JP5240016B2 - vending machine - Google Patents

Description

  The present invention relates to a vending machine that sells a product such as a beverage in a container such as a can, a bottle, a pack, or a plastic bottle after being cooled or heated in a refrigerant circuit.

Reducing carbon dioxide emissions has become a challenge with recent global warming, and energy-saving vending machines have been developed. As one of the methods, a heat pump type vending machine that uses the heat of the condenser, which has been exhausted in the past, for heating in the cabinet has been developed (for example, see Patent Document 1).
The vending machine described in Patent Document 1 is provided with an internal heat exchanger in each of a plurality of product storages, and is connected to a compressor and an external heat exchanger provided outside the product storage to open an electric expansion valve. By adjusting the degree and switching the electromagnetic valve, each product storage is set for cooling or heating, and a heat pump operation is performed using the internal heat exchanger as a condenser. In addition, the cooling and heating setting mode indicates the operation of cooling or heating the product storage using symbols C and H. For example, all the cooling is performed in order from the left side of the product storage as viewed from the front. In the case, the CCC mode is indicated. When only the right product storage is heated, the CCH mode is indicated.

  When the temperature of the product storage is detected and the temperature reaches an appropriate temperature, a thermostat that closes the electric expansion valve and electromagnetic valve connected to the internal heat exchanger of the product storage and stops cooling or heating. Cycle operation is performed. For example, when cooling heating is performed in the heat pump operation in which the cooling heating setting mode is the CHH mode, when the temperature of the heating inner product storage (also referred to as the storage) is detected and the appropriate temperature is reached, The heat pump operation is performed only in the left and right product storages (also referred to as a left store and a right store). Furthermore, when the mode of this heat pump operation is continued and the temperature of the heated right product storage is detected and the appropriate temperature is reached, the electric expansion valve and electromagnetic valve of the right product storage are closed. Then, the heating is stopped, and the single cooling operation is performed by the external heat exchanger and the internal heat exchanger of the left product storage. If the temperature of the right product storage rises and exceeds the appropriate temperature range during this period, the heat pump operation is again performed in the left and right product storages. And if the temperature of all the goods storage reaches | attains appropriate temperature, a compressor will be stopped and cooling heating operation will be stopped.

JP 2002-298210 A

However, the vending machine described in Patent Document 1 is connected to the inlet side of the paused internal heat exchanger when the heat pump operation mode in which at least one internal heat exchanger is paused continues. The refrigerant gradually leaks from the solenoid valve and is stored in the resting internal heat exchanger. As a result, since the amount of refrigerant circulating in the refrigerant circuit is insufficient, there is a problem that operation efficiency is reduced and power consumption is increased.
The present invention has been made in view of the above, and can automatically perform an efficient cooling and heating operation while maintaining an appropriate refrigerant circulation amount even when a heat pump operation mode in which one internal heat exchanger is stopped is continued. The purpose is to provide a vending machine.

  In order to achieve the above object, a vending machine according to claim 1 of the present invention has a plurality of product storages for both cooling and heating, and selectively stores the product storage by a cooling and heating setting mode for cooling and heating. A vending machine that cools or heats, a compressor that compresses the refrigerant, a condenser that is provided outside the refrigerator and condenses the refrigerant via a condenser solenoid valve, an expansion means that expands the refrigerant, and an expansion by the expansion means A distributor that distributes the refrigerant, a plurality of internal heat exchangers that evaporate the refrigerant from the distributor through the cooler inlet solenoid valve, and the evaporated refrigerant through the cooler outlet solenoid valve. And a confluencer for merging with each other to form a cooling circulation circuit, and to the cooling circulation circuit from the compressor through a heater solenoid valve, between the internal heat exchanger and the cooler inlet solenoid valve. Pipe connection, and the internal heat exchanger and the cooling Heating / cooling circulation in which heat pump operation is performed by connecting the internal heat exchanger as a condenser by connecting a pipe to the distributor via an external heat exchanger and second expansion means from between the outlet solenoid valves In a vending machine that constitutes a circuit, when performing heat pump operation in other internal heat exchangers excluding at least one internal heat exchanger, cooling alone when the total time of the heat pump operation reaches a predetermined time It has a control device (also referred to as forced pump down control) that operates for a second predetermined time.

  When the vending machine according to claim 1 according to the present invention performs a heat pump operation in another internal heat exchanger excluding at least one internal heat exchanger, the total time of the heat pump operation reaches a predetermined time. Sometimes, by having the control device that operates the cooling single operation for the second predetermined time, the refrigerant in the in-box heat exchanger is collected in the circulating refrigerant circuit, so that the refrigerant circulation amount is in an appropriate state. As a result, the cooling and heating operation can be performed efficiently.

1 is a perspective view showing a vending machine according to an embodiment of the present invention. It is sectional drawing of the vending machine shown in FIG. It is a refrigerant circuit figure concerning the example of the present invention. It is a block diagram of a control apparatus. It is a circuit diagram which shows the flow of the refrigerant | coolant in the cooling heating setting mode CCC. It is a principal part flowchart of the thermocycle operation control which concerns on the Example of this invention. It is a circuit diagram which shows the flow of the refrigerant | coolant at the time of the heat pump driving | operation in the left store | warehouse | chamber and the right store | warehouse | chamber in cooling heating setting mode CHH. It is a circuit diagram which shows the flow of the refrigerant | coolant by the forced pump down control which concerns on the Example of this invention.

Exemplary embodiments of a vending machine according to the present invention will be described below in detail with reference to the accompanying drawings. Note that the present invention is not limited to the embodiments.
First, a vending machine according to an embodiment of the present invention will be described with reference to a perspective view of FIG. 1 and a sectional view of FIG. In these drawings, the vending machine includes a main body cabinet 10 formed as a rectangular heat insulator having an open front surface, an outer door 20 and an inner door 30 provided on the front surface, and an interior of the main body cabinet 10 in two directions. The bottom plate 11 is partitioned and formed at the stage, and the upper part is cooled by, for example, three independent product storage units 40a, 40b, and 40c separated by two heat insulating partition plates 40w, and the lower part product storage units 40a, 40b, and 40c are cooled or Cooling / heating of the vending machine by the temperature sensor Ta, Tb, Tc disposed inside the machine room 50 for storing the cooling / heating unit 60 for heating and the outer door 20 and in the product storages 40a, 40b, 40c. And a control device 90 that controls operation and the like.

More specifically, the outer door 20 is used to open and close the front opening of the main body cabinet 10 and is not shown in the figure. Product display room, selection button for selecting the product to be sold, money slot for inserting money, product outlet 21 for taking out the paid-out product, etc. Is arranged.
The inner door 30 opens and closes the front surfaces of the product storage units 40a, 40b, and 40c to keep the products in the interior warm. The inner door 30 is a box-shaped structure that is divided into upper and lower stages and has a heat insulator inside. The upper inner door 30a is pivoted at one end to the outer door 20, and the other end is engaged with the outer door 20, and the upper inner door 30a is opened at the same time as the outer door 20 is opened to facilitate replenishment of goods. It is to make. The lower inner door 30b is in a closed state when one end pivots on the main body cabinet 10 and the other end is hooked on the main body cabinet 10 with a latch (not shown) and the outer door 20 is opened. It is possible to prevent the cool air or warm air in the storage cases 40a, 40b, and 40c from flowing out, and to open as necessary during maintenance.

The product storage units 40a, 40b, and 40c are for storing products such as canned beverages and beverages containing plastic bottles at a desired temperature, and the capacity of the storage units is the product storage units 40a, 40c. , 40b in a large manner. In this embodiment, the product storage 40a is exclusively used for cooling, and the product storages 40b and 40c are also used for cooling and heating. The product storage racks 40a, 40b, and 40c store the products in a manner that they are arranged in the vertical direction, and are provided with a product storage rack R that includes a product delivery mechanism for discharging the products one by one in response to a sales signal. There is a product carry-out chute 42 for carrying the discharged product S to the sales port 21 of the outer door through a carry-out door 31 installed in the inner door 30b.
The cooling / heating unit 60 includes a compressor 61, a condenser 62, an expander 63, a second expander 79, an accumulator 69, and an external heat exchanger 76 in the machine room 50, straddling the bottom plate 11. The inside heat exchangers 65a, 65b, and 65c are provided in the cabinet, and each device is connected by a refrigerant pipe. The cooling / heating unit 60 cools or heats the product S in the product storage rack R by circulating cool air or warm air in the cabinet according to the cooling / heating setting mode.

The compressor 61 for cooling and heating is for compressing the refrigerant and circulating it in the circuit. During the cooling operation, the evaporation temperature is about −10 ° C., the condensation temperature is about 40 ° C., and during the heating operation, An evaporation temperature of about −10 ° C. and a condensation temperature of about 70 ° C. are used.
The condenser 62 is a fin tube type heat exchanger, and discharges unnecessary condensation heat during the cooling operation. A fan 62f is installed at the rear of the condenser 62. The fan 62f sucks air from the front opening of the machine chamber 50, sucks heat of condensation by the condenser 62, and absorbs exhaust heat of the compressor 61. Thus, the air is exhausted to the rear opening of the machine room 50.
The expander 63 decompresses the refrigerant passing during the cooling operation and adiabatically expands, and is, for example, a capillary or a fixed expansion valve. Moreover, a temperature expansion valve and an electronic expansion valve may be sufficient.
The flow divider 64 is for distributing the refrigerant adiabatically expanded by the expander 63 to the internal heat exchangers 65a, 65b, 65c.

The internal heat exchangers 65a, 65b, and 65c are for cooling the product storage units 40a, 40b, and 40c, and the internal heat exchangers 65b and 65c are the interiors for heating the product storage units 40b and 40c. It also serves as a heat exchanger. The capacity of the internal heat exchanger is distributed in a large manner in the order of 65a, 65c, 65b corresponding to the capacity of the product storage. The internal heat exchangers 65a, 65b, 65c are installed at the lower part of each product storage, surrounded by a wind tunnel 67, a fan 65f is installed behind them, and a duct 67d is installed behind them. Has been. The cooling and heating in the product storage are performed by blowing the air cooled or heated by the internal heat exchangers 65a, 65b, 65c to the product S in the product storage, and the duct 67d as shown by the arrow in FIG. It is done by more circulating recovery.
The accumulator 69 is a sealed container for flowing in the refrigerant evaporated from the internal heat exchangers 65a, 65b, 65c, separating the gas and liquid, storing the liquid refrigerant, and returning the gas-phase refrigerant to the compressor 61. . The accumulator 69 is also a container for storing the refrigerant remaining in the refrigerant circulation of the circuit.

The external heat exchanger 76 is a fin tube type heat exchanger, and discharges unnecessary condensation heat during heating operation.
The expander 79 decompresses the refrigerant passing during the heating operation and adiabatically expands, and is, for example, a capillary or a fixed expansion valve. Moreover, a temperature expansion valve and an electronic expansion valve may be sufficient.
The heaters 66b and 66c are installed in front of the in-compartment heat exchangers 65b and 65c, and heat the commodity storages 40b and 40c when the heating single operation is performed without performing the heat pump operation.
The inside temperature sensors Ta, Tb, Tc are installed on the upper surface of the wind tunnel 67 in the product storage 40a, 40b, 40c, and are used to detect the inside temperature of the product storage 40a, 40b, 40c. is there.

The condenser solenoid valve 68 opens and closes the refrigerant passage between the compressor 61 and the condenser 62, and the heater solenoid valves 68b and 68c are compressed between the compressor 61 and the internal heat exchangers 65b and 65c. It opens and closes the refrigerant passage. The cooler inlet solenoid valves 70a, 70b, 70c open and close the expanded refrigerant passage between the flow divider 64 and the internal heat exchangers 65a, 65b, 65c. The cooler outlet solenoid valves 72b, 72c It opens and closes the passage of the evaporated refrigerant between the internal heat exchangers 65b and 65c and the compressor 61.
The refrigerant circuit configuration of the cooling / heating unit 60 will be described in detail with reference to the refrigerant circuit diagram of FIG. The refrigerant circuit configuration includes a cooling circuit 60A that only cools the inside of the cabinet and a heating / cooling circuit 60B that simultaneously performs cooling and heating inside the cabinet (performs a heat pump operation). In addition, the enclosure of the dotted line in the figure has shown typically goods storage 40a, 40b, 40c.

  The cooling circuit 60A is connected from the compressor 61 to the flow divider 64 via the condenser 62 and the expander 63, and after being divided from the flow divider 64 to the internal heat exchangers 65a, 65b, 65c, to the collector 67. And return to the compressor 61 via the accumulator 69. Specifically, the cooling circulation circuit 60 </ b> A has three pipelines connected to the flow divider 64 from the compressor 61 via the condenser solenoid valve 68, the condenser 62, and the expander 63, and the flow divider 64. A pipe that is diverted in the direction to reach the cooler inlet electromagnetic valves 70a, 70b, 70c, a pipe that leads from the cooler inlet electromagnetic valve 70a to the collector 67 via the internal heat exchanger 65a, and a cooler inlet A conduit that passes from the solenoid valves 70b and 70c to the in-compartment heat exchangers 65b and 65c via check valves 71b and 71c, respectively, and gathers at the gathering portion 67 via the cooler outlet solenoid valves 72b and 72c, and a gathering portion It is constituted by a pipeline that returns from 67 to the compressor 61 via the accumulator 69.

On the other hand, in addition to the cooling circulation circuit 60A, the heating / cooling circulation circuit 60B is connected in parallel to the condenser electromagnetic valve 68 from the compressor 61, and the check valves 71b, 71c are respectively connected via the heater electromagnetic valves 68b, 68c. Through the check valve 71, 71 from the intermediate point between the pipe line connected to the intermediate point between the internal heat exchanger 65b, 65c and the internal heat exchanger 65b, 65c and the cooler outlet electromagnetic valve 72b, 72c. A pipe connected to the external heat exchanger 76 and a pipe connected from the external heat exchanger 76 to an intermediate point between the expander 63 and the diverter 64 via the second expander 79; Is provided. The check valves 71 and 71 may be electromagnetic valves.
Thus, the heating / cooling circulation circuit 60B is connected from the compressor 61 to the internal heat exchangers 65c, 65b via the heater electromagnetic valves 68b, 68c, and from the internal heat exchangers 65c, 65b to the check valve 71. , 71 through an external heat exchanger 76 and an expander 79 and connected to a distributor 64, and from a flow divider 64 through a cooler inlet electromagnetic valve 70a to an internal heat exchanger 65a. This is a circuit that returns to the compressor 61 via the unit 67 and the accumulator 69.

As the refrigerant, a refrigerant used at a critical pressure or lower, for example, a fluorocarbon refrigerant, R134a is used. Moreover, the refrigerant | coolant used above a critical pressure, for example, a carbon dioxide refrigerant, may be sufficient.
The control device 90 controls the cooling or heating of the product storages 40a, 40b, and 40c in the cooling / heating setting mode. As shown in the control block diagram of FIG. 4, the CPU 90, the memory, and the heat pump are internally provided. A timer memory 92 for storing the total operation mode time is provided, and the cooling / heating operation mode is controlled by setting an operation mode setting SW 91 for setting the cooling / heating operation mode. And the control apparatus 90 is the compressor 61, the condenser solenoid valve 68, and the cooler inlet solenoid valves 70a, 70b, 70c so that the temperature detected by the inside temperature sensors Ta, Tb, Tc is within a certain temperature range. The interior temperature of the refrigerator is maintained at an appropriate temperature by a thermocycle operation in which the cooler outlet solenoid valves 72b and 72c, the heater solenoid valves 68b and 68c, and the like are ON / OFF controlled.

The thermo-cycle operation is connected to the entrance / exit side of the internal heat exchanger in the product storage when the internal temperature becomes OFF temperature (for example, -2 ° C for cooling and 61 ° C for heating). When the internal temperature reaches the ON temperature (for example, 8 ° C for cooling and 41 ° C for heating), the solenoid valve is closed on the inlet / outlet side of the internal heat exchanger in the product storage. By opening the connected solenoid valve, the path of the refrigerant circulating in the circuit is appropriately switched to control the interior at an appropriate temperature.
In addition, when the controller 90 pauses one internal heat exchanger and performs a heat pump operation with another internal heat exchanger, the controller 90 measures the total time of the heat pump operation, and the total time is a predetermined time ( For example, when it reaches 120 minutes), it has a forced pump down control for operating the cooling single operation for a second predetermined time (for example, 3 minutes).

  Here, when the operation mode setting SW91 is set to the CCC mode, the control device 90 opens the condenser solenoid valve 68, the cooler inlet solenoid valves 70a, 70b, 70c, and the cooler outlet solenoid valves 72b, 72c, and the heater The solenoid valves 68b and 68c are closed, and the compressor 61 is driven. At this time, as indicated by the thick line in FIG. 5, the high-temperature refrigerant compressed by the compressor 61 is condensed by the condenser 62 to become a liquid and expands by the expander 63 to become a low-temperature gas-liquid two-phase flow. After being divided into three directions, it flows into the internal heat exchangers 65a, 65b, 65c. The inflowing refrigerant evaporates in the internal heat exchangers 65a, 65b, and 65c, cools the product storages 40a, 40b, and 40c, and the evaporated refrigerant collects in the accumulator 67 to the accumulator 69 that stores the liquid refrigerant. It flows in and is separated into gas and liquid, and only the gas phase refrigerant returns to the compressor 61. In this cooling, the controller 90 controls the internal temperature to an appropriate temperature by the thermocycle operation by the internal temperature sensors Ta, Tb, and Tc.

  When the operation mode setting SW 91 is set to the CHH mode, the control device 90 opens the heater solenoid valves 68b and 68c and the cooler inlet solenoid valve 70a, and the condenser solenoid valve 68 and the cooler inlet solenoid valves 70b and 70c. Then, the cooler outlet solenoid valves 72b and 72c are closed, and the compressor 61 is driven. At this time, the refrigerant circulates in the circuit indicated by the thick line in FIG. 6, and the high-temperature refrigerant compressed by the compressor 61 passes through the heater electromagnetic valves 68b and 68c to the two internal heat exchangers 65b and 65c. Inflow. The refrigerant flowing into the internal heat exchangers 65b and 65c condenses, heats the product storage 40b and 40c, gathers via the check valves 71 and 71, and further condenses in the external heat exchanger 76. It flows into the second expander 79. The refrigerant that has flowed into the expander 79 expands into a low-temperature and low-pressure gas-liquid two-phase flow and flows into the internal heat exchanger 65a via the flow divider 64 and the cooler inlet electromagnetic valve 70a. The refrigerant flowing into the internal heat exchanger 65a evaporates in the internal heat exchanger 65a, cools the product storage 40a, and returns to the compressor 61 via the collector 67 and the accumulator 69. In this heat pump operation, the inside of the cabinet is maintained at an appropriate temperature by the thermocycle operation as described above.

In addition, when one internal heat exchanger is stopped during the thermocycle operation and the heat pump operation is performed with another internal heat exchanger, the control device 90 measures the total time of the heat pump operation in the operation mode. When the total time reaches a predetermined time, forced cooling down control is performed to operate the cooling single operation for a second predetermined time. This forced pump down control will be described by taking as an example a case where the heat pump operation of the right compartment 40c is performed with reference to the main part flowchart of the thermocycle operation control of FIG.
First, the control device 90 detects the temperature of each product storage by the temperature sensors Ta, Tb, Tc (S1), and the temperature in each storage reaches the thermo OFF temperature or the temperature of the thermo ON temperature. It is determined whether it has been reached (S2). If the temperature of the storage is not the thermo OFF temperature or the thermo ON temperature (S2; N), the same operation mode is continued and the process returns to the beginning. If the temperature of the storage has reached the thermo OFF temperature or the thermo ON temperature (S2; Y), it is determined whether the operation mode is the heat pump operation mode (S3). If the operation mode is not the heat pump operation mode (S3; N), the operation returns to the beginning in the operation of the new heat pump operation mode. If the operation mode is the heat pump operation mode (S3; Y), is the same mode as the previous time? Is determined (S4). In the case of the example, since the heat pump operation is performed in the right warehouse 40c, if the current heat pump operation mode is the same as the previous right warehouse 40c one heat pump operation mode (S4; Y), the operation time is accumulated in the timer memory 92. (S5). Next, it is determined whether the total time is a predetermined time (S6). If the total time is within the predetermined time (S6; N), the process returns to the beginning and the heat pump operation mode is continued.

  Specifically, in the case of the heat pump operation of the right warehouse 40c, as shown in FIG. 7, the control device 90 opens the heater electromagnetic valve 68c and the cooler inlet electromagnetic valve 70a, and the condenser electromagnetic valve 68, The heater solenoid valve 68b, the cooler inlet solenoid valves 70b and 70c, and the cooler outlet solenoid valves 72b and 72c are closed, and the compressor 61 is driven. At this time, the refrigerant circulates in the circuit indicated by the thick line in the figure, and the high-temperature refrigerant compressed by the compressor 61 flows into the internal heat exchanger 65c via the heater electromagnetic valve 68c and condenses. The storage 40c is heated. The condensed refrigerant flows into the second expander 79 via the check valve 71 and the external heat exchanger 76 and is expanded to become a low-temperature and low-pressure gas-liquid two-phase flow. The refrigerant that has become a low-temperature and low-pressure gas-liquid two-phase flow flows into the internal heat exchanger 65a via the flow divider 64 and the cooler inlet electromagnetic valve 70a, and evaporates in the internal heat exchanger 65a. The storage 40 a is cooled and returned to the compressor 61 via the collector 67 and the accumulator 69. Thus, when the heat pump operation of the right warehouse 40c is continued, a small amount of refrigerant leaked from the heater electromagnetic valve 68b which is closed as shown by the broken line arrow in FIG. It will be stored in the container 65b. Therefore, in this embodiment, forced pump-down control is configured so as to collect the refrigerant stored in the internal heat exchanger 65b based on the duration time of the single heat pump operation.

  That is, if the total time of the same heat pump operation mode exceeds a predetermined time (S6; Y), forced pump down control is performed (S7). The operation at the forced pump down control is a cooling only operation of the left warehouse 40a only. Specifically, as shown in FIG. 9, the control device 90 opens the condenser solenoid valve 68 and the cooler inlet solenoid valve 70a, and the heater solenoid valves 68b and 68c, the cooler inlet solenoid valves 70b and 70c, the cooling The compressor outlet solenoid valves 72b and 72c are closed, and the compressor 61 is driven. At this time, as indicated by the bold line in the figure, the high-temperature refrigerant compressed by the compressor 61 flows into the condenser 62 through the condenser electromagnetic valve 68 and condenses, and the condensed refrigerant flows into the expander 63. And is expanded into a low-temperature low-pressure gas-liquid two-phase flow. The refrigerant that has become a low-temperature and low-pressure gas-liquid two-phase flow flows into the internal heat exchanger 65a via the flow divider 64 and the cooler inlet electromagnetic valve 70a, and evaporates in the internal heat exchanger 65a. The storage 40 a is cooled and returned to the compressor 61 via the collector 67 and the accumulator 69. At this time, the refrigerant stored in the in-compartment heat exchanger 65b is cooled and circulated through the check valve 71, the external heat exchanger 76, and the second expander 79, as indicated by the dashed arrows in FIG. It is collected in the circuit. As a result, the refrigerant circulation rate can be maintained in an appropriate state even when the cooling and heating operation is continued in the operation mode in which the internal heat exchanger 40b is stopped.

Then, the forced pump-down is performed for a second predetermined time (S8; N). When the second predetermined time is reached (S8; Y), the recovery of the refrigerant is terminated and the timer memory 92 is reset (S9). Return to the beginning.
In addition, when the heat pump operation is another mode in step S4, in this example, when the heat pump operation of the right warehouse 40c is switched to the heat pump operation of the middle warehouse 40b, the warehouse in the paused middle warehouse 40b is stored. Since the internal heat exchanger 65c is opened to the refrigerant circuit and the circulating refrigerant flows, the timer memory 92 is reset (S10) and the process returns to the beginning.
As described above, when one internal heat exchanger 40b is suspended and the heat pump operation is performed in the other internal heat exchanger 40c, the internal heat exchange is performed when the total time of the heat pump operation reaches a predetermined time. By performing forced pump-down control in which only the cooling unit 40a is operated for the second predetermined time, the refrigerant stored in the internal heat exchanger 40b leaked from the heater solenoid valve 68b and stopped is recovered in the refrigerant circuit. As a result, the refrigerant circulation rate can be maintained in an appropriate state, so that an efficient cooling and heating operation can be performed.

DESCRIPTION OF SYMBOLS 10 Main body cabinet 20 Outer door 30 Inner door 40a, 40b, 40c Product storage 60 Cooling / heating unit 61 Compressor 62 Condenser 63, 79 Inflator 64 Shunt 65a, 65b, 65c Intra-chamber heat exchanger 68 Condenser electromagnetic Valve 68a, 68b Heater solenoid valve 70a, 70b, 70c Cooler inlet solenoid valve 72b, 72c Cooler outlet solenoid valve 90 Controller 91 Operation mode setting SW
92 Timer memory

Claims (1)

A vending machine having a product storage for cooling and heating, and selectively cooling or heating the product storage by a cooling heating setting mode of cooling and heating,
A compressor that compresses the refrigerant; a condenser that is provided outside the refrigerator and condenses the refrigerant via a condenser solenoid valve; an expansion unit that expands the refrigerant; a distributor that distributes the refrigerant expanded by the expansion unit; A cooling circulation circuit comprising: a plurality of internal heat exchangers that evaporate the refrigerant from the distributor via the cooler inlet electromagnetic valve; and a merger that merges the evaporated refrigerant via the cooler outlet electromagnetic valve As well as
A piping connection is made between the internal heat exchanger and the cooler inlet electromagnetic valve from the compressor via the heater electromagnetic valve to the cooling circuit, and the internal heat exchanger and the cooler Heating / cooling circulation in which heat pump operation is performed by connecting the internal heat exchanger as a condenser by connecting a pipe to the distributor via an external heat exchanger and second expansion means from between the outlet solenoid valves In vending machines that make up the circuit,
When the heat pump operation is performed in another internal heat exchanger excluding at least one internal heat exchanger, when the total time of the heat pump operation reaches a predetermined time, the cooling single operation is operated for a second predetermined time. A vending machine having a control device.

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