RU2249163C2 - Timer for refrigerator - Google Patents

Abstract

FIELD: refrigerator automatics.

SUBSTANCE: timer has power source, time counter, heater, defrosting pickup, compressor, three-contact relay, two rectifiers, and first and second quenching members. The common lead of the time counter is connected with the movable contact of the three-contact electromagnetic relay. The defrosting pickup is connected between the inlet of the time counter and the second unmovable contact of the relay. The heater is connected between the input of the time counter and the first pole of the power source. The outputs of the second rectifier are connected with the movable contact of the relay and first movable contact of the relay through the second quenching member.

EFFECT: reduced power consumption and enhanced design.

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Description

The invention relates to the field of automation and can be used for periodic switching actuators of AC automation, such as refrigeration devices.

A known timer (RF patent No. 2147463, pr. 04/03/2000), containing a power source, a time counter, a heater, a defrost end sensor, a compressor, a three-pin relay, a movable contact of which is connected to the second pole of the power source, the counting input of the time counter through the heater is connected to the second fixed relay contact and connected to the first pole of the power source through the defrost end sensor, the common output of the time counter is connected to the first fixed relay contact and connected to the first pole of the source through the compressor voltage, and the output - with the first output of the relay winding, while the second output of the relay winding is connected to the second pole of the power supply through an additionally included control circuit, which is a series-connected threshold element, a rectifier and a first ballast resistor, the rectifier inputs are connected between the fixed switching contacts of a three-pin electromagnetic relay through a second ballast resistor.

Resistors in the known timer circuit are suppressor elements and are designed to suppress excessive voltage of the power source. In this case, the main function of the second ballast resistor is the accumulation of energy at the output of the rectifier, sufficient for the relay to operate.

As a result of the relay actuation (when switching its moving contacts from position “a” to position “b”), the first ballast resistor is connected in parallel with the second ballast resistor, the main function of which is to ensure that the relay is held together with the second ballast resistor.

A disadvantage of the known timer circuit is the significant energy loss of the rectifier, due to the fact that when the moving relay contacts are in the initial position - “a” (before the relay is activated), the first ballast resistor is connected in parallel with the rectifier, i.e. the first ballast resistor shunts the rectifier. At the same time, the current supplying the rectifier occurs through the first ballast resistor. The lower the resistance value of the first ballast resistor, the greater the leakage current passing through this resistor.

With an increase in the resistance value of the first ballast resistor, the possibilities of keeping the three-pin relay in the activated state decrease (position “b” of the relay's moving contact). In position “b” of the moving contact of the relay, the first and second ballast resistors are switched on in parallel, therefore, at significant resistance values of the first ballast resistor, the current value at the rectifier output may not be enough to hold the relay.

Thus, the resistance value of the first ballast resistor depends on the resistance value of the second ballast resistor and on the amount of current required to hold the relay. Those. the choice of each of these circuit elements depends on each other and is limited by each other.

In addition, the well-known timer can be used in refrigeration devices, the electrical circuit of which provides for the connection of the common output of the time counter to the fixed contact of the electromagnetic relay, for example, in STINOL freezers - 106, 112.

The use of the timer circuit known in the patent No. 2147463 in refrigerators of another type (the electrical circuit of which provides for connecting the common output of the time counter to the moving contact of the relay, for example, DAEWOO refrigerators, models FR-3501, 3502, 3503, FR-3801, 3802, 3803 ) impossible. Simply switching the common output of the time counter to the moving contact of the electromagnetic relay will not provide the specified algorithm for the circuit, because the timer with this connection will calculate the compressor operating time and the pause time after defrost, regardless of the position of the defrost sensor contacts (voltage will be supplied to the time counter in both positions of the moving relay contact).

The technical problem solved by the invention is the expansion of the arsenal of technical means related to the timers of refrigeration devices, reducing energy consumption by reducing its losses during the operation of the timer, increasing the degree of versatility of the timer.

The problem is solved in that in the timer of refrigeration devices containing a power source, a time counter, a heater, a defrost end sensor, a compressor, two rectifiers, the first and second extinguishing elements, a three-pin relay, a movable contact of which is connected to the second pole of the power source, a counting input the time counter through the heater is connected to the first pole of the power source, and through the defrost end sensor to the second fixed relay contact, the common output of the time counter is connected to the movable contact le, the compressor is connected between the first fixed contact of the relay and the first pole of the power source, the first inputs of both rectifiers are connected to the common output of the time counter, the second input of the first rectifier through the first quenching element is connected to the second fixed contact of the relay, and the second input of the second rectifier is through the second quenching element connected to the first fixed relay contact, the outputs of both rectifiers are connected to the output of the time counter through a threshold element and a relay winding connected in series.

In the proposed timer circuit, the common output of the time counter is connected to the movable contact of the three-contact electromagnetic relay.

The operation of the timer is ensured by the fact that the defrost sensor is connected between the counting input of the time counter and the second fixed relay contact, and the heater is connected between the counting input of the time counter and the first pole of the power source. The inputs of the second rectifier are connected on the one hand to the movable relay contact, and on the other hand, through the second quenching element to the first fixed relay contact.

With this connection scheme of these elements, the counter and timer work as a whole according to a given algorithm.

When the mains voltage is applied, the moving contact of the relay is in the normally closed state “a” of the switching contacts. Current flows from the second pole of the power source through a time counter, the heater to the first pole of the power source. In this case, the heater does not work, because its internal resistance is much less than the internal resistance of a time counter. At the same time, the current from the second pole of the power source enters the compressor and then to the first pole of the power source. The compressor is running, the counter counts the compressor running time. After a set of cold, the contacts of the defrost sensor are closed, the current begins to flow along the circuit from the second pole of the power source through the first rectifier, the first blanking element, the defrost sensor, the heater to the first pole of the power source. In this case, the heater does not work, since the relay contacts are in position “a”, at which the compressor is operating. With the passage of current through the first quenching element, a transition process begins to establish the output voltage of the first rectifier. After reaching the voltage at the output of the first rectifier, a value sufficient for reliable operation of the relay, the threshold element opens and the supply voltage is applied to the second contact of the relay winding. The operation of the relay and the switching of contacts to position “b” will occur if the necessary voltage is supplied to the first winding of the relay coil from the output of the time counter corresponding to a given time interval.

When switching the contacts to position “b”, since the contacts of the defrost sensor are closed, the heater turns on, the defrost of the refrigerator begins. In this case, the current flows through the circuit: from the second pole of the power source through the closed contacts of the defrost sensor, the heater to the first pole of the power source.

At the same time, voltage is applied to the inputs of the second rectifier through the second quenching element, at the output of which the output voltage is set. At the same time, the compressor does not work, and the current flows through the circuit: the second pole of the power source, the second rectifier, the second blanking element, the compressor, the first pole of the power source. When the relay contacts are in position “b”, the circuit formed by the first rectifier and the first quenching element is shorted and does not work. The relay coil is powered only from the second rectifier, i.e. rectifiers work alternately.

When the contacts are in position “b”, the time counter stops working, because its inputs are shunted by a defrost probe whose contacts are closed.

When a defrost occurs, when the set temperature is reached, the defrost probe contacts open. A current flows through the time counter (along the circuit: the second pole of the power supply, time counter, heater, first pole of the power supply) and the pause is counted after the defrost, when both the compressor and heater do not work, because the internal resistance of the time counter is much greater than the resistance of the compressor and heater.

At the end of the pause, the time counter returns to its initial state, the voltage is removed from the first output of the relay coil and the relay contacts switch to the “a” position, the cycle repeats.

Thus, the timer is provided according to the given algorithm for those types of refrigerators, the electrical circuit of which provides for the connection of the common output of the time counter to the movable relay contact.

Since both rectifiers operate alternately, currents through both quenching elements also flow alternately with the corresponding position of the movable contact (“a” or “b”), there is no loss of energy supplied to the input of each rectifier. The choice of the magnitude of the main characteristic of each extinguishing element is solely due to the need to ensure that the relay is activated and to keep it activated. Such a choice is made for each extinguishing element independently, regardless of the parameters of the other extinguishing element. Those. Each rectifier and all other timer circuit elements operate in an optimal mode without unproductive energy losses.

As extinguishing agents, such elements can be selected that provide suppression of excessive voltage by their resistance (active or reactive). In this case, the amount of energy accumulated at the output of the rectifier is inversely proportional to the value of this resistance.

The magnitude of this resistance is the main characteristic of a quenching element.

The choice of the magnitude of the main characteristic of the first quenching element is determined only by the necessary response time of the three-pin relay. The choice of the magnitude of the main characteristic of the second extinguishing element is determined solely by the value at which its value will ensure that the relay is maintained in the activated state. The choice of the values of the main characteristics of both extinguishing elements is determined only by the above conditions and does not depend on the value of the main characteristic of the other extinguishing element, since during operation of the timer both extinguishing elements do not affect each other.

Thus, the energy losses during the timer are reduced, and its versatility is ensured due to the fact that the choice of circuit elements (first and second extinguishing elements) is determined only by their functions and is independent of one another, which allows changing some characteristics with less restrictions timer (for example, the response time of the relay after the counter signal is issued or the timer is consumed in compressor operation mode), depending on the conditions of its use.

The prior art does not reveal the designs of timers characterized by the claimed combination of features, therefore, the present invention meets the patentability criterion of “novelty”.

The claimed combination of features of the invention, which provides an expansion of the arsenal of hardware related to the timers of refrigeration devices, reducing energy consumption by reducing its losses during the operation of the timer, increasing the degree of versatility of the timer compared to those known from the prior art, allows us to conclude that The claimed invention meets the patentability criterion of “inventive step”.

The drawing shows a block diagram of a timer.

The timer contains:

1. Time counter.

2. Three-contact electromagnetic relay.

3. The threshold element.

4. Rectifier 1 power.

5. Rectifier 2 power.

6. Resistor 1.

7. Resistor 2.

8. Switching contacts of a three-contact electromagnetic relay.

9, 10, 11. Elements for periodically switching on a controlled device (9 - heater; 10 - defrost end sensor; 11 - compressor).

12. The first pole of the power source.

13. The second pole of the power source.

The movable contact of the relay 2 is connected to the second pole of the power source 13. The counting input of the time counter 1 through the heater 9 is connected to the first pole 12 of the power source and through the sensor 10 of the end of the defrost is connected to the second fixed contact of the relay. The common output of the time counter 1 is connected to the movable contact of the relay 2. The compressor 11 is connected between the stationary contact “a” of the relay 2 and the first pole 12 of the power source. The output of the counter 1 is connected to the first output of the relay winding 2. The first inputs of the rectifiers 4 and 5 are connected to the common output of the counter 1. In this case, the second output of the rectifier 4 through the resistor 6 is connected to the fixed contact “b” of the relay 2, and the second output of the rectifier 5 through the resistor 7 is connected to the fixed contact “a” of relay 2.

The outputs of both rectifiers 4 and 5 through a threshold element 3 are connected to the second terminal of the relay coil 2.

The device operates as follows.

The timer is included in the defrost system of the refrigerator.

When the mains voltage is applied, the movable contact of relay 2 is in the normally closed state “a” of the switching contacts 8. Current flows through the counter 1 and the operating time of the compressor 11 is counted. At the same time, the heater 9 does not work, because the internal resistance of the counter 1 is much greater than the resistance of the heater 9. After a set of cold, the contacts of the sensor 10 are closed, as a result of which voltage is applied to the inputs of the rectifier 4 through the resistor 6 and the transition process of establishing its output voltage begins. Upon reaching a voltage sufficient for reliable operation of relay 2, the threshold element 3 opens and supplies the supply voltage to the second contact of the coil of electromagnetic relay 2. The operation of relay 2 and the switching of contacts 8 to position “b” will occur provided that the necessary relay 2 is supplied to the first winding of the coil voltage from the output of counter 1, corresponding to a given time interval.

When contacts 8 are switched from position “a” to position “b”, heater 9 is switched on (by closed contacts of sensor 10), defrosting of the refrigerator begins. At the same time, a voltage is supplied through the resistor 7 to the inputs of the rectifier 5, at the output of which the output voltage is set. When contacts 8 are in position “b”, counter 1 stops working, because its input contacts are bridged by a sensor 10, the contacts of which are closed.

When the defrost has occurred, when the set temperature is reached, the contacts of the sensor 10 open. A current flows through counter 1 and a pause is counted after the defrost, when both compressor 11 and heater 9 are not working, because the internal resistance of the counter 1 is much greater than the resistance of the compressor 11 and the heater 9.

At the end of the pause, counter 1 returns to its initial state, the voltage is removed from the first output of relay coil 2, and contacts 8 are switched to position “a”, the cycle repeats.

Claims (1)

A cooling device timer comprising a power source, a time counter, a heater, a defrost end sensor, a compressor, two rectifiers, first and second blanking elements, a three-pin relay, a movable contact of which is connected to the second pole of the power source, the counting input of the time counter through the heater is connected to the first the power supply pole, and through the defrost end sensor - with the second fixed relay contact, the common output of the time counter is connected to the moving relay contact, the compressor is connected between the first by moving the relay contact and the first pole of the power supply, the first inputs of both rectifiers are connected to the common output of the time counter, the second input of the first rectifier through the first quenching element is connected to the second fixed relay contact, and the second input of the second rectifier through the second quenching element is connected to the first fixed relay contact , the outputs of both rectifiers are connected to the output of the time counter through a series-connected threshold element and a relay coil.