element present on the removable dispenser part.
A possible implementation in this sense is illustrated schematically in
With initial reference to
The seats 121 are configured and positioned in such a way that, when the movable dispenser part 100 is coupled on the fixed dispenser part 200, at least part of each retaining element 206c can project into the corresponding seat 121, with the possibility of angular movement between the retaining position and the releasing position. This angular movement is obtained through the corresponding angular movement of the locking elements 2061, 2062, to which the retaining elements are fixed in rotation. In the example, an element 206c and the corresponding seat 121, on one side, and the other element 206c, and the corresponding seat 121, on the other side, are shaped in a different way, considering that the angular positions of retaining and releasing of the two elements 206c are different. However, in possible variant embodiments, the retaining elements, on one side, and the corresponding retaining counter-elements, on the other side, could be the same as one another.
As may be appreciated also from
Finally,
Control of the actuator 450 for the purposes of the obtaining the positions of
The operating condition of the locking/unlocking arrangement of
In the example of
It should also be noted that, in possible variant embodiments, the locking/unlocking arrangement could be devised to interact with the coupling/uncoupling arrangement operating between the removable dispenser part and the fixed dispenser part (see, for example, what is described with reference to
For instance, with reference to
From the foregoing description the characteristics and advantages of the dispenser of washing agents according to the embodiments proposed emerge clearly, amongst which the following should be emphasized:
i) the solution of providing a reversible peristaltic pump, with a command arrangement associated thereto, makes it possible to use the pump itself for the purposes of delivery of two different washing agents, via two different dispensing arrangements;
ii) the solution of providing a removable dispenser part defining at least one tank, the outlet of which is provided with an automatically driven non-return valve, makes it possible to prevent risks of dispersion in the environment of the corresponding washing agent, when the removable dispenser part is removed from a fixed dispenser part;
iii) the solution of providing on the front of the dispenser a purposely designed housing for a tablet of washing agent that is directly exposed simplifies production of the dispenser as compared to the prior art and at the same time simplifies the activity of loading-in of the tablet by the user;
iv) the solution of providing a signalling system, with a light-generation element on a fixed dispenser part, and one or more light-transmission elements on a removable dispenser part, makes it possible to transfer effectively information of an optical type at the front of the dispenser, to the benefit of the user, and at the same time enables positioning of the components subject to electric voltage in a protected area of the dispenser;
v) the solution of providing a locking/unlocking arrangement for a part of the dispenser which is operable by a user, with the arrangement that is managed by a corresponding logic implemented in a control circuit, makes it possible to reduce the risks of error by a user in the use of the dispenser, in particular as regards topping-up with washing agents or else removal of a dispenser part to enable interventions thereon only when actually necessary;
vi) the solution of providing at least part of a sensor device on a fixed dispenser part, in particular at an inlet thereof for a washing agent, makes it possible to make detections of a quantitative type and/or of a qualitative type as regards the contents of a tank defined in a removable dispenser part, and at the same time makes it possible to simplify the electrical connections, as well as positioning of the connections in a protected area of the dispenser;
vii) the solution of equipping the dispenser with a sensor device pre-arranged for detecting one or more qualitative characteristics of a washing agent makes it possible to provide information concerning the type or quality of a washing agent contained in a corresponding tank, which are, for example, useful in order to prevent or correct any possible malfunctioning due to errors of a user in relation to the type of washing agent or a degradation of the latter, or in order to enable a more efficient control of a treatment program carried out by the dish-washer on which the dispenser is installed.
It should again pointed out that the technical solutions of points i), ii) and vii) can be implemented also in dispensers that do not include removable parts, i.e., ones that have a dispenser body that is as a whole designed to be installed in a fixed position.
It is clear that numerous variations may be made by the person skilled in the branch to the dispenser described by way of example, without thereby departing from the scope of the invention.
Previously, reference has been made to a system for dispensing of a washing agent, in particular the washing agent contained in the tank R2, operation of which is in part based upon displacement of the mounting wall of the dispenser 10 between a substantially vertical position and a substantially horizontal position (see in particular what is described with reference to
A number of sensing elements described previously with reference to different types of sensor may be combined in single sensor device. In this perspective, for example, one and the same sensor device could include both electrodes for detection of an electrical quantity and a piezoelectric element for detection of a physical characteristic (viscosity or density), or else at least one light emitter and at least one light receiver for a detection of an optical type.
Number | Date | Country | Kind |
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102020000013468 | Jun 2020 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2021/054924 | 6/4/2021 | WO |