The present invention relates to a device for the mixing of fluids.
To date several types of device are known for the mixing of fluids, e.g., used to prepare drinks, where syrup or juice concentrate has to be mixed with a diluent, e.g., water, in order to obtain the desired drink.
These devices generally have a first supply line of a first fluid, e.g., water, along which are arranged first valve means adapted to control the flow rate of the first fluid itself, a second supply line of a second fluid, e.g., syrup or juice, along which are arranged second valve means adapted to control the flow rate of the second fluid itself, and mixing means for mixing the two fluids.
In order to obtain a drink flavor which is as reproducible as possible over time, the ratio between the dispensed fluids must be maintained substantially constant.
Some devices for the mixing of fluids are known from U.S. Pat. No. 5,868,279, US 2004/0084475 and U.S. Pat. No. 6,450,369, to name just a few.
In particular, U.S. Pat. No. 5,868,279 provides that along each of the supply lines be arranged relative normally-open valves and that downstream of these a flow meter be present adapted to send a signal to relative control means programmed to close the valves when the detected flow rate exceeds a predefined value.
Once the desired ratio between the fluids has been found to have been complied with, the control means reopen the previously closed valves.
The device described by U.S. Pat. No. 5,868,279 then performs a discrete type of control of the flow rate of the fluids, i.e., the moment the flow rate of one of the two fluids reaches the relative reference value, its dispensing is interrupted while that of the other fluid is kept active until the ratio between them has reached the required value.
The flow rate of the fluids is therefore adjusted by acting on the corresponding valves, closing them.
US 2004/0084475 describes a system for dispensing drinks in which a measurement is taken of the flow rate of the syrup, by means of a pressure sensor and a temperature sensor, and of the flow rate of the water, by means of a flow rate sensor, the signals of which are sent to a control device adapted to operate the relative valves in order to obtain the required ratio between the flow rates of the dispensed fluids.
In particular, the control device performs a modulation of the valves of the Pulse Width Modulation type (PWM) which varies the current flowing inside the valve coils and changes the magnetic field and the position of the valve shutter according to the flow rates detected and the preset ratio.
U.S. Pat. No. 6,450,369 describes a device for dispensing drinks which provides for a single piston placed between the fluid dispensing lines and the mixing means and adapted to regulate the dispensing of both fluids.
In particular, such device provides for the detection of the flow rate of both fluids and the feedback control of the water flow rate, by means of the aforementioned piston, according to the measured flow rate of the syrup in order to obtain a predefined ratio between them.
These known devices have some drawbacks.
They do not in fact allow a precise and rapid feedback control of the fluid flow rates. More in detail, the flow rate control performed by adjusting the opening time of the relative valves does not allow, also because of the response times of the relevant shutters, to carry out an effective feedback control of the flow rate of the fluids.
This limit of the devices of known type generally translates into low reproducibility over time of the flavor of the dispensed drinks, which can therefore affect appreciation by consumers.
Generally, the bigger the operating pressure and the viscosity of the dispensed fluids, the more evident this drawback is.
To this must be added the fact that the devices of known type have low if not zero capacity to regulate the flow rate of the two fluids and to maintain the desired mixing ratio with the variation in pressure and temperature of the fluids themselves.
The main aim of the present invention is to provide a device for the mixing of fluids which allows effectively performing the feedback control of the flow rate of the fluids.
Within this aim, one object of the present invention is to control, in a substantially continuous way, the flow rate of the dispensed fluids and their ratio.
Another object of the present invention is to reduce the head losses in the fluids during the crossing of the valve means, in order to curb the turbulences and loss of carbonation when the fluids are gassed.
Yet another object is to provide valve means that have quick and precise actuation and at the same time to avoid any sugar component contained in the syrup resulting over time in the formation of residues that hinder the shifting of the relative shutters.
A further object of the present invention is to provide a device for the mixing of fluids which allows:
Another object of the present invention is to provide a device for the mixing of fluids which allows overcoming the mentioned drawbacks of the prior art within the ambit of a simple, rational, easy, effective to use and affordable solution.
The above mentioned objects are achieved by the present device for the mixing of fluids according to claim 1.
Other characteristics and advantages of the present invention will become better evident from the description of a preferred, but not exclusive, embodiment of a device for the mixing of fluids, illustrated by way of an indicative, but non-limiting, example in the accompanying drawings, wherein:
With particular reference to such figures, globally indicated by reference numeral is 1 a device for the mixing of fluids, in particular for the production of drinks or the like.
The device 1 comprises a base frame 2 mountable, e.g., inside a drink dispensing machine not shown in detail in the illustrations because it is of known type.
On the base frame 2 is mounted a series of components assembled together so as to define:
The first fluid consists, e.g., of water, if necessary with the addition of carbon dioxide.
The second fluid consists, e.g., of a syrup or a juice concentrate which, when mixed with water, form a drink.
At least one of the first valve means 4 and second valve means 7, preferably both, comprises a body 10 which defines a receiving chamber 11 of the relative fluid having at least one inlet port 12 and at least one outlet port 13.
Inside of the receiving chamber 11 is arranged at least one shutter 14 movable to put into communication with/isolate from each other the inlet port 12 and the outlet port 13.
The shutter 14 has an abutment surface with a substantially annular shape and adapted to rest on the body 10 at the outlet port 13 to obstruct the flow of the fluid.
In a first embodiment of the valve means 4, 7 shown in detail in
In a second embodiment of the valve means 4, 7 shown in detail in
In this second embodiment, the abutment surface of the shutter 14 is adapted to abut at the outlet port itself and, usefully, the shutter 14 is cup-shaped, is internally hollow and has at least one opening 15 for the flow therethrough of the relative fluid; this way, the flow of the relative fluid is made easier through the valve means 4, 7 when the shutter 14 is moved away from the outlet port 13. Advantageously, the body 10 defines at least one outlet channel 16 for the fluid which extends from the outlet port 13 and which is substantially shaped as a Venturi tube.
At least one of the first valve means 4 and the second valve means 7, preferably both, comprises at least a sealing element 17 adapted to separate in a hydraulically-operated manner the relative control means 5, 8 from the relative receiving chamber 11, thus preventing the fluids from flowing out of the receiving chamber 11 and wetting the control means.
In this regard it is specified that the control means 5, 8 are of the electronic type and must therefore be kept dry.
In particular, at least one of the first control means 5 and the second control means 8, preferably both, comprises at least one command coil 18.
Thanks to the command coil 18, the control means 5, 8 are commandable between an active configuration, wherein they are able to generate a magnetic field to attract the shutter 14 towards the opening position, and a rest configuration, wherein they interrupt the magnetic field and comprise return means 19, of the type of a spring or the like, adapted to counteract the shift of the shutter 14 itself towards the relative opening position.
The device 1 comprises driving means 20 for driving at least one of the first control means 5 and the second control means 8 and adapted to maintain at least a predefined ratio between the flow rate of the first fluid and the flow rate of the second fluid along the relative supply lines 3, 6.
The driving means 20 comprise generation means 21, 22 of an impulsive driving signal 23 by pulses which are adapted to open the first valve means 4 and/or the second valve means 7 for an impulsive opening time T-on and to close the first valve means 4 and/or the second valve means 7 for an impulsive closure time T-off, wherein the ratio between the impulsive opening time T-on and the impulsive closure time T-off for each pulse is constant and the pulses have a variable repetition frequency.
At every opening and closure cycle of the valve means 4, 7, in practice, the duration of the impulsive opening time T-on and the duration of the impulsive closure time T-off may change but always in a proportional way.
In other words, if the impulsive opening time T-on changes, then the impulsive closure time T-off also changes proportionally.
Such pattern is graphically shown in
The impulsive driving signal 23 is usefully made up of a signal of the PFM (Pulse Frequency Modulation) type, in which in practice the duration of the pulses, i.e., precisely intended as T-on/T-off ratio, is fixed and the repetition frequency varies.
The PFM frequency is determined by the system essentially on the basis of the combined action of a feedback integral control error and a reference feed-forward control.
In particular, the generation means 21, 22 comprise at least a pulse (PFM) frequency modulation unit 21 adapted to receive at input a predetermined control signal 24 to be modulated and to return at output the impulsive driving signal 23.
The generation means 21, 22 also comprise at least a control circuit 22 connected upstream of the frequency modulation unit 21, adapted to receive at input at least a reference flow value 25, provided by a management unit, and adapted to generate at output the control signal 24.
The driving means 20 also comprise at least one flow rate sensor 26, 27 arranged along the first supply line 3 and/or the second supply line 6, respectively upstream of the first valve means 4 and/or of the second valve means 7, which is adapted to measure at least one flow value 28 corresponding to the flow rate of the fluids in the supply lines 3, 6.
The control circuit 22 comprises at least one feedback line 29 connected to the flow rate sensor 26, 27, which allows the control circuit 22 to receive at input not only the reference flow value 25 but also the flow value 28 measured by the flow rate sensor 26, 27.
The control circuit 22 compares the reference flow rate 25 and the flow value 28 measured by the flow rate sensor 26, 27, and calculates the control error as the difference between the two and, if necessary, integrates it by means of an integrator.
From the integral control error and from the reference flow value 25, which is nothing more than a feed-forward control, the control circuit 22 provides the control signal 24 to be modulated at output.
The control signal 24 is received by the frequency modulation unit 21 which returns at output the impulsive driving signal 23 having the pulse frequency PFM which depends proportionally on the magnitude of the control signal 24.
The impulsive driving signal 23 thus obtained commands the opening and the closure of the valve means 4, 7.
In this respect, it should be noticed that the command coil 18 of the control means 5, 8 is operatively connected to the output of the generation means 21, 22 and to at least one of the first and second valve means 4, 7.
The command coil 18 is also adapted to actuate at least one of the first and the second valve means 4, 7 at each pulse of the impulsive driving signal 23.
Advantageously, there are two command coils 18, one for the first control means 5 and one for the second control means 8.
Similarly, there are two flow rate sensors 26, 27, of which a first flow rate sensor 26 is arranged along the first supply line 3 and a second flow rate sensor 27 is arranged along the second supply line 6.
The flow rate sensors 26, 27 are preferably of the type without movement.
Number | Date | Country | Kind |
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UB2015A003021 | Aug 2015 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2016/054691 | 8/3/2016 | WO | 00 |