Patent Application
20250018727
The present invention relates to a system for recirculating ink, or the like, for printing equipment, in particular inkjet, and equipment comprising said recirculating system.
The present invention refers to the technical field of machines for printing on supports of various kinds, such as paper, cardboard, textile materials, metal materials, wood materials, plastic materials, minerals or the like.
Equipment is known in the art, which comprises at least one tank for a printing material, such as paint, ink, or other types of enhancing materials. In particular, printing equipment is known, which has a plurality of tanks, each dedicated to a distinct color, varnish or enhancing material.
The printing material, taken from the tank, is delivered to a recirculation unit, which has the function of circulating the printing material through a printing head. In the prior art it is known that the recirculation of the printing material is necessary due to the tendency of the various printing materials to deposit and/or sediment, becoming unusable for printing and forcing a machine stop for cleaning operations and replenishment of new printing material.
Patent application EP2875956A1 by the same applicant describes a printing equipment comprising a printing head for printing a printing material on a support, and a recirculation unit. The recirculation unit comprises a first container, a second container, a first recirculation device for generating a first flow of said printing material from said first container towards said printing head and a second container, and a second recirculation device for transferring the printing material from the second container to the first container. In particular, the first container of the printing material is maintained at a first negative pressure, i.e. lower than atmospheric pressure, while the second container is maintained at a second negative pressure, i.e. lower than the pressure of the first container.
Patent application IT201600107827A1 also describes a printing equipment similar to that described in document EP2875956A1. In these documents, the heating of the ink provided in the recirculation chambers of the recirculation system takes place by means of thermal energy generation elements, particularly powered by electrical energy.
In currently known printing equipment, the recirculation system comprises thermal conditioning devices connected to at least one of the containers of the recirculation system to modify the physical characteristics, for instance temperature and viscosity, of the printing material circulating through the printing head. The thermal conditioning devices can comprise a temperature regulation system, for instance made with a heat transfer circuit, capable of modulating the temperature of the ink contained in at least one of the containers of the recirculation system itself, for instance by heating and/or cooling.
The heating element can comprise, for instance, an electric resistance as shown in a thermo-conditioning circuit, or other device suitable for the purpose.
Conditioning devices known in the state of the art can comprise, in combination with heating elements, also cooling elements to induce in at least one of the containers of the recirculation system a cooling of the printing material contained therein and adjust its temperature to that used by the printing head.
The temperature regulation system typically comprises a control unit, for instance a PLC which executes a control program of the ink thermal parameters state, which are measured by one or more sensors, and which control the operation of the thermal conditioning according to the achievement of the desired thermal conditions. This control unit comprises a plurality of electronic circuits typically assembled on electronic boards and the electronic components generate heat which must be dissipated, so that cooling systems are generally provided for the control unit or for the electronic components thereof.
The recirculation systems, and in a more general way the printing equipment comprising these systems are therefore relatively energy-intensive and above all in the context of the use of printing equipment for manufactured articles industrially manufactured (for instance painting of pieces, such as elements of furniture, covering elements and other products) energy consumption has become a very important parameter for the production cost and therefore for the cost of the finished product.
There is therefore an unsatisfied need to provide printing equipment, in particular of the industrial type, which can improve energy saving performance, for instance by avoiding the dissipation of energy into the environment.
At the state of the art, in fact, as described in the aforementioned documents, there are no solutions that are intended to optimize the energy consumption of printing equipment.
The present invention therefore has the purpose of realizing an ink recirculation system in printing equipment of the aforementioned type which allows overcoming the drawbacks present in the state of the art.
According to a first embodiment, the present invention solves the aforementioned problem, thanks to the provision of a system for recovering the heat generated by the electronic components of the control unit or part of said control unit and using this thermal energy for thermal conditioning, i.e. heating of the printing material, of the ink or the like, present in the recirculation system.
As will appear later on, this heat recovery system generated by the electronic units present in the printing equipment can be provided as the only heating system or it can be combined with the heating systems already known and provided in the state of the art and also to cooling systems already known and provided in the state of the art. In this case, especially in combination with traditional heating systems, the heating through the thermal energy recovered from the electronic components present in the printing equipment can operate in synergy with the traditional heating systems, for instance by carrying out a preliminary heating which raises the temperature of the ink with respect to that of the surrounding environment, whereby any further heating required to bring the ink to the working temperature of the printing head is performed by said conventional heating elements. In this case, the energy consumption necessary for these elements is less than what would be necessary in the absence of preventive heating by recovering thermal energy from the cooling processes of the printing equipment electronics.
In particular, the present invention solves the aforementioned problem with a recirculation system for ink, or the like, which has the combination of characteristics of the independent claim 1.
The recirculation system according to this claim comprises, in thermal contact with the ink containment compartment, at least one heat exchange chamber which is inserted in a circulation circuit of a heating fluid, said circuit comprising a further heat exchanger in thermal contact with one or more electronic circuit parts of the printing equipment, such as for instance one or more electronic boards and/or with one or more electronic components and/or with one or more thermal dissipators of said electronic components.
Said at least one heat exchange chamber comprises at least one inlet and at least one outlet for a flow of heating fluid, said inlet and said outlet being respectively connected to at least one outlet and to at least one inlet of said at least one heat exchanger of a cooling unit of one or more components of a control unit, which at least one heat exchanger is in thermal contact with one or more of said components, in particular one or more said electronic circuit components of the control unit and/or of the printing equipment.
According to a preferred embodiment, the recirculation system comprises at least two heat exchange chambers which are in thermal contact with at least one of the containers of the recycling system and between said heat exchange chambers said at least one container is interposed.
Again according to a preferred embodiment, the recirculation system comprises three or more heat exchange chambers which externally surround said at least one container of the recirculation system on three or more sides.
According to one embodiment, said heat exchange chambers can be separated from each other and connected at least for a part of them to a common heat exchanger in thermal contact with one or more parts of the electronics of the printing equipment or each of said chambers is connected to a dedicated heat exchanger in thermal contact with said one or more electronic parts of the printing equipment.
According to a variant embodiment, all or at least a part of the heat exchange chambers associated with said at least one container are mutually communicating, at least one inlet for the heating fluid being provided to said heat exchange chambers and at least one outlet from said heat exchange chambers.
In a preferred embodiment, the recirculation system comprises two containers which are provided side by side and optionally with a common intermediate separation wall, while a heat exchange chamber is provided for each container which is arranged along the external side wall of the respective container and is separated from the compartment of the corresponding container by said side wall of the same which is common to said container and to the heat exchange chamber.
In a further possible embodiment, a further third heat exchange chamber is provided in an intermediate position between them, in an area wherein the wall separating the two containers is divided into two independent branches.
One embodiment provides that at least one further heat exchange chamber is provided in the area of the bottom of said two containers at said separation wall common to the two containers divides into two mutually diverging branches and at the same time it forms the common separation wall from said further heat exchange chamber.
According to an advantageous embodiment, the two containers of the recirculation system and the associated heat exchange chambers with a heating fluid are made in a single body with continuous walls, i.e. a one-piece body, being envisaged for manufacturing an Additive Manufacturing process.
When an anti-sloshing element is provided, thanks to the additive manufacturing process it is possible to make together with the containers also further construction parts of the containers and/or of the heat exchange chambers, including, for instance and not limited to, the pipe unions for connection to the supply and outlet pipes of the heating fluid which can be shaped, directly and without further processing or without providing for the connection of separate parts, with the profiles provided for coupling to the connection terminals of said pipes, in particular to the connectors of so-called Luer couplings.
The advantages of the present invention appear evident from the previous description and will emerge more clearly from the following description of some embodiments illustrated in the attached drawings.
These advantages consist first of all in the fact of being able to recover a considerable amount of energy which would in any case have to be dissipated to avoid overheating of the electronic units present in the printing equipment.
Added to this advantage are the advantages relating to the specific embodiment relating to the energy recovery system, i.e. heating the ink or optionally preheating the ink or other printing material.
In fact, the structural configuration of the containers of the recirculation system and of the heat exchange chambers of the ink with the heating fluid offers optimal heat exchange conditions. This configuration can be obtained in a simple and relatively cheaper way using production processes of the Additive Manufacturing type which allow the creation of single-piece construction parts, i.e. in a single body wherein cavities of relatively complex shapes are provided and difficult to obtain with current production systems.
The characteristics of the present invention indicated above as well as any further characteristics object of the dependent claims, as well as the advantages deriving from said characteristics are described in greater detail in relation to an embodiment illustrated in the attached figures wherein:
Detailed descriptions of embodiments of the invention are provided herein. It is to be understood, however, that the present invention may be embodied in various forms. Therefore, the specific details disclosed herein are not to be interpreted as limiting, but rather as a representative basis for teaching one skilled in the art how to employ the present invention in virtually any detailed system, structure, or manner.
According to the embodiment shown, the printing equipment 10 comprises a feeding device 11 which has the purpose of feeding the printing material, i.e. the ink or a varnish or other type of printing material, towards a recirculation unit 15 which generates a continuous recirculation of the printing material in a printing head 13. The recirculation unit 15 for case of description is divided into two recirculation sub-units, a first sub-unit 16 and a second sub-unit 17.
The printing head 13 can be controlled in a known way to deposit the printing material, i.e. the ink, or the like, on the printing support (not shown in detail since it is not the subject of the present invention), according to a predetermined pattern.
According to a preferred embodiment, the feeding device 11 comprises an accumulation tank 12 wherein the printing material according to one or more of the variants defined above is contained, before being used for printing, and a first device for pumping unit 22 for transferring the printing material from the storage tank 12 to the recirculation unit 15. The tank 12 is connected to a filter device 21 via a pipe 41. The pumping device 22 draws the ink from the storage tank 12 through a first suction pipe 41, and coveys it to the recirculation unit 15 through a second pipe 42.
In one embodiment, the feeding device 11 can furthermore comprise a mixing device 30 for periodically or continuously mixing the printing material contained in the accumulation tank 12.
A filtering device 21 can be interposed on the first pipe 41 and/or on the second pipe 42, for instance in the form of a filter or other similar devices.
According to the exemplary but non-limiting embodiment illustrated in
The recirculation system 15 further comprises a second container 18 for the printing material which comes from the printing head 13 via the pipe 43b. In a preferred embodiment, the second pipe 43b is connected to the lower portion of the second container 18, so as to prevent the printing material contained in the second container 18 from incorporating air bubbles.
In one embodiment, the first container 14 and the second container 18 for the printing material lie on the same plane and can contain two distinct levels of printing material.
The recirculation system 15 of the exemplary embodiment illustrated is of the pneumatic type and comprises a pair of elements 19, 20 for the generation of negative pressure (in the form of a series of solenoid valves) connected to the first container 14 and to the second container 18 of the printing material. In particular, the elements 19, 20 for generating negative pressure are configured to induce a negative pressure, or vacuum, inside the first container 14 and the second container 18. The elements 19 and 20 operate in such a way as to generate a difference of negative pressure which is established between the first container 14 and the second container 18 and which induces the movement of the printing material from the first container 14 to the second container 18, passing through the printing head 13.
In one embodiment, the elements 19, 20 for generating negative pressure consist of a series of solenoid valves which are assembled on a mechanical block made to exploit the Venturi principle. In particular, the element 19 gives the negative pressure to the first container 14 and the clement 20 gives the negative pressure to the second container 18; the two negative pressures are different between the two containers 14 and 18 of the printing material.
Typically, the negative pressure value inside the first container 14 for the printing material is equal to −4 kilopascals, while the value inside the second container 18 for the printing material is equal to −10 kilopascals. This pressure difference triggers the passage of the printing material from the first container 14 to the second container 18 passing through the printing head 13.
By acting on the two negative pressure generation elements 19 and 20, it is possible to vary the negative pressure inside the containers 14 and 18 of the printing material. Indicatively, the negative pressure values that can be achieved vary between 0 and −50 kilopascals.
Different printing heads and different printing materials require setting up the negative pressures in the first 14 and second 18 printing material container.
The negative pressure values are detected by a pressure sensor 50 which detects the negative pressure values in the containers 14 and 18 of the printing material. The detected values are then sent to a control unit 33 which drives the elements 19 and 20 so as to obtain the desired negative pressure values.
Furthermore, the elements 19 and 20 have a further valve (not shown) which allows the cleaning of the printing head 13 with positive pressure, by modifying the pressure inside the containers 14 and 18 of the printing material. Obviously, the cleaning cycle, which involves feeding the printing head 13 with positive pressure, is performed when the machine is not printing.
According to one embodiment, there are two overflow tanks 25a, 25b which are interposed between the first container 14 and the second container 18 of the printing material, for instance in an intermediate position along a first connecting pipe 46 and a second connecting pipe 47.
In particular, it is envisaged that in the tank 25a, connected to the first container 14, the air is placed in a negative pressure condition, and also in the tank 25b, connected to the second container 18, a negative pressure condition is generated.
The tanks 25a, 25b can be provided with discharge valves, not shown in the drawings, of the condensate that may be generated, or of any printing material that may be present inside them. Furthermore, the tanks 25a, 25b can be provided with sensors for detecting the printing material which, if activated, control or supply a signal for deactivating the elements 19, 20 for generating negative pressure. In this way it is possible to avoid damage to the negative pressure generation elements 19, 20.
In an embodiment of the present invention, the recirculation unit 15 also comprises a second recirculation sub-unit 17 for transferring the printing material from the second container 18 to the first container 14.
The second recirculation sub-unit 17 comprises a pumping device 23 connected, via a pipe 28, to the first container 14 and to the second container 18, to transfer the printing material from the second container 18 to the first container 14.
In a preferred embodiment, the suction pipe 28 is connected with one of its first ends to the lower portion of the second container 18. This embodiment prevents air from being sucked in through the suction pipe 28.
The pipe 28 connects the pumping device 23 to the second container 18 of the printing material, while a pipe 45 connects the pumping device 23 to the first tank 14 of the printing material. In a preferred embodiment, the pipe 45 is connected with one of its first ends to the lower portion of the first container 14. This embodiment prevents air from being sucked in through the pipe 45.
In one embodiment, at least the delivery pipe 45 is provided with a filtering device 59 intended to filter the flow of printing material which is introduced from the second container 18 into the first container 14. Furthermore, the presence of the filtering device 59, in case of breakage of the membrane of the pumping device 23, prevents unwanted particles from ending up in the first container 14 of the printing material, and from there in the printing head 13 damaging it.
In one embodiment, detection devices 56 are provided which comprise a first level sensor for detecting the ink level in the first container 14, and a second level sensor for detecting the ink level in the second container 18.
The first level sensor and the second level sensor can be selected from a group comprising optical sensors, magnetic sensors, inductive sensors, capacitive sensors, floating elements, or possible combinations thereof.
In one embodiment, the recirculation system 15 comprises conditioning devices connected to at least one of the first 14 and second 18 containers to modify the physical characteristics, for instance temperature and viscosity, of the printing material circulating through the printing head 13.
The conditioning devices can comprise a temperature regulation system, for instance made with a heat transfer circuit, capable of modulating the temperature of the ink contained in at least one of the first 14 and second 18 containers, for instance by heating and/or cooling action.
The conditioning devices comprise for instance a heating element 52 assembled externally to the first 14 and second 18 containers of the printing material to heat the printing material contained in the latter according to predetermined methods.
As shown in
Several possible configurations of this heating system are envisaged, which will be described in greater detail below.
According to a possible embodiment and as shown in the diagram of
In a further embodiment variant, the conditioning devices comprise, in combination with one or more of said heating elements, also a cooling element 61 to induce in at least one of the first 14 and the second 18 containers a cooling of the printing material contained therein and adjust its temperature to that used by the printing head 13.
An example of a cooling element 61 can comprise a fluid-dynamic conditioning circuit which exploits the principles of a refrigeration cycle.
The ink heating circuit which operates by heating said ink by means of the thermal energy taken from the electronics of the printing equipment during the cooling process of said electronics can operate alternatively or in synergy with further heating and/or cooling devices.
In particular, a synergistic function is possible wherein a preheating phase of the ink is carried out with the thermal energy taken from the electronic circuits when they cool down, for instance at a temperature between room temperature and the optimal working temperature, while the ink is further heated with one or more further heating elements to pass from said intermediate temperature to the working temperature.
Due to this, the energy consumption due to the cooling of the electronic circuits is partially compensated by using the thermal energy dissipated for the pre-heating of the ink, while the energy consumption for the heating with the additional traditional heating elements and in any case limited due to the fact that the ink has been preheated from room temperature or from a starting temperature it would have had in the absence of the preheating action.
The printing equipment comprises a control unit 33, in particular a PLC, to monitor and manage at least the operating modes of the first recirculation subunit 16 and of the second recirculation subunit 17. In particular, the control unit 33, also as a function of the signals detected by the first level sensor and by the second level sensor, is capable of suitably managing the activation of the first pumping device 22 and of the pumping device 23 to maintain in the first container 14 and in the second container 18 a predetermined level of printing material in order to guarantee the correct supply of the printing head 13.
In one embodiment, the control unit 33 is connected with the components of the equipment 10 to be controlled and managed through electrical connections, such as electrical cables or electrical tracks (not shown), in case the control device comprises integrated boards, or PCB 300 (see for instance
According to a further embodiment, the control unit 33 can be made dependent on interface devices 34 with a human user to allow the latter to selectively set some parameters relating to the recirculation of the printing material and monitor alarms and anomalies.
According to a variant embodiment, the interface devices 34 can be external to the printing equipment 10, for instance made using an electronic computer, such as a PC, or similar device.
Even if the present invention has been described with reference to a printing equipment 10 comprising a single printing head 13, it is evident that the same recirculation device can be applied to a printing equipment comprising several printing heads 13 as shown in
In an embodiment, as shown in
However, executive variants are also possible wherein for each printing head 13 its own recirculation system 15 is provided similarly to what has been described above.
Typically, in printing equipment of the aforementioned type, the printing heads 13 and also at least part of the corresponding recirculation system 15, in particular the first and second containers 14, 18 are assembled on a slide or a trolley and are translatable along a guide, forwards and backwards, between two extreme positions. In this way the printing head or heads 13 can cover relatively large dimensions of print media. Generally, the translating direction is perpendicular to the advancing direction of the substrate.
According to one embodiment, the boards 300 are provided in combination with a system for cooling them consisting of one or more heat exchangers 310 which are in thermal contact with the boards themselves and which transfer the thermal energy from the boards to a heating or preheating fluid which is fed through ducts 320 to heat exchange chambers 430, 440 which are in thermal contact with the containers 14, 18.
Preferably, the supply circuit of the heating fluid to the heat exchange compartments 430, 440 associated with the containers 14 and 18 is of the type capable of allowing said heating fluid to recirculate between said heat exchange compartments 430, 440 and the exchangers 310. The heat exchange compartments 430, 440 can consist of a single chamber which surrounds at least part of the outer wall of the containers 14 and 18, or they can be compartments completely separated from each other or communicating through communication passages.
Furthermore, some heat exchange compartments can be further connected to a cooling fluid supply circuit.
According to a variant embodiment, the supply circuit of the heating fluid to the heat exchange chambers 430, 440 has a return branch 330 from the heat exchange chambers 430, 440 to the heat exchangers 310 with the electronic boards 300. This is straight as indicated in 330.
An alternative embodiment can provide that the return 330 feeds the heating fluid to a further heating system 350 which can be of any type, such as for instance a heat pump heating system or another type.
The system 350 can be provided in series or even in parallel with the heat exchangers 310.
Furthermore, although not illustrated in detail, the heating system referred to in the variants of
Furthermore, it is possible to provide said additional heating system alternatively or also on the delivery 320 of the heating fluid from the heat exchangers 310 with the boards 300 to the heat exchange chambers 430, 440 of the containers 14, 18 of the recirculation system 15.
The containers 14 and 18 of the recirculation system 15 follow this reciprocating movement and the ink contained therein is subject to sudden decelerations and accelerations which involve a sloshing of the ink in said containers, with the consequent swaying of the surface of the mass of ink and with potential dangers of degeneration of the ink due to possible air inclusions and/or even mechanical effects on the material mixtures that make up the inks themselves.
According to the present invention and as shown in
The production technique known as Additive Manufacturing has proved to be advantageous for this production.
Thanks to this technology, as shown in
The anti-sloshing elements indicated with 400 in
Different embodiments of the anti-sloshing elements 400 are possible.
In particular, and without this constituting a limitation, but only by way of example, the containers according to the present example are intended to perform reciprocating translational movements in the transversal direction to the side walls of the same, or in a parallel or substantially parallel direction, relating to the sectional plane of
The illustrated non-limiting embodiment provides that said anti-sloshing elements consist of a plurality of bulkheads 401 which extend mainly transversely to the translating direction of the containers 14, 18.
According to the illustrated embodiment, the bulkheads can be parallel to each other and laterally equidistant, the distance being mainly defined by the number of bulkheads 401 provided.
The bulkheads 401 are held in position between crosspieces 402 in the form of rods transverse to the surface extension of the bulkheads themselves.
Advantageously and preferably, the compartments 403 into which the chamber or part of the chamber of the containers 14, 18 is divided communicate with each other.
Communication between compartments can take place due to different configurations of the bulkheads which can also comprise through windows, from side to side, distributed along their surface extension.
In the illustrated embodiment, the compartments 403 formed by the bulkheads 401 are open at least along one of the perimetral edges of the bulkheads themselves, for instance at least along the lower and upper edges of the bulkheads 401.
According to one embodiment, the anti-sloshing elements 400 are provided only in some areas of the chambers of the containers 14, 18, in particular approximately in the lower half of said containers 14, 18.
In the illustrated embodiment, communication between the compartments 403 delimited by the bulkheads 401 takes place due to the fact that said bulkheads end with at least part of their peripheral edges at a certain distance from the wall of the container 14, 18, thus defining passages between compartment and compartment 403.
Again according to an embodiment, the bulkheads 401 are arranged substantially vertically and divide the chamber into compartments 403 interposed between the two opposite side walls of the containers, between which the crosspieces 402 extend.
A possible embodiment instead provides opposite fins which branch off from opposite walls delimiting the container and which end at a certain distance from each other in an intermediate region of the same, forming an intermediate slot. The fins have a predominantly horizontal directional component and are slightly sloping towards the bottom in the direction of the intermediate slot. Preferably the fins are perforated, or grid shaped.
As is evident from
For at least one sector 421 of the converging jacket side walls of said funnel shape of the bowl or well 420, the slope of said jacket wall 421 is relatively steep, i.e. it has a preponderant directional component which is oriented parallel to the vertical direction or to the axis of a discharge opening 422.
The funnel shape of the bowl or well 420 according to a preferred, but non-limiting embodiment variant is asymmetrical, said discharge opening 422 being provided laterally offset in the direction of a side wall of the corresponding container 14, 18 and in detail, but not as a limitation, of the jacket wall of the corresponding outermost container 14, 18. In this way, at least one sector 423 of the jacket wall of the funnel-shaped bowl or well 420 has a substantially vertical direction without deviating substantially from the extension direction of the jacket wall of the container 14, 18, while at least the diametrically opposite sector 421, with reference to the discharge opening 422 is sloping with respect to the vertical direction towards the opposite sector 423.
With reference to a further characteristic, externally to at least a part of the boundary wall of the containers 14, 18 and preferably, but not as a limitation externally to at least a part or all of the outermost side of the jacket wall of said containers 14, 18, for each container 14, 18 a chamber 430 for containing and optionally also for flowing of a heating fluid is provided.
Said chamber 430, i.e. the walls delimiting it, are made in one piece, i.e. they form a single body, with the walls of the containers 14, 18.
The cross-sectional plane of
According to yet another embodiment, visible in the figures, it is possible to provide additional heat exchange chambers, such as the one indicated with 440 and provided in a non-limiting way in an intermediate position between the two containers 14 and 15, and in particular between the two funnel-shaped bowl or well extensions on the bottom side of the same.
The additional heat exchange chamber can be used for the heat exchange of the containers, i.e. of the ink contained in them with a cooling fluid.
Alternatively, it is possible to modify the fluid supply circuit in such a way that only a heating fluid or a cooling fluid can be supplied to one or more of the heat exchange chambers or in such a way that depending on the conditioning functions at least some or all of the heat exchange chambers 430 and 440 are required to be alternatively supplied with a heating fluid or a cooling fluid.
Also this configuration of the heat exchange chambers is advantageously obtained thanks to a production process called Additive Manufacturing which allows to make all the walls of the containers and of the heat exchange chambers as well as the anti-sloshing devices as a one-piece body, i.e. as a single body.
With reference to
With reference to
Thanks to this configuration, the heat taken from the boards for their cooling to the desired working temperature, or to preheat it to a temperature closer to the working one.
In particular, the containers 14 and 18 have at least one, generally a plurality of brackets 700 for fixing additional parts, such as the board 710 which can already be made with the specific shape required, without the need for post-processing, and which specifically also have housings 720 of a shape corresponding to the nut screws 730 for tightening the fastening bolts of the electronic board 710.
Similarly a further feature of the containers 14 and 18 according to the present invention and which can be made at low costs by avoiding post-processing with chip removal forming processes, provides that, for instance for fixing the more rigid PE pipes 800 coming from the ink inlet and recirculation pumps, the corresponding pipe unions 810 on the containers 14, 18 have been shaped so as to reproduce the male Luer profiles 811 directly on the pipe unions during the manufacture of the containers 14, 18. This entails a strengthening of the connection and avoids the breakage of the tail piece when fixing the tube.
While the invention has been described in connection with the above-described embodiments, it is not intended to limit the scope of the invention to the particular forms set forth, but on the contrary, it is intended to cover such alternatives, modifications, and equivalents as may be included within the scope of the invention. Further, the scope of the present invention fully encompasses other embodiments that may become obvious to those skilled in the art and the scope of the present invention is limited only by the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 102023000014844 | Jul 2023 | IT | national |
