The present invention relates to a machine for brewed beverages, such as coffee, tea or the like.
It is known in the state of the art that water temperature is a fundamental parameter for the correct preparation of brewed beverages. Brewed beverage-making machines comprising devices capable of controlling the temperature of the water used for the preparation of such beverages are therefore known in the state of the art.
Examples of such devices or machines can be found in documents EP0422738, EP1969979 and WO2015056241.
Document EP0422738 describes an apparatus capable of regulating small amounts of water by means of two electrovalves that intercept the hot and cold water ducts.
Document EP1969979 also shows a device characterized by the presence of two ducts, one for conveying hot water and the other for cold water. In particular, the two ducts of EP1969979 are intercepted by two distinct valves controlled to stop and allow the passage of water through the ducts. This document provides instructions on how to mix two distinct flows of cold water and hot water so as to obtain a flow of water at a predetermined temperature.
Finally, document WO2015056241 shows a brewed beverage-making machine comprising a mixing unit, a supply line, a first and a second duct connected to the mixing unit and the supply line. The first and second known ducts are configured to receive cold water from the supply line and send cold or hot water to the mixing unit. The known machine further comprises a pump configured to receive cold water from an external network and supply it to the supply line.
Furthermore, in the prior art, a flow meter is connected to the supply line and placed downstream of the pump, while a heating element is connected to the second duct and is configured to receive cold water from the same duct and supply hot water to the mixing unit.
However, the flow rate of the first and second ducts of the known art is not defined, and its determination would require the arrangement of sensor on the ducts. Such sensors would allow to obtain a control on the mixing of cold and hot water.
In this context, the technical task underlying the present invention is to propose brewed beverage-making machine which overcomes the drawbacks of the prior art.
In particular, it is an object of the present invention to provide a brewed beverage-making machine capable of dispensing water within a temperature range.
It is also an object of the present invention to provide a machine which improves the quality of brewed beverages drinks and which is cheaper.
It is a further object of the present invention to suggest a method for the preparation of brewed beverages that may be performed either with an automatic coffee machine or with a traditional coffee machine (with hand-loaded coffee per dispensing).
The specified technical task and the specified purposes are substantially achieved by a brewed beverage-making machine and a method for the preparation of brewed beverages comprising the technical features set forth in one or more of the claims disclosed herein.
The present invention solves the technical problem. In fact, it is possible to make a brewed beverage-making machine that autonomously regulates the mixing of cold and hot water.
It is also possible to make a more cost-effective and versatile brewed beverage-making machine.
It is further possible to manufacture a brewed beverage-making machine that automatically controls the supply of water according to the contents of the brewing chamber.
Further features and advantages of the present invention will be made clearer by the indicative, and therefore non-limiting, description of a preferred, but not exclusive, embodiment of a brewed beverage-making machine illustrated with reference to the accompanying Figures:
With particular reference to the appended Figures, number 1 denotes a brewed beverage-making machine object of the present invention.
The machine 1 comprises a supply line 2 and a pump 3 configured to receive water at a first temperature from an external source 4 and supply such water at the first temperature to the supply line 2. In particular, said supply line 2 has a branch point 5. The external source 4 may comprise a tank or a water supply network adapted to supply the water at the first temperature to the pump 3. The pump 3 may be configured to receive water at the first temperature from the water supply network or from the tank.
The machine 1 also comprises a flow meter 6 arranged on the supply line 2 between the pump 3 and the branch point 5. Preferably, the flow meter 6 is configured to detect the flow rate of the water at the first temperature through the supply line 2. Again preferably, the flow meter 6 is configured to generate input data representative of the flow rate of the water at the first temperature through the supply line 2.
The machine 1 comprises a mixing unit 7 configured to receive and mix water at the first temperature and water at a second temperature, higher than the first temperature, so as to generate a mixture.
In addition, the machine 1 comprises a first fluid path 8 and a second fluid path 9. The first fluid path 8 and the second fluid path 9 both connect the branch point 5 of the supply line 2 to the mixing unit 7. In particular, the second fluid path 9 is in parallel to the first fluid path 8. In detail, the first fluid path 8 is configured to supply the water at the first temperature to the mixing unit 7. The second fluid path 9 is configured to supply the water at the second temperature to the mixing unit 7.
The machine 1 comprises a heating element 11 arranged along the second fluid path 9 and configured to receive the water at the first temperature from the branch point 5 and supply the water at the second temperature to the mixing unit 7. In detail, the heating element 11 may comprise a boiler configured to raise the temperature of the water from the first temperature to the second temperature, different and higher than the first.
In addition, the machine 1 comprises a first nozzle 12 and a second nozzle 13 arranged respectively along the first fluid path 8 and the second fluid path 9. These first nozzle 12 and second nozzle 13 are configured to define respectively the fluid flow rate along the first fluid path 8 and the second fluid path 9. In other words, the flow rates along the first fluid path 8 and the second fluid path 9 are fixed and defined respectively by the first nozzle 12 and the second nozzle 13.
Advantageously, it is possible to create a brewed beverage-making machine that does not present temperature sensors along the first fluid path 8 and along the second fluid path 9 downstream of the heating element 11.
It is also possible to make a machine 1 which allows to mix a volume of water at the first temperature and a volume of water at the second temperature without the use of pressure or temperature sensors at the mixing unit 7. This is advantageous since it makes the machine 1 cheaper than the brewed beverage-making machines of the known type.
In one embodiment, the machine 1 comprises a first electrovalve 14 and a second electrovalve 15 arranged respectively along the first fluid path 8 and along the second fluid path 9. In detail, the first electrovalve 14 and the second electrovalve 15 are on/off type valves and are configured to be controlled to stop and allow the passage of water along the first fluid path 8 and the second fluid path 9, respectively.
This is advantageous because, by controlling the valves individually or simultaneously, it is possible to adjust the volume of water at the first temperature and the volume of water at the second temperature supplied to the mixing unit 7 through the first fluid path 8 and the second fluid path 9.
Preferably, the first nozzle 12 is arranged along the first fluid path 8 between the first electrovalve 14 and the mixing unit 7. Also preferably, the second nozzle 13 is arranged along the second fluid path 9 between the branch point 5 and the heating element 11.
According to one aspect, the second electrovalve 15 is arranged along the second fluid path 9 between the heating element 11 and the mixing unit 7.
In one embodiment, the machine 1 comprises a control unit 16 which, in turn, comprises an acquisition module 17, a processing module 18 and an actuation module 19.
The acquisition module 17 is in signal communication with the flow meter 6 to receive input data and is configured to receive control data representative of the volume of water at the first temperature to be supplied to the supply line 2. Preferably, the control data are representative of the volume of water at the first temperature and the volume of water at the second temperature to be supplied to the mixing unit 7 respectively through the first fluid path 8 and the second fluid path 9.
The processing module 18 is placed in signal communication with the acquisition module 17 and is configured to generate a regulation signal based on the input data and the control data.
The regulation signal may be representative of the mode of operation of one or more of the pump 3, the first electrovalve 14 and the second electrovalve 15. In particular, this regulation signal may be representative of the operating time of the pump 3 or of the activation time of the first electrovalve 14 or of the second electrovalve 15.
The actuation module 19 is in signal communication with the pump 3 to send the regulation signal and adjust the volume of water at the first temperature supplied to the supply line 2 based on the regulation signal. The actuation module 19 is configured to activate and deactivate the pump 3 according to the adjustment signal to allow and interrupt the supply of water at the first temperature to the supply line 2.
Preferably, the actuation module 19 is placed in signal communication with the first electrovalve 14 and with the second electrovalve 15 to adjust the volume of water at the first temperature supplied to the mixing unit 7 through the first fluid path 8 and the volume of water at the second temperature supplied to the mixing unit 7 through the second fluid path 9 based on the regulation signal.
Also preferably, the actuation module 19 is configured to activate and deactivate the first electrovalve 14 and the second electrovalve 15 individually or simultaneously according to the adjustment signal to allow and stop the passage of water along the first fluid path 8 and the second fluid path 9 respectively.
This is advantageous since it allows the volume of water at the first temperature or at the second temperature supplied to the mixing unit 7 to be precisely adjusted by acting on the single fluid path.
In one embodiment, the actuation module 19 is configured to activate intermittently one or more of the pump 3, the first electrovalve 14 and the second electrovalve 15 based on the control signal. In detail, the actuation module 19 is configured to activate and deactivate according to an impulse train one or more of the pump 3, the first electrovalve 14 and the second electrovalve 15.
Preferably, the machine 1 comprises a brewing chamber 21 connected to the mixing unit 7 and configured to receive from said mixing unit 7 the mixture of water at the first temperature and water at the second temperature. The brewing chamber 21 is further configured to receive and contain coffee powder. In use, the coffee comes into contact with the mixture to make the brewed beverage.
In a first embodiment, the brewing chamber 21 comprises a dispensing unit connected to the mixing unit 7 and configured to receive the mixture and a filter holder that can be coupled to such a dispenser unit. In particular, the filter holder has a seat configured to receive and contain the coffee. The dispenser unit is configured to supply the mixture to the filter holder at the seat.
In a second embodiment, the brewing chamber 21 comprises a first hollow cylindrical body and a pressing body. The first cylindrical body is adapted to contain coffee. The press is connected to the mixing unit 7 to receive the mixture. In addition, the pressing body is configured to press the coffee contained within the first body and convey the mixture from the mixing unit 7 within the first body.
It is also an object of the present invention to propose a method for the preparation of brewed beverages by means of a brewed beverage-making machine 1 as described above.
According to a first embodiment, the method comprises the steps of defining a total volume of water to be supplied to the mixing unit 7 and defining a mixing volume corresponding to a fraction of the total volume of water.
To supply the total volume of water, the method comprises a step of defining a first parameter representative of the total volume of water or the time necessary for the pump 3 to supply said total volume of water.
To supply the mixing volume, the method comprises a step of defining a second parameter representative of the mixing volume or the time required for the pump 3 to supply said mixing volume.
This second parameter is representative of the time in which the first electrovalve 14 and the second electrovalve 15 are active simultaneously to supply the mixing volume to the mixing unit 7.
The first and second parameter can be defined by a number of activation pulses of the pump 3 to supply the total volume of water and the mixing volume to the mixing unit 7.
The method comprises the step of generating input data representative of water flow rate through the supply line 2. Preferably, the step of generating input data representative of the water flow rate through the supply line 2 is performed by means of the flow meter 6.
The input data is processed to determine the volume of water supplied to the supply line 2 from the pump 3 when it is activated and/or to determine the pulses provided by the pump 3.
In addition, the method comprises the steps of:
The step of supplying/stopping the water supply in the supply line 2 according to the first parameter and the input data is performed by means of the pump 3.
The step of supplying/stopping the water supply in the first path 8 and/or the second path 9 based on one or more of the first parameter, the second parameter and the input data is performed by means of the first electrovalve 14 and/or the second electrovalve 15. According to a first operating mode, the method comprises the following steps:
In other words, the pump 3 and the electrovalves 14, 15 are activated simultaneously. Once the mixing unit 7 has received a volume of water equal to the mixing volume, one of the electrovalves 14, 15 is deactivated. When the total volume of water has been reached, the electrovalve not previously deactivated and the pump 3 are deactivated. According to a preferred embodiment, the electrovalve 14 is deactivated when the mixing volume has been reached and then the electrovalve 15 is deactivated when the total volume of water has been reached.
Additionally, the method comprises the step of defining a delay volume corresponding to a fraction of the total volume of water.
To supply the delay volume, the method may comprise a step of defining a third parameter representative of the delay volume or time or pulses required for the pump 3 to supply said delay volume.
This third parameter is also representative of a delay time between activation of the first electrovalve 14 and activation of the second electrovalve 15 or vice versa.
According to a second operating mode, the method comprises the following steps:
In other words, the pump 3 and the second electrovalve 15 are activated simultaneously. Once the mixing unit 7 has received a volume of water equal to the delay volume, the first electrovalve 14 is activated. When the mixing volume has been reached, the first electrovalve 14 is deactivated, while the pump 3 and the second electrovalve 15 are kept active until the total volume of water has been reached.
In a second embodiment, the method comprises the step of defining a reference volume and a reference time necessary for the pump 3 to supply said reference volume. Furthermore, the method comprises the step of defining an interval volume corresponding to a fraction of the total volume of water and a stoppage time. The method may comprise the step of defining a fourth parameter representative of one or more of reference volume, reference time, interval volume, stoppage time, pulses required by pump 3 to supply the reference volume and/or interval volume.
In accordance with one aspect, the method comprises the steps of:
The supply of water in the first path 8 can be allowed and stopped according to an impulse train based on the fourth parameter. By way of example, if the water flow rate through the supply line 2 detected by the flow meter 6 is greater than the ratio of reference volume to reference time, water will be supplied both in the first path 8 and in the second path 9. Vice versa water will only be supplied in the second path 9. When active, the water supply in the first path 8 is maintained until the interval volume has been reached, after which it is interrupted for a time equal to the stoppage time.
This is advantageous, as it makes it possible to obtain excellent brewed beverages even in cases where the edible powder, for example coffee powder, used in the preparation of the beverage has a grain size inhomogeneity.
The method that is the object of the present invention enables the mixing of a water flow at the second temperature and a water flow at the first temperature using the water flow rate through the supply line 2 as the only information calculated in real time.
This is advantageous, since the use of proportional valves and temperature or pressure sensors along the first fluid path 8 or the second fluid path 9 is rendered superfluous.
Number | Date | Country | Kind |
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102021000018644 | Jul 2021 | IT | national |