KR830002146B1 - Cooling device for hot and cooling vending machine - Google Patents

Abstract

No content.

Description

Cooling device in the hot and cold vending machine

1 and 2 are front and side views showing the overall structure of a hot / cold vending machine.

3 is a refrigerant circuit diagram of a conventional internal cooling apparatus.

4 is a control circuit diagram of FIG.

5 is a refrigerant circuit diagram of an embodiment of the present invention.

6 is a control circuit diagram of FIG.

7 and 8 are explanatory diagrams of the progress of the cold operation according to the conventional and the embodiments of the present invention, respectively.

The present invention relates to an internal cooling device of a hot / cold vending machine. It is common to cool or warm containers and bottles such as beverages handled in a vending machine in a plane, and to contribute them to sales as cooling products or warm products.

In addition, in order to diversify the product and to sell the cooling product and the heated product in the same season according to the season, the product storage compartment is partitioned into a plurality of chambers, and each of the chambers can be sent or selected for warming operation. Vending machines are becoming practical. In this case, a refrigerator is used as the cooling means, and a heat transfer heater is generally used as the heating means.

Here, the outline | summary of the conventional live hot and cold vending machine is demonstrated according to drawing.

In FIG. 1 and FIG. 2, (1) the main cabinet of the vending machine, (2) is a front door, and the cabinet of the cabinet 1 is partitioned by two left and right goods storage rooms 3A and 3B. Each shelf is equipped with a merchandise shelf 4. The goods carried out according to the sales instruction are discharged to the product discharge port 6 via the shooter 5.

However, the storage chamber 3A is a product storage chamber dedicated to cooling, and is provided with a refrigerator evaporator 7A and a high internal blower fan 8A. On the other hand, in the storage chamber 3B, the heater 9 is provided by the evaporator 7B and the blower fan 8B as a heating or cooling goods storage chamber.

In the lower machine room of the cabinet (1), a condenser unit (13) of a refrigerator, in which a motor compressor (10), a condenser (11) and an external outer fan (12) are combined, is disposed. ) To form a refrigerant circuit.

Next, the conventional circuit of the refrigerant circuit is shown in FIG.

In other words, the evaporators 7A and 7B of the storage chambers 3A and 3B are connected to each other in parallel with the condensation unit 13 via expansion valves 14 serving as capillaries. Here, two series branched refrigerant circuits including the evaporator of each storage chamber are denoted by reference numerals 15A and 15B.

In addition, as a control means for maintaining the cold storage temperature of the cooled product in each of the storage chambers 3A and 3B, the temperature controllers 16A and 16B which sense the room temperature and operate at a set temperature, respectively. In addition, solenoid valves 17A and 17B are inserted and connected to the branch refrigerant circuits 15A and 15B at the inlet side, respectively.

Next, the electrical control circuit of the refrigerant circuit of FIG. 3 is shown in FIG. 18A and 18B are auxiliary relays, 19 are cold-heating operation selection switches, and 20 are thermostats for controlling the heater 9.

As is apparent from the circuit shown, the temperature controllers 16A and 16B of each of the storage chambers 3A and 3B open and control the solenoid valves 17A and 17B, respectively, so that each branch refrigerant circuit 15A, When the flow of the refrigerant to the 15B is controlled, and the solenoid valves 17A and 17B are all closed together, the compressor 10 of the condensation unit 13 via the auxiliary relays 18A and 18B, The operation of the high external fan 12 is stopped.

In addition, FIG. 3 is shown slightly, and the pillar relay, the overload relay, etc. of a compressor motor are abbreviate | omitted. In addition, when the operation selector switch 19 is switched to sell the heated product in the storage chamber 3B, the solenoid valve 17B is closed and the auxiliary relay 18B is not operated, and the heater 9 is energized. do.

The actual operation progress when the cold storage operation is performed together with the storage chamber 3A and the storage chamber 3B by the cold storage control method will be described with reference to FIG.

In the figure, m, n, m ', and n' indicate contact closing and opening points of the temperature controllers 16A and 16B of each storage chamber, and on and off indicate operation and stop periods of the condensation unit 13. Is displayed.

However, as shown in FIG. 7, the opening and closing cycles of the temperature controllers 16A and 16B generally do not coincide due to unbalance of the freezing load in the storage compartment 3A and the storage compartment 3B. to be. On the other hand, the condensation unit 13 is controlled to continue operation even when the evaporator is in the rest state by closing the solenoid valve of the other storage chamber as long as the temperature controller of the at least one storage chamber contains the contact point.

As a result, the operating period " on " of the condensation unit 13 is extremely longer than the stop period " off ", and the state remains almost always operated. Furthermore, the capacity of the condensation unit 13 is determined in advance by balancing the total load of the freezing loads of the storage chambers 3A and 3B, and is applied only to the freezing load of one of the storage chambers 3A and 3B. Even if it consumes the power required for the operation of the condensation unit, the power consumption as a whole is high, the operation efficiency is lowered.

In addition, as is apparent from the control circuit configuration of Fig. 4, each of the temperature controllers 16A and 16B controls the opening and closing control of the solenoid valve and the operation control of the condensation unit. In addition, there is a difficulty in complicating the circuit configuration such as the need for an auxiliary relay.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned point, and it is advantageous that the power consumption is small so that energy saving and operation cost can be reduced while maintaining the cold storage temperature of each storage compartment at an appropriate temperature. It is an object of the present invention to provide an in-vehicle cooling apparatus for hot and cold vending machines.

According to the present invention, the evaporator of each commodity storage chamber is connected to one refrigerator condenser unit in parallel with each other via an expansion valve to form a refrigerant circuit, and at the same time, the evaporator of a warm or cold commodity storage chamber is constructed. The solenoid valve is inserted only in the branch refrigerant circuit included, and furthermore, the condensing unit is controlled by the temperature controller of the exclusive product storage chamber among the temperature controllers installed in each product storage chamber, and the electronic controller is controlled by the temperature controller of the hot / cold product storage chamber. This is achieved by opening and closing the valve.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

First, in the refrigerant circuit of FIG. 5, the basic circuit thereof is the same as that of FIG. 2, but differs from FIG. 2 only in the storage chamber 3B, which is a hot / cold product storage chamber among the storage chambers 3A and 3B. The solenoid valve 17B is inserted in the refrigerant circuit 15B. Here, the evaporators 7A and 7B installed in the storage chambers 3A and 3B, the refrigerant evaporation temperature, the heat exchange area, and the blowing amount of the fan inside the refrigerator are added to the refrigeration load conditions of the chambers. In the same cold operation cycle, each high temperature is selected in advance so as to maintain approximately a predetermined temperature. On the other hand, the control circuit has a circuit configuration as shown in FIG.

According to this circuit configuration, the condensation unit 13 is operated and stopped controlled regardless of the operation of the temperature controller 16B under the operating conditions of the temperature controller 16A of the cooling exclusive product storage chamber 3A. On the other hand, the temperature controller 16B controls the opening and closing of only the solenoid valve 17B under its operating conditions.

In particular, the temperature controller 16B controls the flow of the refrigerant to the solenoid valve 17B, that is, the evaporator 7B, for the purpose of preventing freezing in the cold storage of the goods stored in the storage chamber 3B. The opening operating point is set to the temperature just before the product freezes.

When the operation of the storage chamber 3B is switched from cold to warm, the solenoid valve 17B is closed and is heated by the heater 9.

An example of the actual operation progress by the said cold storage operation control is shown in FIG. As apparent from this figure, the refrigeration condenser unit 13 is operated and controlled via the temperature controller 16A according to the internal temperature condition of the storage compartment 3A, and at the same time in accordance with the same operation cycle, the evaporator of the storage compartment 3B. (7B) also maintains the internal temperature of the high temperature while operating control.

Therefore, the operation period of the condensation unit 13, that is, the amount of power consumption is greatly reduced compared to the conventional method of FIG. 7, and can greatly contribute to energy saving. In addition, since the solenoid valve 17B was controlled solely with respect to the storage chamber 3B by the temperature controller 16B, when the goods with high product temperature of the storage chamber 3A were replenished, Even if an imbalance occurs in a refrigeration load such that the product has already been sufficiently cooled, in the storage chamber 3B, the temperature controller 16B opens the contact point at the operating point m 'and closes the solenoid valve 17B. The temperature is not controlled and the freezing of the product can be prevented.

In addition, the control circuit of FIG. 6 can eliminate the solenoid valve 16A, the auxiliary relays 18A, 18B, and the like, compared with FIG. .

Claims (1)

In the cabinet, a product storage room exclusively for cooling equipped with an evaporator of a refrigerator and a heating or cooling product storage compartment equipped with a heater and an evaporator of a refrigerator are installed, and each product storage is provided in a hot / cold vending machine for refrigeration or warming of the internally stored products. The refrigerant evaporator is connected to each other in parallel to the refrigerator condenser unit via expansion valves to form a refrigerant circuit, and the solenoid valve is inserted only in the branch refrigerant circuit including the evaporator of the heating or cooling product storage compartment. Further, among the temperature controllers installed in each product storage room, the condensing unit is operated by the temperature controller of the cooling product storage room and the solenoid valve is opened and closed by the temperature controller of the heating or cooling product storage room. Cooling device in hot and cold vending machines.

Images