Double cooled draft beer machine

Abstract

A double cooled draft beer machine comprises a cabinet, and there is a refrigeration circuit inside the cabinet, including a compressor, a condenser, and an evaporator. Inside the cabinet, there is a cold storage chamber used to hold the cask, and the evaporator can refrigerate the cold storage chamber. A beer pipe and a refrigeration tube which can refrigerate the beer pipe are also arranged inside the cabinet. The refrigeration tube is connected to the refrigeration circuit and in parallel with the evaporator. In the refrigeration circuit, at least one solenoid valve is set up. The present double cooled draft beer machine also comprises a relay and the first thermostat. The first thermostat is in series with the relay, and the contacts of the relay are connected to the solenoid of the solenoid valve, as well as the compressor.

Claims

1. A double cooled draft beer machine, comprising: a cabinet (1); a refrigeration circuit inside the cabinet (1), the refrigeration circuit including a compressor (2), a condenser (3), and an evaporator (4); a cold storage chamber (6) inside the cabinet (1), the cold storage chamber (6) used to hold a cask (5), and the evaporator (4) is capable of refrigerating the cold storage chamber (6); a beer pipe (7) and a refrigeration tube (8) capable of refrigerating the beer pipe (7) are arranged inside the cabinet (1); a beer tap (9) fixed to an outside of the cabinet (1); an outer end of the beer pipe (7) connected to the beer tap (9); an inner end of the beer pipe (7) connected to the cask (5); at least one solenoid valve, including a first solenoid valve, is set up in the refrigeration circuit, the first solenoid valve used to open or close the refrigeration circuit for refrigerant to flow toward the refrigeration tube (8) or the evaporator (4); a control chip (19) used to control an action of the first solenoid valve; a first temperature sensor (20) used to detect temperature; and a detection point (29) of the first temperature sensor (20), the detection point (29) located between the refrigeration tube (8) and the beer pipe (7); wherein the refrigeration tube (8) is connected to the refrigeration circuit and is in parallel with the evaporator (4); wherein the first temperature sensor (20) is connected to an input end of the control chip (19), the first solenoid valve is connected to an output end of the control chip (19), and a relay (10) used to control the on-off operation of the compressor (2) is also connected to the output end of the control chip (19); wherein an electromagnetic coil of the relay (10) is connected to and controlled by the output end of the control chip (19), and a normally open contact of the relay (10) is connected between the compressor (2) and a power supply (22) of the compressor (2); wherein a first upper limit temperature threshold and a first lower limit temperature threshold of the beer pipe (7) are set inside the control chip (19); wherein when the temperature detected by the first temperature sensor (20) is higher than the first upper limit temperature threshold, the control chip (19) controls the first solenoid valve to act and switch on the compressor (2) to allow the refrigerant in the refrigeration circuit to stop flowing toward the evaporator (4), and instead to allow the refrigerant in the refrigeration circuit to flow toward the refrigeration tube (8) only; and wherein when the temperature detected by the first temperature sensor (20) is equal to or lower than the first lower limit temperature threshold, the control chip (19) controls the first solenoid valve to act to allow the refrigerant in the refrigeration circuit to stop flowing toward the refrigeration tube (8).

2. The double cooled draft beer machine as claimed in claim 1, further comprising: a second temperature sensor (21) inside the cold storage chamber (6), the second temperature sensor (21) capable of detecting an inner temperature of the cold storage chamber (6); and the second temperature sensor (21) connected to a input end of the control chip (19), and a second upper limit temperature threshold and a second lower limit temperature threshold of the cold storage chamber (6) are set inside the control chip (19); wherein when the temperature detected by the first temperature sensor (20) is equal to or lower than the first lower limit temperature threshold, and an inner temperature of the cold storage chamber (6) is higher than the second upper limit temperature threshold, the control chip (19) controls the first solenoid valve to act and switches on the compressor (2) to allow the refrigerant to flow toward the evaporator (4); and wherein when the temperature detected by the first temperature sensor (20) is equal to or lower than the first lower limit temperature threshold, and the inner temperature of the cold storage chamber (6) is equal to or lower than the second lower limit temperature threshold, the control chip (19) controls the relay (10) to switch off the compressor (2) and causes the compressor (2) to stop working.

3. The double cooled draft beer machine as claimed in claim 2 wherein the refrigeration tube (8) and the beer pipe (7) are helically wound into a round or an elliptic cylindrical shaped quick cooler (13); wherein the quick cooler (13) comprises at least one mixing layer of a round or an elliptic cylindrical shape, each of the at least one mixing layer is formed by helically winding the refrigeration tube (8) and the beer pipe (7) which are arranged in an abreast manner; wherein an inflowing direction of the beer pipe (7) is opposite a flowing direction of refrigerant in the refrigeration tube (8); and wherein the first temperature sensor (20) is arranged on the quick cooler (13) and the detection point (29) of the first temperature sensor (20) is close to an outlet end of the beer pipe (7).

4. The double cooled draft beer machine as claimed in claim 3 wherein the first solenoid valve is a 3-way solenoid valve (16); and wherein an inlet of the 3-way solenoid valve (16) is connected to a refrigerant outlet of the condenser (3), a first outlet of the 3-way solenoid valve (16) is connected to the refrigeration tube (8), and a second outlet of the 3-way solenoid valve (16) is connected to the evaporator (4).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a first perspective schematic view of one embodiment of the present invention.

(2) FIG. 2 is a second perspective schematic view of one embodiment of the present invention.

(3) FIG. 3 is a first schematic view of one embodiment of the present invention under the service condition.

(4) FIG. 4 is a second schematic view of one embodiment of the present invention under the service condition.

(5) FIG. 5 is a perspective view of one embodiment of the quick cooler in the present invention.

(6) FIG. 6 is a first schematic diagram of the flowing direction of the refrigerant in one embodiment of the present invention.

(7) FIG. 7 is a second schematic diagram of the flowing direction of the refrigerant in one embodiment of the present invention.

(8) FIG. 8 is a sectional view of an arranged location of the detection point of a first thermostat in the first embodiment of the present invention.

(9) FIG. 9 is a first electric circuit connection diagram of a first embodiment of the present invention.

(10) FIG. 10 is a second electric circuit connection diagram of a first embodiment of the present invention.

(11) FIG. 11 is a sectional view of an arranged location of the detection point of a first temperature sensor in the second embodiment of the present invention.

(12) FIG. 12 is a first electric circuit connection diagram of a second embodiment of the present invention.

(13) FIG. 13 is a second electric circuit connection diagram of a second embodiment of the present invention.

(14) FIG. 14 is a sectional view of an arranged location of the detection point of the first temperature sensor in a third embodiment of the present invention.

(15) FIG. 15 is a first electric circuit connection diagram of a third embodiment of the present invention.

(16) FIG. 16 is a second electric circuit connection diagram of a third embodiment of the present invention.

(17) FIG. 17 is a sectional view of an arranged location of the detection point of the first temperature sensor in a fourth embodiment of the present invention.

(18) FIG. 18 is a first electric circuit connection diagram of a fourth embodiment of the present invention.

(19) FIG. 19 is a second electric circuit connection diagram of a fourth embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

(20) The embodiments of this invention will be described below and the technical solutions of the invention will be further illustrated in connection with the accompanying figures. However, the present invention shall not be limited to these embodiments.

First Embodiment

(21) As shown in FIG. 1 through FIG. 10, a double cooled draft beer machine comprises a cabinet (1), and there is a refrigeration circuit inside the cabinet (1), including a compressor (2), a condenser (3), and an evaporator (4). Inside the cabinet (1), there is a cold storage chamber (6) used to hold the cask (5), and the evaporator (4) can refrigerate the cold storage chamber (6). A beer pipe (7), as well as a refrigeration tube (8) which can refrigerate the beer pipe (7), is also arranged inside the cabinet (1). The refrigeration tube (8) is connected to the refrigeration circuit and is in parallel with the evaporator (4). A beer tap (9) is fixed to the outside of the cabinet (1). The outer end of the beer pipe (7) is connected to the beer tap (9), and its inner end is used to connect to the cask (5).

(22) In the refrigeration circuit, at least one solenoid valve is set up, which is used to open or close the refrigeration circuit for the refrigerant to flow toward the refrigeration tube (8) or the evaporator (4). The present double cooled draft beer machine also comprises a relay (10) used to control the action of the solenoid valve and the first thermostat (11) used to detect the temperature. The detection point (29) of the first thermostat (11) is located between the refrigeration tube (8) and the beer pipe (7). The first thermostat (11) is in series with the relay (10), and the contact of the relay (10) is connected to the solenoid of the solenoid valve, as well as the compressor (2).

(23) When the temperature detected by the first thermostat (11) is higher than the first upper limit temperature threshold set by the first thermostat (11), the relay (10) controls the solenoid valve to allow the refrigerant in the refrigeration circuit to stop flowing toward the evaporator (4), instead, to flow toward the refrigeration tube (8) only. When the temperature detected by the first thermostat (11) is equal to or lower than the first lower limit temperature threshold set by the first thermostat (11), the relay (10) controls the solenoid valve to allow the refrigerant in the refrigeration circuit to stop flowing toward the refrigeration tube (8). The solenoid valve is a 3-way solenoid valve (16). The inlet of the 3-way solenoid valve (16) is connected to the refrigerant outlet of the condenser (3), one outlet of the 3-way solenoid valve (16) is connected to the refrigeration tube (8), and the other outlet is connected to the evaporator (4). As an alternative, there are two solenoid valves: the first solenoid valve (17) and the second solenoid valve (18). The inlet of the first solenoid valve (17) is connected to the refrigerant outlet of the condenser (3), and the outlet is connected to the refrigeration tube (8). The inlet of the second solenoid valve (18) is connected to the refrigerant outlet of the condenser (3), and the outlet is connected to the evaporator (4). The relay (10) has both a normally open contact and a normally closed contact. The normally open contact is connected to the first solenoid valve (17) and the normally closed contact is connected to the second solenoid valve (18).

(24) The second thermostat (12) which can detect the inner temperature of the cold storage chamber (6) is arranged inside the cold storage chamber (6). The second thermostat (12) is in parallel with a series branch consisting of the first thermostat (11) and the relay (10). When the temperature detected by the first thermostat (11) is equal to or lower than the first lower limit temperature threshold, and the inner temperature of the cold storage chamber (6) is higher than the second upper limit temperature threshold set by the second thermostat (12), the relay (10) controls the solenoid valve to allow the refrigerant in the refrigeration circuit to flow toward the evaporator (4). When the temperature detected by the first thermostat (11) is equal to or lower than the first lower limit temperature threshold, and the inner temperature of the cold storage chamber (6) is equal to or lower than the second lower limit temperature threshold set by the second thermostat (12), the second thermostat (12) switches off and makes the compressor (2) stop working.

(25) The current input of the electromagnetic coil of the relay (10) and the contact of the relay (10) are connected to one end of the first thermostat (11), and the other end of the first thermostat (11) is connected to a power supply (22). The current output of the electromagnetic coil of the relay (10) is connected to the power supply (22) to form a circuit. The other contact of the relay (10) is connected to the current input of the solenoid valve and the current input of the compressor (2) respectively. The current output of the solenoid valve and the current output of the compressor (2) are connected to the power supply (22). One end of the second thermostat (12) is connected to the power supply (22), and the other end is connected to the current input of the compressor (2).

(26) The refrigeration tube (8) and the beer pipe (7) are wound into a quick cooler (13) of a round or an elliptic cylindrical shape, in a helical manner. The quick cooler (13) comprises at least one mixing layer, which is formed by winding the refrigeration tube (8) and the beer pipe (7) into a round or elliptic cylindrical shape, in an abreast and helical manner. The inflowing direction of the beer pipe (7) is opposite the flowing direction of the refrigerant in the refrigeration tube (8). The first thermostat (11) is arranged on the quick cooler (13) and the detection point (29) of the first thermostat (11) is close to the outlet end of the beer pipe (7).

(27) A mounting cover (14) is also arranged on the top of the cold storage chamber (6). The mounting cover (14) is fixed to the inner wall of the cabinet (1), and the evaporator (4) is arranged inside mounting cover (14). On the mounting cover (14), there is also an evaporator blower (15) which can blow the cold air diffused from the evaporator (4) into the cold storage chamber (6). The evaporator blower (15) is also connected to the power supply (22). The present double cooled draft beer machine also comprises a condenser blower (26) used to blow the condenser (3) and dissipate the heat. The current input of the condenser blower (26) is connected to the other end of the second thermostat (12), and the current output of the condenser blower (26) is connected to the power supply (22) to form a circuit. A thermal protector (27), which can prevent the compressor (2) from overheating, is also connected between the current input of the compressor (2) and the second thermostat (12).

(28) The following is the working process of the present invention:

(29) The present double cooled draft beer machine comprises a refrigeration circuit including the compressor (2), the condenser (3) and the evaporator (4), and the refrigeration tube (8) is connected to the refrigeration circuit and in parallel with the evaporator (4). This affords two refrigeration modes, firstly, the evaporator (4) can refrigerate the casks (5) in the cold storage chamber (6), and secondly, the refrigeration tube (8) can refrigerate the beer pipe (7). Since the refrigeration tube (8) and the beer pipe (7) are wound into a quick cooler (13) of a round or elliptic cylindrical shape in a helical manner, with the arrangement of the quick cooler (13), the beer pipe (7) and the refrigeration tube (8) adhere tightly and then the cooling capacity is transferred between the refrigeration tube (8) and the beer pipe (7) in the form of dry contact cooling. Also, compared to water cooling, dry contact cooling has an advantage of high speed of cooling capacity transfer, and can further expedite the refrigeration process to achieve a quick cooling effect, so as to fulfill the purpose of quick cooling of beer. The quick cooler (13) may be round or elliptic cylindrical. Both shapes can present smooth bends on the refrigeration tubes (8) and the beer pipes (7). This ensures that the fluid in the beer pipes (7) and the refrigeration tubes (8) flows fluently, can further ensure a uniform distribution of cooling capacity to improve the refrigeration speed, and prevents the tubes from being clogged by ice due to non-uniform local cooling capacity. The arranged location of the first thermostat (11) makes the detection result more accurate. The flowing direction of the fluid in the beer pipe (7) is opposite that of the fluid in the refrigeration tube (8). The refrigerant at a relatively low temperature in the refrigeration tube (8) first transfers the cooling capacity to beer at a higher temperature in the beer pipe (7). Such an arrangement ensures a long refrigeration time of the beer and improves the refrigeration efficiency. Also, after the evaporator (4) fulfills the refrigeration, the refrigeration area and speed are increased by the evaporator blower (15), and the cold storage chamber (6) is refrigerated quickly, so as to refrigerate the casks (5). Therefore, the present double cooled draft beer machine can improve the refrigeration effect of the draft beer machine.

(30) After the present double cooled draft beer machine is powered on, it always refrigerates the refrigeration tube (8) first, so as to ensure beer can always flow out at a relatively low temperature. The temperature detected by the first thermostat (11) may be the temperature of the beer pipe (7) or the temperature of the refrigeration tube (8). When a temperature conductive medium, such as the temperature conductive mud, is arranged between the refrigeration tube (8) and the beer pipe (7), the temperature detected by the first thermostat (11) may also be the temperature of the temperature conductive mud.

(31) The first upper limit temperature threshold and the first lower limit temperature threshold are set on the first thermostat (11). The first upper limit temperature threshold is 5 to 10 degrees Celsius, and the first lower limit temperature threshold is 0 to 6 degrees Celsius. Preferably, the first upper limit temperature threshold is 6 degrees Celsius, and the first lower limit temperature threshold is 1 degrees Celsius.

(32) As shown in FIG. 6 and FIG. 9, after the draft beer machine is powered on, the detection point (29) of the first thermostat (11) senses the detection temperature. When the detection temperature is above 6 degrees Celsius, it means the temperature of the beer passing through the beer pipe (7) is relatively high, and the flavor will be affected. At this point, the switch of the first thermostat (11) is closed to close the circuit between the power supply (22) and the relay (10). The contact of the relay (10) is then closed to power on the 3-way solenoid valve (16). After the 3-way solenoid valve (16) is powered on and acts, the inlet is connected to the outlet which is connected to the refrigeration tube (8), and the compressor (2) is also powered on. At this point, the flowing direction of the refrigerant is switched so that the refrigerant in the refrigeration circuit stops flowing toward the evaporator (4), instead, flows toward the refrigeration tube (8) only. When the refrigerant flows toward the refrigeration tube (8), the temperature of the refrigeration tube (8) decreases, the beer pipe (7) is refrigerated, the temperature of the inflowing beer decreases quickly, and the flavor of beer is improved. The first thermostat (11) detects the temperature continuously. When the detection temperature is equal to or lower than 1 degree Celsius, the switch of the first thermostat (11) is off to power off the relay (10). The contact of the relay (10) is opened, and the 3-way solenoid valve (16) is powered off. Its inlet is connected to the outlet which is connected to the evaporator (4). Only when the first thermostat (11) is opened, does the action of the second thermostat (12) take effect. The second upper limit temperature threshold and the second lower limit temperature threshold are set on the second thermostat (12). The second upper limit temperature threshold is 5 to 10 degrees Celsius, and the second lower limit temperature threshold is 0 to 6 degrees Celsius. Preferably, the second upper limit temperature threshold is 6 degrees Celsius, and the second lower limit temperature threshold is 1 degrees Celsius. When the temperature detected by the first thermostat (11) is equal to or lower than 1 degree Celsius and the temperature inside the cold storage chamber (6) is higher than 6 degrees Celsius, the refrigerant in the refrigeration circuit flows toward the evaporator (4). The evaporator (4) starts refrigeration, and the evaporator blower (15) increases the refrigeration speed of the evaporator (4). When the temperature detected by the first thermostat (11) is equal to or lower than 1 degree Celsius, and the temperature inside the cold storage chamber (6) is lower than or equal to 1 degree Celsius, the switch of the second thermostat (12) is off. At this point, the compressor (2) is disconnected from the power supply (22) and stops working. When the compressor (2) is working, the condenser blower (26) is also powered on, and it dissipates the heat of the condenser (3).

(33) The analysis of the temperature detected by the first thermostat (11) always takes precedence in the present double cooled draft beer machine, no matter when the refrigerant is flowing toward the evaporator (4), or when the compressor (2) is powered off.

(34) As an alternative, as shown in FIG. 7 and FIG. 10, there are two solenoid valves: the first solenoid valve (17) and the second solenoid valve (18). The relay (10) has both a normally open contact and a normally closed contact. The normally open contact is connected to the first solenoid valve (17) and the normally closed contact is connected to the second solenoid valve (18). When the relay (10) is powered on, the normally closed contact will be disconnected to switch off the second solenoid valve (18), and the normally open contact is on to switch on the first solenoid valve (17), so the refrigerant flow toward the refrigeration tube (8) only. Other contents are the same as the contents in the description above where the 3-way solenoid valve (16) is adopted.

Second Embodiment

(35) As shown in FIG. 1 through FIG. 7, as well as in FIG. 11 through FIG. 13, the structure and the working process of the second embodiment are basically the same as those in the first embodiment. The differences are:

(36) The present double cooled draft beer machine comprises a control chip (19) used to control the action of the solenoid valve and the first temperature sensor (20) used to detect the temperature. The detection point (29) of the first temperature sensor (20) is located between the refrigeration tube (8) and the beer pipe (7). The first temperature sensor (20) is connected to the input end of the control chip (19), the solenoid valve is connected to the output end of the control chip (19), and a relay (10) used to control the on-off operation of the compressor (2) is also connected to the output end of the control chip (19). The electromagnetic coil of the relay (10) is connected to output end of the control chip (19), and the normally open contact of the relay (10) is connected to between the compressor (2) and the power supply (22) of the compressor (2). The first upper limit temperature threshold and the first lower limit temperature threshold of the beer pipe (7) are set inside the control chip (19). When the temperature detected by the first temperature sensor (20) is higher than the first upper limit temperature threshold, the control chip (19) controls the solenoid valve to act and switch on the compressor (2) to allow the refrigerant to stop flowing toward the evaporator (4), instead, to flow toward the refrigeration tube (8) only. When the temperature detected by the first temperature sensor (20) is equal to or lower than the first lower limit temperature threshold, the control chip (19) controls the solenoid valve to act to allow the refrigerant in the refrigeration circuit to stop flowing toward the refrigeration tube (8). The first temperature sensor (20) is arranged on the quick cooler (13) and the detection point (29) of the first temperature sensor (20) is close to the outlet end of the beer pipe (7).

(37) The present double cooled draft beer machine also comprises the second temperature sensor (21) to detect the inner temperature of the cold storage chamber (6). The second temperature sensor (21) is connected to the input end of the control chip (19), and the second upper limit temperature threshold and the second lower limit temperature threshold of the cold storage chamber (6) are set inside the control chip (19). When the temperature detected by the first temperature sensor (20) is equal to or lower than the first lower limit temperature threshold, and the inner temperature of the cold storage chamber (6) is higher than the second upper limit temperature threshold, the control chip (19) controls the solenoid valve to act and switches on the compressor (2) to allow the refrigerant to flow toward the evaporator (4). When the temperature detected by the first temperature sensor (20) is equal to or lower than the first lower limit temperature threshold, and the inner temperature of the cold storage chamber (6) is equal to or lower than the second lower limit temperature threshold, the control chip (19) controls the relay (10) to switch off the compressor (2) and make it stop working.

(38) The following is the working process of this embodiment:

(39) The present double cooled draft beer machine comprises a refrigeration circuit including the compressor (2), the condenser (3) and the evaporator (4), and the refrigeration tube (8) is connected to the refrigeration circuit and in parallel with the evaporator (4). This affords two refrigeration modes, firstly, the evaporator (4) can refrigerate the casks (5) in the cold storage chamber (6), and secondly, the refrigeration tube (8) can refrigerate the beer pipe (7). After the present double cooled draft beer machine is powered on, it always refrigerates the refrigeration tube (8) first, so as to ensure beer can always flow out at a relatively low temperature. The first upper limit temperature threshold and the first lower limit temperature threshold of the beer pipe (7) are set in the control chip (19). The first upper limit temperature threshold is 5 to 10 degrees Celsius, and the first lower limit temperature threshold is 0 to 6 degrees Celsius. Preferably, the first upper limit temperature threshold is 6 degrees Celsius, and the first lower limit temperature threshold is 1 degrees Celsius. The second upper limit temperature threshold is 5 to 10 degrees Celsius, and the second lower limit temperature threshold is 0 to 6 degrees Celsius. Preferably, the second upper limit temperature threshold is 6 degrees Celsius, and the second lower limit temperature threshold is 1 degrees Celsius. The temperature detected by the first temperature sensor (20) may be the temperature of the beer pipe (7) or the temperature of the refrigeration tube (8). When a temperature conductive medium, such as the temperature conductive mud, is arranged between the refrigeration tube (8) and the beer pipe (7), the temperature detected by the first temperature sensor (20) may also be the temperature of the temperature conductive mud.

(40) After the draft beer machine is powered on, when the temperature detected by the first temperature sensor (20) is higher than 6 degrees Celsius set by the control chip (19), it is indicated that the temperature of beer passing through the beer pipe (7) is relatively high, and the flavor will be affected. At this point, the control chip (19) sends electronic signals to the relay (10), and the normally open contact of the relay (10) is closed to close the circuit between the compressor (2) and the power supply (22). Meanwhile, the control chip (19) sends electronic signals to the 3-way solenoid valve (16). The 3-way solenoid valve (16) acts after it is powered on, connecting the inlet to the outlet which is connected to the refrigeration tube (8), and the compressor (2) is also powered on. At this point, the flowing direction of the refrigerant is switched so that the refrigerant in the refrigeration circuit stops flowing toward the evaporator (4), instead, flows toward the refrigeration tube (8) only. When the refrigerant flows toward the refrigeration tube (8), the temperature of the refrigeration tube (8) decreases, the beer pipe (7) is hence refrigerated, and the temperature of the inflowing beer decreases. When the temperature detected by the first temperature sensor (20) is equal to or lower than 1 degree Celsius, the control chip (19) controls the 3-way solenoid valve (16) to power off, and its inlet is connected to the outlet which is connected to the evaporator (4). The second temperature sensor (21) detects the temperature of the cold storage chamber (6). When the condition that the temperature of inflowing beer of the beer pipe (7) is equal to or lowers than 1 degrees Celsius and the temperature of the cold storage chamber (6) is higher than 6 degrees Celsius is met, the control chip (19) keeps the compressor (2) working, and the refrigerant flows toward the evaporator (4) at this point. The evaporator (4) starts refrigeration, and the evaporator blower (15) increases the refrigeration speed of the evaporator (4). When the temperature detected by the first temperature sensor (20) is still equal to or lower than 1 degrees Celsius, and the temperature inside the cold storage chamber (6) is lower than or equal to 1 degrees Celsius, the control chip (19) controls the relay (10) to be powered off, and the compressor (2) is disconnected from the power supply (22) and stops working. When the compressor (2) is working, the condenser blower (26) is also powered on, and it dissipates the heat of the condenser (3).

(41) The analysis of the temperature detected by the first temperature sensor (20) always takes precedence in the present double cooled draft beer machine, no matter when the refrigerant is flowing toward the evaporator (4), or when the compressor (2) is powered off.

(42) As an alternative, as shown in FIG. 7 and FIG. 13, there are two solenoid valves: the first solenoid valve (17) and the second solenoid valve (18). The control chip (19) controls the on-off operation of the first solenoid valve (17) and the second solenoid valve (18) respectively. When the first solenoid valve (17) is switched on, the second solenoid valve (18) is switched off. Other contents are the same as the contents in the description above where the 3-way solenoid valve (16) is adopted.

Third Embodiment

(43) As shown in FIG. 1 through FIG. 7, as well as in FIG. 14 through FIG. 16, the structure and the working process of the second embodiment are basically the same as those in the first embodiment. The differences in the structure are:

(44) The present double cooled draft beer machine also comprises a microprocessor (28) used to control the action of the solenoid valve, the first temperature sensor (20) used to detect the temperature, a flow sensor (23) used to detect the beer flow of the beer pipe (7), and a relay (10) used to the control the on-off operation of the compressor (2). The first temperature sensor (20) is arranged on the quick cooler (13) and the detection point (29) of the first temperature sensor (20) is close to the outlet end of the beer pipe (7). The electromagnetic coil of the relay (10) is connected to output end of the microprocessor (28), and the normally open contact of the relay (10) is connected to between the compressor (2) and the power supply (22) of the compressor (2). The flow sensor (23) is arranged on the beer pipe (7), next to the beer tap (9). There is a timer (24) inside the microprocessor (28). The flow sensor (23) and the first temperature sensor (20) are connected to the input end of the microprocessor (28) respectively, and the solenoid valve and the relay (10) are connected to the output end of the microprocessor (28) respectively. The first lower limit temperature threshold is set inside the microprocessor (28). When a flow passes through the beer pipe (7), the timer (24) re-starts timing. Within the timing interval set by the microprocessor (28), when the beer flow in the beer pipe (7) reaches the flow threshold set by the microprocessor (28), the microprocessor (28) controls the solenoid valve to act and switches on the compressor (2) to allow the refrigerant to stop flowing toward the evaporator (4), instead, to flow toward the refrigeration tube (8) only. When the temperature detected by the first temperature sensor (20) is equal to or lower than the first lower limit temperature threshold, the microprocessor (28) controls the solenoid valve to act to allow the refrigerant in the refrigeration circuit to stop flowing toward the refrigeration tube (8).

(45) The second temperature sensor (21) which can detect the inner temperature of the cold storage chamber (6) is arranged inside the cold storage chamber (6). The second temperature sensor (21) is connected to the input end of the microprocessor (28), and the second lower limit temperature threshold is set inside the microprocessor (28). When the temperature detected by the first temperature sensor (20) is equal to or lower than the first lower limit temperature threshold, the microprocessor (28) controls the solenoid valve to act and switches on the compressor (2) to allow the refrigerant to flow toward the evaporator (4). When the temperature detected by the first temperature sensor (20) is equal to or lower than the first lower limit temperature threshold, and the inner temperature of the cold storage chamber (6) is equal to or lower than the second lower limit temperature threshold, the microprocessor (28) controls the relay (10) to switch off the compressor (2) and make it stop working. The first temperature sensor (20) is arranged on the quick cooler (13) and the detection point (29) of the first temperature sensor (20) is close to the beer pipe (7).

(46) The following is the working process of this embodiment:

(47) The present double cooled draft beer machine comprises a refrigeration circuit including the compressor (2), the condenser (3) and the evaporator (4), and the refrigeration tube (8) is connected to the refrigeration circuit and in parallel with the evaporator (4). This affords two refrigeration modes, firstly, the evaporator (4) can refrigerate the casks (5) in the cold storage chamber (6), and secondly, the refrigeration tube (8) can refrigerate the beer pipe (7). After the present double cooled draft beer machine is powered on, it always refrigerates the refrigeration tube (8) first, so as to ensure beer can always flow out at a relatively low temperature. The first lower limit temperature threshold and the second lower limit temperature threshold of the beer pipe (7), the flow threshold, and the timing interval are set in the microprocessor (28). The range of the first lower limit temperature threshold is 0 to 6 degrees Celsius, and preferably, the first lower limit temperature threshold is 1 degrees Celsius. The range of the second lower limit temperature threshold is 0 to 6 degrees Celsius, and preferably, the second lower limit temperature threshold is 1 degree Celsius. The flow threshold is 500 to 1500 milliliters, and preferably 500 milliliters. The timing interval is 5 to 20 minutes and preferably 10 minutes.

(48) The temperature detected by the first temperature sensor (20) may be the temperature of the beer pipe (7) or the temperature of the refrigeration tube (8). When a temperature conductive medium, such as the temperature conductive mud, is arranged between the refrigeration tube (8) and the beer pipe (7), the temperature detected by the first temperature sensor (20) may also be the temperature of the temperature conductive mud.

(49) The flow sensor (23) detects the flow inside the beer pipe (7) in real time and sends detection signals to the microprocessor (28). When the microprocessor (28) just receives the signals sent by the flow sensor (23), it is indicated that beer is flowing into the beer pipe (7). At this point, the microprocessor (28) controls the timer (24) to start timing. When the flow of the beer pipe (7) reaches 500 milliliters within 10 minutes, it is indicated that much beer is discharged during a short period. This would take away the cooling capacity in the refrigeration tube (8), makes the temperature of the refrigeration tube (8) increase quickly, and at the meanwhile, the temperature of the beer pipe (7) also increases. At this point, the microprocessor (28) sends electronic signals to the relay (10), and the normally open contact of the relay (10) is closed to close the circuit between the compressor (2) and the power supply (22). Meanwhile, the microprocessor (28) sends electronic signals to the 3-way solenoid valve (16), the 3-way solenoid valve (16) is powered on and acts, connecting the inlet to the outlet which is connected to the refrigeration tube (8), and the compressor (2) is also powered on. At this point, the flowing direction of the refrigerant is switched so that the refrigerant in the refrigeration circuit stops flowing toward the evaporator (4), instead, flows toward the refrigeration tube (8) only. When the refrigerant flows toward the refrigeration tube (8), the temperature of the refrigeration tube (8) decreases, the beer pipe (7) is hence refrigerated, and the temperature of the inflowing beer decreases. When the temperature detected by the first temperature sensor (20) is equal to or lower than 1 degree Celsius, the microprocessor (28) controls the 3-way solenoid valve (16) to power off, and its inlet is connected to the outlet which is connected to the evaporator (4). The second temperature sensor (21) detects the temperature of the cold storage chamber (6). Only after the refrigeration to the refrigeration tube (8) is fulfilled, the cold storage chamber (6) will be refrigerated. Within the given 10 minutes, and when the flow in the beer pipe (7) reaches 500 milliliters, even if the microprocessor (28) is controlling the refrigerant in the refrigeration circuit to flow toward the evaporator (4), the refrigerant will be switched to flowing toward the refrigeration tube (8) to first fulfill the refrigeration to the beer pipe (7), so as to ensure that beer can always flow out at a relatively low temperature. When the refrigeration condition under which the refrigerant flows toward the refrigeration tube (8) is not met, and the temperature inside the cold storage chamber (6) is lower than or equal to 1 degrees Celsius, the control chip (19) controls the relay (10) to be powered off, and the compressor (2) is disconnected from the power supply (22) and stops working. When the compressor (2) is working, the condenser blower (26) is also powered on, and it dissipates the heat of the condenser (3). The refrigeration condition under which the refrigerant flows toward the refrigeration tube (8) is that the flow inside the beer pipe (7) reaches 500 milliliters within the given 10 minutes.

(50) After the microprocessor (28) controls the solenoid valve and the compressor (2) to act according to signals from the flow sensor (23) and electronic signals from the timer (24), the microprocessor (28) clears the flow value sent by the flow sensor (23). Also, after the recorded time of the timer (24) reaches the given timing interval, and when beer flow appears inside the beer pipe (7) again, the microprocessor (28) starts timing.

(51) The analysis of the beer flow of the beer pipe (7) always takes precedence in the present double cooled draft beer machine, no matter when the refrigerant is flowing toward the evaporator (4), or when the compressor (2) is powered off.

(52) As an alternative, as shown in FIG. 7 and FIG. 16, there are two solenoid valves: the first solenoid valve (17) and the second solenoid valve (18). The microprocessor (28) controls the on-off operation of the first solenoid valve (17) and the second solenoid valve (18) respectively. When the first solenoid valve (17) is switched on, the second solenoid valve (18) is switched off. Other contents are the same as the contents in the description above where the 3-way solenoid valve (16) is adopted.

Fourth Embodiment

(53) As shown in FIG. 1 through FIG. 7, as well as in FIG. 17 through FIG. 19, the structure and the working process of the fourth embodiment are basically the same as those in the first embodiment. The differences in the structure are:

(54) The present double cooled draft beer machine also comprises a microprocessor (28) used to control the action of the solenoid valve and the first temperature sensor (20) used to detect the temperature. The detection point (29) of the first temperature sensor (20) is located between the refrigeration tube (8) and the beer pipe (7). A stroke switch (25), which will be switched on when beer is discharged from the beer tap (9), is arranged on the beer tap (9), and the stroke switch (25) is connected to the input end of the microprocessor (28). There is a timer (24) inside the microprocessor (28). The stroke switch (25) and the first temperature sensor (20) are connected to the input end of the microprocessor (28) respectively, the solenoid valve is connected to the output end of the microprocessor (28), and a relay (10) used to control the on-off operation of the compressor (2) is also connected to the output end of the microprocessor (28). The electromagnetic coil of the relay (10) is connected to the output end of the microprocessor (28), and the normally open contact of the relay (10) is connected to between the compressor (2) and the power supply (22) of the compressor (2). The first lower limit temperature threshold is set inside the microprocessor (28). When the stroke switch (25) switches on the timer (24) to start timing, and the recorded time is longer than the timing interval set by the microprocessor (28), the microprocessor (28) controls the solenoid valve to act and switches on the compressor (2) to allow the refrigerant to stop flowing toward the evaporator (4), instead, to flow toward the refrigeration tube (8) only. When the temperature detected by the first temperature sensor (20) is equal to or lower than the first lower limit temperature threshold, the microprocessor (28) controls the solenoid valve to act to allow the refrigerant in the refrigeration circuit to stop flowing toward the refrigeration tube (8).

(55) The second temperature sensor (21) which can detect the inner temperature of the cold storage chamber (6) is arranged inside the cold storage chamber (6). The second temperature sensor (21) is connected to the input end of the microprocessor (28). The second lower limit temperature threshold is set inside the microprocessor (28). When the temperature detected by the first temperature sensor (20) is equal to or lower than the first lower limit temperature threshold, the microprocessor (19) controls the solenoid valve to act and switches on the compressor (2) to allow the refrigerant to flow toward the evaporator (4). When the temperature of inflowing beer of the beer pipe (7) is equal to or lower than the first lower limit temperature threshold, and the inner temperature of the cold storage chamber (6) is equal to or lower than the second lower limit temperature threshold, the microprocessor (28) controls the relay (10) to switch off the compressor (2) and make it stop working. The first temperature sensor (20) is arranged on the quick cooler (13) and the detection point (29) of the first temperature sensor (20) is close to the outlet end of the beer pipe (7).

(56) The following is the working process of this embodiment:

(57) The present double cooled draft beer machine comprises a refrigeration circuit including the compressor (2), the condenser (3) and the evaporator (4), and the refrigeration tube (8) is connected to the refrigeration circuit and in parallel with the evaporator (4). This affords two refrigeration modes, firstly, the evaporator (4) can refrigerate the casks (5) in the cold storage chamber (6), and secondly, the refrigeration tube (8) can refrigerate the beer pipe (7). After the present double cooled draft beer machine is powered on, it always refrigerates the refrigeration tube (8) first, so as to ensure beer can always flow out at a relatively low temperature. The first lower limit temperature threshold and the second lower limit temperature threshold of the beer pipe (7), and the timing threshold are set in the microprocessor (28). The range of the first lower limit temperature threshold is 0 to 6 degrees Celsius, and preferably, the first lower limit temperature threshold is 1 degrees Celsius. The range of the second lower limit temperature threshold is 0 to 6 degrees Celsius, and preferably, the second lower limit temperature threshold is 1 degree Celsius. The timing threshold is 5 to 100 seconds and preferably, the timing threshold is 30 seconds. The temperature detected by the first temperature sensor (20) may be the temperature of the beer pipe (7) or the temperature of the refrigeration tube (8). When a temperature conductive medium, such as the temperature conductive mud, is arranged between the refrigeration tube (8) and the beer pipe (7), the temperature detected by the first temperature sensor (20) may also be the temperature of the temperature conductive mud.

(58) When the beer tap (9) opens, the stroke switch (25) is on and sends electronic signals to the microprocessor (28). The microprocessor (28) starts timing with the timer (24). When the recorded time is longer than 30 seconds, it is indicated that much beer is discharged from the beer tap (9). This would take away the cooling capacity in the refrigeration tube (8), makes the temperature of the refrigeration tube (8) increase quickly, and at the meanwhile, the temperature of the beer pipe (7) also increases. At this point, the microprocessor (28) sends electronic signals to the relay (10), and the normally open contact of the relay (10) is closed to close the circuit between the compressor (2) and the power supply (22). Meanwhile, the microprocessor (28) sends electronic signals to the 3-way solenoid valve (16), the 3-way solenoid valve (16) is powered on and acts, connecting the inlet to the outlet which is connected to the refrigeration tube (8), and the compressor (2) is also powered on. At this point, the flowing direction of the refrigerant is switched so that the refrigerant in the refrigeration circuit stops flowing toward the evaporator (4), instead, flows toward the refrigeration tube (8) only. When the refrigerant flows toward the refrigeration tube (8), the temperature of the refrigeration tube (8) decreases, the beer pipe (7) is hence refrigerated, and the temperature of the inflowing beer decreases. When the temperature detected by the first temperature sensor (20) is equal to or lower than 1 degree Celsius, the microprocessor (28) controls the 3-way solenoid valve (16) to power off, and its inlet is connected to the outlet which is connected to the evaporator (4).

(59) The second temperature sensor (21) detects the temperature of the cold storage chamber (6). Only after the refrigeration to the refrigeration tube (8) is fulfilled, the cold storage chamber (6) will be refrigerated. When the beer tap opens and the opening time exceeds 30 seconds, even if the microprocessor (28) is controlling the refrigerant in the refrigeration circuit to flow toward the evaporator (4), the refrigerant will be switched to flowing toward the refrigeration tube (8) to first fulfill the refrigeration to the beer pipe (7), so as to ensure that beer can always flow out at a relatively low temperature. When the refrigeration condition under which the refrigerant flows toward the refrigeration tube (8) is not met, and the temperature inside the cold storage chamber (6) is lower than or equal to 1 degrees Celsius, the microprocessor (28) controls the relay (10) to be powered off, and the compressor (2) is disconnected from the power supply (22) and stops working. When the compressor (2) is working, the condenser blower (26) is also powered on, and it dissipates the heat of the condenser (3). The refrigeration condition under which the refrigerant flows toward the refrigeration tube (8) is that the beer tap (9) opens and the opening time exceeds 30 seconds.

(60) The analysis of the beer discharging time of the beer tap (9) always takes precedence in the present double cooled draft beer machine, no matter when the refrigerant is flowing toward the evaporator (4), or when the compressor (2) is powered off.

(61) As an alternative, as shown in FIG. 7 and FIG. 19, there are two solenoid valves: the first solenoid valve (17) and the second solenoid valve (18). The microprocessor (28) controls the on-off operation of the first solenoid valve (17) and the second solenoid valve (18) respectively. When the first solenoid valve (17) is switched on, the second solenoid valve (18) is switched off. Other contents are the same as the contents in the description above where the 3-way solenoid valve (16) is adopted.

(62) The description of the preferred embodiments thereof serves only as an illustration of the spirit of the invention. It will be understood by those skilled in the art that various changes or supplements in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

(63) Although the terms of Cabinet (1), Compressor (2), Condenser (3), Evaporator (4), Cask (5), Cold Storage Chamber (6), Beer Pipe (7), Refrigeration Tube (8), Beer Tap (9), Relay (10), The First Thermostat (11), The Second Thermostat (12), Quick Cooler (13), Mounting Cover (14), Evaporator Blower (15), 3-way Solenoid Valve (16), The First solenoid Valve (17), The Second Solenoid Valve (18), Control Chip (19), The First Temperature Sensor (20), The Second Temperature Sensor (21), Power Supply (22), Flow Sensor (23), Timer (24), Stroke Switch (25), Condenser Blower (26), Thermal Protector (27), Microprocessor (28), Detection Point (29), etc. are often used herein, it does not exclude the possibility to use any other terms. Using such terms is only to describe or explain the nature of the present invention more conveniently. Any additional restrictions are contrary to the spirit of the present invention.

LIST OF REFERENCE NUMERALS

(64) 1 Cabinet 2 Compressor 3 Condenser 4 Evaporator 5 Cask 6 Cold Storage Chamber 7 Beer Pipe 8 Refrigeration Tube 9 Beer Tap 10 Relay 11 First Thermostat 12 Second Thermostat 13 Quick Cooler 14 Mounting Cover 15 Evaporator Blower 16 3-Way Solenoid Valve 17 First Solenoid Valve 18 Second Solenoid Valve 19 Control Chip 20 First Temperature Sensor 21 Second Temperature Sensor 22 Power Supply 23 Flow Sensor 24 Timer 25 Stroke Switch 26 Condenser Blower 27 Thermal Protector 28 Microprocessor 29 Detection Point