JPS6234390Y2 - - Google Patents

Description

[Detailed explanation of the idea] (b) Industrial application fields The present invention relates to a defrost control device for a vending machine.

(b) Conventional technology Vending machines that cool and sell products are known to have a defrost heater that is activated by a timer so that the cooler can be defrosted periodically. It is shown in Utility Model Publication No. 47-21482.

(c) Problems that the invention aims to solve However, especially in vending machines that store frozen products such as ice cream, when the defrost operation and product loading work overlap, the defrost heater is not activated by the defrost operation. There is a drawback that the temperature inside the refrigerator rises rapidly due to heat and the outside air temperature that enters when the front door is opened during the loading operation, causing the products to melt and become deformed.

In view of the above points, the present invention provides a defrost control device for a vending machine in which the loading operation and the defrosting operation do not overlap.

(d) Means for solving the problem The present invention provides a vending machine equipped with a cooler with a defrost timer that switches its own switch for a predetermined amount of time at regular intervals, and a defrost timer that switches its own switch for a predetermined amount of time at regular intervals. a first defroster relay which is energized via a switch of the timer and whose demagnetization is delayed by a delay means even when the timer has accumulated a predetermined value and the contact of the switch is switched; a second defrost relay that is energized through the switch of the first defrost relay during the delay and self-maintained through its own switch; and a defrost that is energized while the second defrost relay is energized. a defrost heater, an operating switch that operates based on an operation related to product loading to demagnetize the second defrost relay, and when defrosting is performed by the heater and the temperature of the cooler reaches a predetermined temperature or higher; and a return thermoswitch that opens to demagnetize the second defrost relay.

(e) Operation When the defrost timer switch is switched, the second defrost relay is
The defrost relay is energized, and the defrost heater is energized via the switch of this second defrost relay. When the activation switch is activated based on the product loading operation while the defrost heater is energized, or the return thermo switch is activated when the temperature of the cooler exceeds a predetermined temperature, the second defrost relay is demagnetized and the frost is removed. The power supply to the intake heater is stopped. Furthermore, even if the timer switch operates while the activation switch is operating, the excitation circuit of the second defrost relay is opened by the activation switch, so the second defrost relay is not energized. The defrost heater is not energized.

(f) Example An example of the present invention will be described below in detail based on the drawings.
First, numerals 1 and 2 are AC power lines, and numeral 3 is a defrost timer which is constantly energized and closes the switch 3A to the C contact for a predetermined time at regular intervals. The b contact of the switch 3A is connected to the coil 4A of the defrost relay A4 via the diode D and resistor _R2 .
The C contact is connected to the A contact of switch 4B of the relay A4. Also, the resistor _R1 and the capacitor C are connected in series, and this
It is connected to a series circuit of R ₂ and coil 4A. Defrost relay A4 has coil 4A and switch 4B
The other end of the coil 4A is connected to the line 2, and the b contact of the switch 4B is connected to the coil 5A of the defrost relay B5. Defrost relay B5 has a coil 5A and switches 5B and 5C.
The a contact of B is connected to the b contact of the switch 4B and the coil 5A, and the b contact is connected to the a contact of switch 5C and line 1. The other end of the coil 5A is connected to an operating switch 6 which is operated based on operations related to loading products into the main body of the ice cream vending machine. The operating switch 6 may be, for example, a door switch that is activated when the front door forming the front surface of the vending machine is opened for loading, or a loading switch that is manually operated when loading the vending machine. 7 is the return thermo switch,
It opens when the surface temperature of the cooler exceeds 8°C and closes when it falls below -2°C, and one end is connected to the operating switch 6 and the other end to the line 2. A defroster heater 8 is used to remove frost adhering to the cooler, and one end is connected to the b contact of the switch 5C, and the other end is connected to the line 2. 9 is a fixed point thermo switch, which opens when the surface temperature of the cooler is 0℃ or higher and closes when the surface temperature of the cooler is -13℃ or lower.One end is connected to the c contact of the switch 5C, and the other end is connected to the electric fan for cold air circulation. The fan motor 10 is connected to the line 2. This fixed point thermo switch 9 and the fan motor 1
A series circuit of a temperature control thermoswitch 12 and a compressor 11 is connected in parallel to a series circuit of a temperature control thermoswitch 12 and a compressor 11. The temperature control thermoswitch 12 is installed inside the storage, closes when the temperature inside the refrigerator is -17°C or higher, and opens when the temperature inside the refrigerator is lower than -21°C, reducing the temperature inside the refrigerator to approximately -19°C.
The compressor 11 is controlled to maintain the same.

The operation of the above configuration will be explained below.
First, when voltage is applied to power supply lines 1 and 2, line 1 - b contact of switch 3A - diode D -
By closing the resistor R ₂ , the coil 4A, the resistor R ₁ , and the capacitor C line 2, the defrost relay A4 is energized and the capacitor C is charged. When the relay A4 is energized, the switch 4B is changed to a B contact, but the defrost relay B5 is not energized and the switch 5B,
5C is closed to the c contact. Therefore, the compressor 11 is energized and operated via the C contact of the switch 5C and the temperature control thermoswitch 12. Then, the temperature of the cooler eventually drops below a predetermined temperature, for example -13
When the temperature drops below 0.degree. C., the fixed point thermo switch 9 closes, and the electric fan motor 10 for circulating cool air in the refrigerator starts operating. In this way, the inside of the storage is cooled. And temperature control thermo switch 12 is minus 17
It closes when the temperature is above ℃ and opens when the temperature is below minus 21 degrees Celsius, and the compressor 11 operates and stops to maintain the inside of the refrigerator at approximately minus 19 degrees Celsius. Then, when the defrost timer 3 performs an integration operation for a predetermined period of time, the switch 3A is changed to a C contact, so that the defrost relay A4 is demagnetized after the capacitor C is discharged. This capacitor C
During discharge, line 1 - switch 3A's c contact -
When the b contact of switch 4B, coil 5A, operating switch 6, thermo switch 7, and line 2 are closed, defrost relay B5 is energized and its own switch 5B is energized.
Since the capacitor C is self-held via the b contact of the capacitor C, it will not be demagnetized even after the capacitor C has finished discharging. By energizing the defrost relay B5, the switch 5C is changed to a B contact, so the power fan motor 10 and the compressor 11 immediately stop operating, and the defrost heater 8 is energized to remove the frost that has adhered to the cooler. Begin to. Eventually, when the frost is removed from the cooler and the surface temperature of the cooler increases and exceeds 8°C,
The return thermoswitch 7 is opened. Then, the self-holding circuit of the defrost relay B5 is released, and the switch 5C changes to the c contact, and at this time, the temperature inside the refrigerator also rises to -17°C or more, so the temperature control thermo switch 12 is closed. Yes compressor 11
is energized and operates. However, the electric fan motor 10 does not start at the same time because the fixed point thermo switch 9 is open because the surface temperature of the cooler is 0° C. or higher. When the surface temperature of the cooler eventually reaches -13° C., the thermoswitch 9 closes, and the fan motor 10 starts operating.
Therefore, since the electric fan motor 10 is operated after the temperature of the cooler has sufficiently decreased, warm air is not sent into the storage, so the ice cream in the storage does not melt. The time that the timer 3 is activated and the switch 3A is closed to the c contact is short and is set to return during defrosting, but the defrost relay B5 is activated by the activation switch 6 regardless of the set time. , return thermo switch 7
controlled by.

Next, we will discuss a case where the manager attempts to load a product while the cooler is being defrosted. When I tried to load this and opened the front door,
The actuation switch 6 is opened. Therefore, switch 5B
Defrost relay B, which was self-maintained via the B contact of
5 is demagnetized, the defroster heater 8 is de-energized, the compressor 11 is energized, and when the surface temperature of the cooler falls below -13° C., the electric fan motor 10 is also operated. In other words, if you try to load the product during defrosting, defrosting is immediately stopped, so the temperature increase due to defrosting will not be added to the increase in internal temperature due to loading, so the ice cream will not melt. It is something.

We will also discuss the case where the defrosting time comes during product loading. First, before the defrost time, defrost relay A4 is energized via the b contact of switch 3A, but relay B5 is demagnetized. Therefore, in this state, the compressor 11 and the cold air circulation electric fan motor 10 are in operation. At this time, when loading the product, the operating switch 6 is opened. During this loading, when the defrost time comes, the timer 3 operates and the switch 3A changes to the C contact, but the capacitor C
Due to the discharge, the operating switch 6 is open even though the switch 4B is still in the b contact, so the defrost relay B5 is not energized. Therefore, the defrost heater 8 is not energized and no defrost is performed this time.

(G) Effects of the invention As mentioned above, this invention provides a vending machine with a cooler that has a defrost timer that switches its own switch for a predetermined amount of time at regular intervals, and a defrost timer that switches its own switch for a predetermined amount of time at regular intervals. a first defrost relay which is sometimes energized via a switch of the timer, and whose demagnetization is delayed by a delay means even if the timer completes a predetermined integration and the contact of the switch is switched; a second defrost relay that is energized through the switch of the first defrost relay and self-maintained through its own switch; and a defrost relay that is energized while the second defrost relay is energized. a heater, an operation switch that operates based on an operation related to product loading to demagnetize the second defrost relay, and an operation switch that opens when defrosting is performed by the heater and the temperature of the cooler reaches a predetermined temperature or higher. and a reset thermoswitch that demagnetizes the second defrost relay.
Defrosting operation is not performed during loading work. Therefore, the internal temperature of the refrigerator does not rise too rapidly, so that deformation of frozen products such as ice cream due to melting can be prevented.

[Brief explanation of the drawing]

The figure is a control circuit diagram showing an embodiment of the present invention. 6...Operating switch, 8...Defrost heater.

Claims (1)

[Scope of utility model registration request] A vending machine with a cooler has a defrost timer that switches its own switch for a predetermined amount of time at regular intervals, and when the timer has not reached a predetermined cumulative value, the timer is energized via the timer switch. a first defrost relay whose degaussing is delayed by a delay means even if the contact point of the switch is switched after a predetermined integration; A second defrost relay that is energized and self-maintained via its own switch; a defrost heater that is energized while the second defrost relay is energized; and a defrost heater that operates based on operations related to product loading. an operating switch that demagnetizes the second defrost relay when the heater performs defrosting and the temperature of the cooler reaches a predetermined temperature or higher, a return thermostat that opens and demagnetizes the second defrost relay. Defrost control device for vending machines consisting of a switch.