RU2357317C1 - Timer of refrigerators defrosting - Google Patents

Abstract

FIELD: mechanics.

SUBSTANCE: invention refers to automatics. The device includes power supply, timer, heater, defrosting finish sensor, compressor, voltage suppressor, first and second rectifiers, first and second extinguishing elements, three-pin electromagnetic relay movable contact of which is connected to power supply second pole. Timer inverting input is connected with power supply first pole through heater and with second fixed relay contact through defrosting finish sensor. Timer common leg is connected with power supply second pole. Timer output is connected with second fixed relay contact through two series-connected circuits. The first circuit is formed by relay winding and threshold element. The second circuit is formed by first rectifier and first extinguishing element. Common point of the first and the second circuits is connected with timer common leg through voltage suppressor and with first fixed relay contact through circuit of series-connected second rectifier and second extinguishing element (the third circuit). The first fixed relay contact is connected with power supply first pole through compressor. According to the second version the device includes power supply, timer, heater, defrosting finish sensor, compressor, voltage suppressor, first and second rectifiers, first and second extinguishing elements, three-pin electromagnetic relay movable contact of which is connected to power supply second pole. Timer common leg is connected with power supply second pole. Timer inverting input is connected with power supply first pole through heater and with second fixed relay contact through defrosting finish sensor. Timer output is connected with relay winding first output, the second output of which is connected with the second fixed relay contact through series-connected first rectifier and first extinguishing element. Common point of relay winding second output and circuit formed by series-connected first rectifier and first extinguishing element is connected with timer common leg through voltage suppressor and with fixed first relay contact through circuit of series-connected second rectifier and second extinguishing element. The first fixed relay contact is connected with power supply first pole through compressor. Timer is performed with additional control input connected with voltage suppressor. Additional control input provides the possibility for timer to receive a signal about power in the circuit after emergency shutdown.

EFFECT: structure simplification, increase of operation safety at the expense of decreasing the requirements for timer elements permissible work voltage, decrease of discrete elements quantity, facilitation of optimal version choice for certain conditions of use.

3 cl, 3 dwg

Description

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

Known timer for the defrost of refrigerators on half-wave rectifiers (patent for invention No. 2255274, priority 23.10.2003), containing a power source, time counter, heater, end defrost sensor, compressor, first and second rectifiers, first and second blanking elements, three-pin a relay whose movable contact is connected to the second pole of the power source; the common output of the time counter is connected to the second pole of the power source; the counting input of the time counter through the defrost end sensor is connected to the second fixed relay contact and through the heater is connected to the first pole of the power source; the output of the time counter is connected to the second fixed relay contact through two circuits connected in series, formed, on the one hand (the first circuit) by the relay coil and the threshold element, and on the other hand (the second circuit) - by the first rectifier and the first quenching element; the counter output is connected to the first fixed relay contact also through two circuits connected in series, formed, on the one hand (the first circuit) - by the relay coil and the threshold element, and on the other hand (the third circuit) - by the second rectifier and the second blanking element.

Extinguishing elements in the known timer circuit are designed to reduce the voltage of the power source to a value acceptable for reliable operation of the entire device. In this case, the main function of the first quenching element is the accumulation of energy at the output of the rectifier, sufficient for the relay to operate.

After the relay is triggered (when switching its moving contacts from position “a” to position “b”), the relay coil is supplied with power through the second quenching element, the main function of which is to maintain the relay in the operated state.

The threshold element serves to restore the timer after an emergency shutdown of the mains voltage when the counter output is closed with a common output, that is, the timer performs the defrost process. Without a threshold device, the voltage at the rectifier output when the mains voltage appears due to the relatively low resistance of the relay winding and the relatively high resistance of the first quenching element can only increase to a value significantly lower than the response voltage. The relay will remain in the released state and the defrost mode will not be restored. The threshold device allows the voltage at the output of the rectifier to reach the response value of the relay, after which it closes the power circuit of its winding.

A disadvantage of the known timer circuit is the significant voltage at the output of the first rectifier when the counter reads out the total compressor operating time necessary before defrosting (the counter output is open and there is no load for the first rectifier). The voltage at the output of the first rectifier in this case reaches the amplitude value of the supply voltage, which sharply increases the requirements for the permissible operating voltage of the filter capacitor of the rectifier and the key element at the output of the counter and, as a result, leads to a significant increase in their cost.

The technical problem solved by the invention is to simplify the design, increase reliability by reducing the requirements for the allowable working voltage of timer elements, reduce the number of discrete elements, facilitate the selection of the best option for specific application conditions.

The problem is solved as follows.

According to the first variant, the defrost timer of freezers containing a power source, a time counter, a heater, a defrost end sensor, a compressor, a voltage limiter, the first and second rectifiers, the first and second quenching elements, a three-pin electromagnetic relay, the 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 pole of the power source and through the end defrost sensor to the second fixed relay contact; the common output of the time counter is connected to the second pole of the power source; the output of the time counter is connected to the second fixed relay contact through two circuits connected in series, formed on one side (the first circuit) by the relay coil and the threshold element and on the other hand (second circuit) by the first rectifier and the first quenching element; a common point of the first and second circuit is connected through a voltage limiter to a common terminal of the time counter and connected through a chain of series-connected second rectifier and second quenching element (third circuit) to the first fixed relay contact; the first fixed contact of the relay through the compressor is connected to the first pole of the power source.

According to the second variant, the defrost timer of freezing devices containing a power source, a time counter, a heater, a defrost end sensor, a compressor, first and second rectifiers, first and second damping elements, a voltage limiter, a three-pin electromagnetic relay, a movable contact of which is connected to the second pole of the power source ; the common output of the time counter 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 pole of the power source and through the end defrost sensor to the second fixed relay contact; the output of the time counter is connected to the first output of the relay winding, the second output of which is connected through the circuit from the first rectifier and the first blanking element connected in series with the second fixed relay contact; the common point of the second terminal of the relay winding and the circuit formed by the first rectifier and the first quenching element connected in series, connected to the common terminal of the time counter through a voltage limiter and connected to the first fixed relay contact through the chain of the second rectifier and the second quenched element connected in series; the first fixed contact of the relay through the compressor is connected to the first pole of the power source; the time counter is made with an additional control input connected to a voltage limiter; through an additional control input, it is possible to receive a time counter for a signal on the appearance of the mains voltage after its emergency shutdown.

In the timer according to the second embodiment, the time counter may contain: a delay time counter having two inputs — an installation input and a counting input and two outputs — a first output and an inverse output, a voltage conditioner pulse shaper, the output of which is connected to the delay time counter installation input, and the input is an additional input of the time counter control, the first logical element “AND”, the output of which is connected to the counting input of the delay time counter, the first input of the first logical element “AND” is the counting input a time counter, and the second input of the first logic element “AND” is connected to the inverse output of the delay time counter, the second logic element “And” and the counter of the compressor’s working hours, while the first input of the compressor’s working hours’ counter is the common output of the time counter, the second input of the time counter the compressor operation is the counting input of the time counter, the output of the compressor operating time counter is connected to the input of the second logic element “I”, the other input of which is connected to the first output of the time counter leverage, the output of the second logical element "AND" is the output of the time counter.

Fundamentally new in the timer in both cases is the introduction of a voltage limiter parallel to the rectifier output, for example a zener diode or a resistor or a circuit from a zener diode and a resistor connected in series, designed to limit the voltage at the rectifier output when the time counter is open to a value sufficient to trigger the relay, which reduces the requirements for the permissible operating voltage of the filter capacitor of the rectifier and the key element at the output of the counter.

The proposed timer design provides two equivalent possibilities for restoring the defrost mode after emergency power outages.

According to the first option, the timer included in the freezer defrost system works as follows. When the mains voltage is applied, the moving contact of the relay is closed to the first fixed contact. The compressor starts to work. From the second pole of the power source, the current passes through the time counter and the idle heater to the first pole of the power source, providing a time counter that starts to count the compressor operating time, proportional to the number of voltage fluctuations of the power supply network (or internal clock). Further, along the circuit, the second pole of the power source, the voltage limiter, the first rectifier and the first suppressor element connected in series, the contacts of the defrost end sensor closed after a cold set, the idle heater, the first pole of the power source begins to flow the charge current of the rectifier filter capacitor. Due to the relatively high resistance of the first quenching element, the current flowing through the heater is negligible and the heater does not work. When the voltage across the rectifier filter capacitor reaches the level of the voltage limiter, the circuit of the threshold device is closed; The timer is prepared for relay operation. After counting the set compressor operation time and closing the output of the time counter, a current begins to flow along the circuit of the second pole of the power supply, time counter, relay coil, threshold element, the first rectifier and the first blanking element connected in series, the closed contacts of the defrost end sensor, the idle heater, the first pole power source. Relay trips; its movable contact closes with the second fixed contact. The heater is energized, and the defrost process begins. After the relay coil is powered, the second pole of the power source, time counter, threshold element, the second rectifier and the second blanking element, the idle compressor, the first pole of the power source are connected in series. The counting input of the time counter is shorted by the closed contacts of the defrost end sensor. The interruption in the counter operation continues until the end of the defrost and opening of the sensor contacts. After that, the current from the second pole of the power source through the time counter, the idle heater enters the first pole of the power source. The time counter counts the pause time after the defrost (there may not be a pause). At the end of the pause, the time counter returns to its original state, opening the power circuit of the relay winding; the moving contact of the relay switches to the first fixed contact; the cycle repeats.

In this case, it does not matter in which sequence the first rectifier and the first quenching element are connected relative to the second fixed relay contact, the second rectifier and the second quenching element are relative to the first fixed relay contact, and the threshold element and relay coil are relative to the time counter output. With any arrangement of the listed elements, each of them performs the corresponding functions. As a result, it becomes possible to vary the relative position of the respective rectifiers and damping elements, the threshold device and the relay winding. This is important from the point of view of the design of the timer under severe restrictions in the volume of the device, as it allows to achieve a denser layout.

According to the second option, the timer works similarly to the first, except that a threshold device is excluded from the relay winding supply circuit, and the voltage increase at the rectifier output to the relay operation voltage (its value is determined by the voltage limiter) is provided by a time counter with an additional control input, when which voltage in the time counter is formed a signal of the appearance of the voltage of the supply network. The counter output closes with a time delay that is obviously sufficient to charge the rectifier filter capacitor to the relay operation voltage. This is achieved by standard means, for example, by including in the circuit of the time counter of the pulse shaper the appearance of the mains voltage, the input of which is an additional control input, two “I” circuits, a delay time counter, a compressor operating time counter, interconnected accordingly.

These standard tools are easily implemented as part of a single integrated circuit, which significantly reduces the number of discrete timer elements and increases its reliability.

The voltage limiter used in this embodiment may include a device for converting the output voltage range of the rectifier in accordance with the requirements imposed by the integrated circuit of the time counter with an additional control input to the levels of input signals.

Thus, the work is ensured in the necessary (predetermined) mode of the claimed timer as a whole.

The proposed timer versions provide an optimal choice for specific applications and are intended for use in types of refrigeration devices, the electrical circuit of which provides for the connection of a common output of the time counter to the moving contact of an electromagnetic relay, for example in DAEWOO refrigerators, models FR-3501, 3502, 3503, FR-3801, 3802, 3803, etc.

The inventive timer is illustrated by drawings.

Figure 1 shows a functional diagram of a timer according to the first embodiment.

Figure 2 shows a functional diagram of a timer according to the second embodiment.

Figure 3 presents a variant of the functional diagram of a time meter with an additional control input.

The timer according to the first embodiment (Fig. 1) contains a time counter 1, a three-contact electromagnetic relay with a winding 2, a threshold element 3, the first 4 and second 16 rectifiers, the first 5 and second 15 blanking elements, the movable contact 7 of the relay, the first 6 and second 8 fixed relay contacts, defrost end sensor 9, heater 10, compressor 11, first 12 and second 13 poles of the power supply, voltage limiter 14. A movable relay contact 7 is connected to the second pole 13 of the power source. The counting input of the time counter 1 through the heater 10 is connected to the first pole 12 of the power source and through the sensor 9 of the end of the defrost - with the second 8 fixed relay contact. The common output of the time counter 1 is connected to the second pole 13 of the power source. The output of the time counter 1 is connected to the second 8th relay contact via two circuits connected in series, formed on one side (the first circuit) by the relay coil 2 and the threshold element 3 and on the other hand (the second circuit) by the first rectifier 4 and the first quenching element 5. The common point of the first and second circuit through the voltage limiter 14 is connected to the common output of the time counter 1 and through a chain of series-connected second rectifier 16 and the second blanking element 15 (third circuit) is connected to the first 6 fixed relay contact . The first 6 fixed contact of the relay through the compressor 11 is connected to the first pole 12 of the power source.

According to the first embodiment (figure 1), the timer included in the defrosting system of the freezer operates as follows. When the mains voltage is applied, the moving contact 7 of the relay is closed to the first 6 fixed contact. The compressor 11 starts to work. From the second pole 13 of the power source, the current passes through the time counter 1 and the idle heater 10 to the first pole 12 of the power source, providing a time counter, which starts to count down the compressor 11, proportional to the number of fluctuations in the voltage of the supply network (or internal clock generator). Next, through the circuit, the second pole 13 of the power source, voltage limiter 14, the first rectifier 4 and the first blanking element 5 connected in series, the contacts of the sensor 9 for defrosting end closed after a cold set, the idle heater 10, the first pole 12 of the power source begins to flow the charge current of the filter capacitor rectifier. Due to the relatively high resistance of the first quenching element 5, the current flowing through the heater 10 is negligible and the heater 10 does not work. When the voltage across the rectifier filter capacitor reaches the level of voltage limiter 14, the circuit of the threshold device 3 is closed; The timer is prepared for relay operation. After counting the set operating time of the compressor 11 and closing the output of the time counter 1, a current begins to flow along the circuit of the second pole 13 of the power supply, time counter 1, relay coil 2, threshold element 3, the first rectifier 4 and the first blanking element 5 connected in series, the sensor contacts are closed 9 the end of the defrost, the idle heater 10, the first pole 12 of the power source. Relay trips; the movable contact 7 closes with the second 8 fixed contact. The voltage is supplied to the heater 10, - the defrost process begins. Power supply to the relay winding 2 after operation is carried out through the circuit of the second pole 13 of the power source, time counter 1, threshold element 3, the second rectifier 16 and the second blanking element 15 connected in series, the idle compressor 11, the first pole 12 of the power source. The counting input of the time counter 1 is shorted by the closed contacts of the sensor 9 of the end of the defrost. The interruption in the counter operation continues until the end of the defrost and opening of the sensor contacts. After that, the current from the second pole 13 of the power source through the time counter 1, the idle heater 10 is supplied to the first pole 12 of the power source. Time counter 1 counts the pause time after the defrost (there may not be a pause). At the end of the pause, the time counter 1 returns to its initial state, opening the power circuit of the relay winding 2; moving contact 7 of the relay switches to the first 6 fixed contact; the cycle repeats.

The timer according to the second embodiment (figure 2) contains a time counter 17, a three-contact electromagnetic relay with winding 2, the first 4 and second 16 rectifiers, the first 5 and second 15 blanking elements, the movable contact 7 of the relay, the first 6 and second 8 fixed relay contacts , defrost end sensor 9, heater 10, compressor 11, first 12 and second 13 poles of the power supply, voltage limiter 18. A movable relay contact 7 is connected to the second pole 13 of the power source. The counting input of the time counter 1 through the heater 10 is connected to the first pole 12 of the power source and through the sensor 9 of the end of the defrost - with the second 8 fixed relay contact. The common output of the time counter 17 is connected to the second pole 13 of the power source. The output of the time counter 17 is connected to the first output of the relay winding 2; the second output of the relay winding 2 through a chain of series-connected first rectifier 4 and the first quenching element 5 is connected to the second fixed contact 8 of the relay; the common point of the second terminal of the relay winding 2 and the circuit formed by the first rectifier 4 and the first quenching element 5 connected in series is connected to the common terminal of the time counter 17 through the voltage limiter 18 and connected to the first one through the series of the second rectifier 16 and the second quenched element 15 6 fixed relay contact; the first fixed contact 6 of the relay through the compressor 11 is connected to the first pole 12 of the power source; the time counter 17 is made with an additional control input connected to a voltage limiter 18; through an additional control input, it is possible to receive a time counter for a signal on the appearance of the mains voltage after its emergency shutdown.

According to the second option (figure 2), the timer included in the defrosting system of the freezer operates as follows. When the mains voltage is applied, the moving contact 7 of the relay is closed to the first 6 fixed contact. The compressor 11 starts to work. From the second pole 13 of the power source, the current passes through the time counter 17 and the idle heater 10 to the first pole 12 of the power source, providing a time counter that starts to count the compressor 11, proportional to the number of fluctuations in the voltage of the supply network (or internal clock generator). Current also begins to flow along the circuit, the second pole 13 of the power source, the voltage limiter 18, the circuit from the first rectifier 4 and the first blanking element 5 connected in series, the contacts of the defrosting end sensor 9 closed after a cold set, the idle heater 10, the first pole 12 of the power source. There is a process of establishing the output voltage of the first rectifier 4. Due to the relatively high resistance of the first quenching element 5, the current flowing through the heater 10 is negligible and the heater 10 does not work. At the same time, voltage is supplied through the voltage limiter 18 to the additional control input of the time counter 17; the delay time begins, during which the output of the time counter 17 is closed. When the delay time expires, the voltage on the filter capacitor of the first rectifier 4 obviously reaches the level of the voltage limiter 18; the ban on closing the output of the time counter 17 is removed; The timer is prepared for relay operation. After counting the set operating time of the compressor 11 and closing the output of the time counter 17, a current begins to flow along the circuit of the second pole 13 of the power supply, time counter 17, relay coil 2, a chain of series-connected first rectifier 4 and first blanking element 5, closed contacts of the end sensor 9 defrost, inoperative heater 10, first pole 12 of the power source. The relay operates, the movable contact 6 closes with the second fixed contact 8. A voltage is applied to the heater 10, and the defrost process begins. The winding 2 of the relay is powered by the circuit: the second pole 13 of the power source, the time counter 17, the circuit from the second rectifier 16 and the quenching element 15 connected in series, the idle compressor 11, the first pole 12 of the power source. The counting input of the time counter 17 is shorted by the closed contacts of the sensor 9 of the end of the defrost. The interruption in the operation of the time counter 17 continues until the defrost and opening of the contacts of the sensor 9 are completed. After that, the current from the second pole 13 of the power source through the time counter 17, the idle heater 10 enters the first pole 12 of the power source. The time counter 17 counts the pause time after the defrost (there may not be a pause). At the end of the pause, the time counter 17 returns to its initial state, opening the power circuit of the relay winding 2; moving contact 6 of the relay switches to the first fixed contact 7; the cycle repeats.

The voltage limiter 18 used in this embodiment may include a device for converting the output voltage range of the first 4 and second 16 rectifiers in accordance with the requirements imposed by the integrated circuit of the time counter 17 to the input signal levels.

The time counter 17 (Fig. 3) contains a delay time counter 19, which has two inputs — an installation input and a counting input and two outputs — a first output and an inverse output, a driver 20 of a voltage generation pulse, the output of which is connected to the installation input of the delay time counter 19 and the input is an additional control input of the time counter 17, the first logic element "And" 21, the output of which is connected to the counting input of the delay time counter 19, the first input of the first logic element "And" 21 is the counting input of the time counter 17 and the second input of the first logic element "And" is connected to the inverse output of the delay time counter 19, the second logic element "And" 23 and the time counter 22 of the compressor, while the first input of the time counter 22 of the compressor is a common output of the time counter 17, the second the input of the compressor operation time counter 22 is the counting input of the time counter 17, the output of the compressor operation time counter 22 is connected to the input of the second logic element “AND” 23, the other input of which is connected to the first output of the time counter LCD 19, the output of the second logical element "AND" 23 is the output of the time counter 17.

The time counter 17 (Figure 3), included in the timer circuit, operates as follows. In the initial state, the first output of the delay time counter 19 is in the state "1". This state persists indefinitely (including during short-term power outages), since the passage of clock pulses to the counting input is blocked by the element "And" 21 (the inverse output of the counter 19 is in the state "0"). In this case, the output status of the counter 22 is transmitted through the circuit "And" 23 to the output of the counter 17. When it appears again in the defrost mode after a short-term power failure, the driver 20 supplies a pulse to the input of the delay time counter 19. The first output of the counter 19 goes into state "0"; circuit "And" 23 prevents the output of the counter 17 to close the relay power circuit. The charge of the rectifier filter capacitor begins. The inverted output of the counter 19 goes into state “1”, allowing the passage of clock pulses through the circuit “I” 21 to the counting input of the delay time counter 19. The delay time is calculated, which is obviously longer than the charge time of the capacitor to the relay voltage, after which the counter 19 goes into initial state, allowing the circuit "And" 23 to close the power circuit of the relay winding. The relay is activated, restoring the defrost mode after a short-term power failure.

Claims (3)

1. A defrost timer for freezing devices containing a power source, a time counter, a heater, a defrost end sensor, a compressor, a voltage limiter, first and second rectifiers, first and second blanking elements, a three-contact electromagnetic 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 pole of the power source and through the end defrost sensor to the second fixed relay contact; the common output of the time counter is connected to the second pole of the power source; the output of the time counter is connected to the second fixed relay contact through two circuits connected in series, formed on one side (the first circuit) by the relay coil and the threshold element and on the other hand (second circuit) by the first rectifier and the first quenching element; a common point of the first and second circuit is connected through a voltage limiter to a common terminal of the time counter and connected through a chain of series-connected second rectifier and second quenching element (third circuit) to the first fixed relay contact; the first fixed contact of the relay through the compressor is connected to the first pole of the power source. 2. A defrost timer for freezing devices containing a power source, a time counter, a heater, an end defrost sensor, a compressor, first and second rectifiers, first and second damping elements, a voltage limiter, a three-pin electromagnetic relay, a movable contact of which is connected to the second pole of the power source; the common output of the time counter 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 pole of the power source and through the end defrost sensor to the second fixed relay contact; the output of the time counter is connected to the first output of the relay winding, the second output of which is connected through the circuit from the first rectifier and the first blanking element connected in series with the second fixed relay contact; the common point of the second terminal of the relay winding and the circuit formed by the first rectifier and the first quenching element connected in series, connected to the common terminal of the time counter through a voltage limiter and connected to the first fixed relay contact through the chain of the second rectifier and the second quenched element connected in series; the first fixed contact of the relay through the compressor is connected to the first pole of the power source; the time counter is made with an additional control input connected to a voltage limiter; through an additional control input, it is possible to receive a time counter for a signal on the appearance of the mains voltage after its emergency shutdown. 3. The timer according to claim 2, in which the time counter contains a delay time counter having two inputs — an installation input and a counting input and two outputs — a first output and an inverse output, a pulse shaper of the appearance of the mains voltage, the output of which is connected to the time counter installation input delays, and the input is an additional input of the time counter control, the first logical element “And”, the output of which is connected to the counting input of the delay time counter, the first input of the first logical element “And” is the counting input of the time counter the second input of the first logic element “And” is connected to the inverse output of the delay time counter, the second logic element “And” and the counter of the compressor’s working hours, while the first input of the compressor’s working hours counter is the general output of the time counter, the second input of the working hours counter the compressor is the counting input of the time counter, the output of the compressor operating time counter is connected to the input of the second logic element "AND", the other input of which is connected to the first output of the delay time counter, the output torogo logical element "I" is the output of the time counter.

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