RU2256289C1 - Thawing timer on base of half-wave rectifiers - Google Patents

Abstract

FIELD: automatics, namely devices for automatic periodic connection of actuators of AC apparatuses such as refrigerators.

SUBSTANCE: timer includes time counter 1; three-contact electromagnetic relay 2; threshold unit 3; power supply rectifiers 4,5; switching contacts of relay 8; hater 9; thawing ending sensor 10, compressor 11, poles 12, 13 of power source. Use of two half-wave rectifiers allows to arrange circuit elements closer one relative to other while satisfying safety demands.

EFFECT: improved design, enhanced operational reliability.

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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 the 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 at the rectifier output, 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 normal functioning and operability of the known timer are ensured only if the rectifier supplying the relay winding is made half-wave, i.e. works in every half-cycle of mains voltage. In this case, the connection of the second input of the rectifier with the first fixed relay contact is necessary in order to ensure a half-wave operation mode of the rectifier.

When a half-wave rectifier is used in the defrost timer circuit, the location of the damping elements relative to the circuit elements, in particular the rectifier, is strictly defined. The second blanking element must be connected between the first input of the rectifier and the second fixed relay contact, and the first blanking element must be connected between the first input of the rectifier and the second pole of the power source. Only with such an arrangement of the quenching elements, each of them will fulfill its function, namely: the second quenching element will provide the voltage level at the rectifier output necessary for the relay to operate, and the first quenching element together with the first will keep the relay activated.

With a different arrangement of the damping elements relative to the rectifier, the timer will be disrupted. In this case, the extinguishing elements will not perform their functions - to ensure that the relay is activated and to keep it activated.

Thus, the known timer will be workable, and each extinguishing element will perform its function only if they are so arranged, as indicated in the formula and description of the timer according to patent No. 2147463.

Strict assignment of the location of the circuit elements reduces the possibility of changing the dimensions of the timer circuit, reduces the possibility of maneuver with respect to the dimensions of the timer if the timer needs to be built into ready-made objects. In addition, the use of a half-wave rectifier determines the significant dimensions of the known timer design.

The technical problem solved by the invention is to reduce energy consumption by reducing its losses during the operation of the timer, increasing the degree of versatility of the timer, as well as minimizing the size and increasing the degree of maneuverability in relation to the dimensions of the timer.

The problem is solved in that in the defrost timer on half-wave rectifiers containing a power source, a time counter, a heater, a defrost end sensor, a compressor, the first and second half-wave rectifiers, the first and second quenching elements, a three-pin relay, a moving contact of which is connected to the second pole power source; the common output of the time counter is connected to the first fixed contact of the relay and through the compressor is connected to the first pole of the power source; the counting input of the time counter through the heater is connected to the second fixed contact of the relay and through the end defrost sensor 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 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; the counter output is connected to the second pole of the power source also 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 (third circuit) - by the second rectifier and the second blanking element.

When solving the task of minimizing the dimensions of the timer, there was a problem - using two half-wave rectifiers, instead of one half-wave, create a workable timer, the design of which is minimized and has a high degree of maneuverability in size.

This feature is provided by the proposed timer design.

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

When the mains voltage is applied, the moving contact of the relay is closed to the first fixed contact.

From the second pole of the power source, the current through the normally closed first fixed relay contact, time counter and defrost end sensor of the refrigerator, the contacts of which are closed after a cold set, goes to the first pole of the power source, ensuring the operation of the time counter, which starts to count the compressor operating time proportional the number of fluctuations in the supply network (or internal clock). At the same time, along the circuit: the second pole of the power supply, normally closed contacts in position “a”, a time counter (after counting the set compressor operation time and applying voltage from the counter to the first contact of the relay winding), connected in series: relay winding, threshold element, first rectifier, first blanking element; the heater, the contacts of the defrost end sensor closed after a set of cold, the first pole of the power source, current begins to flow; The process of establishing the output voltage of the first rectifier is in progress. At the same time, the current from the second pole of the power source through the second rectifier flows to the first rectifier, while maintaining the current at the output of the first rectifier.

When reaching the voltage at the output of the first rectifier, sufficient for reliable operation of the electromagnetic relay, the threshold element opens and supplies the supply voltage to the second contact of the coil of the electromagnetic relay. 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 switching the relay contacts from the first fixed contact to the second, the heating element is turned on, the defrost of the refrigerator begins. At the same time, voltage is supplied to the second rectifier through the circuit: the second pole of the power supply, the second blanking element, the second rectifier, open threshold element, relay coil, time counter, inactive compressor, the first pole of the power source. During the defrost period of the refrigerator, the first rectifier does not work, current does not flow through it.

When the defrost occurs, when the set temperature is reached, the contacts of the defrost end sensor open. The current from the second pole of the power source through the relay contact, closed to the second fixed contact, the idle heater, time counter, idle compressor enters the first pole of the power source. The time counter counts the pause time after the defrost.

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 winding and the contacts switch to the first stationary contact, the cycle repeats.

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

In this case, it does not matter in which sequence, relative to the fixed contacts of the relay and circuit, from the series-connected relay windings and the threshold element, rectifiers and damping elements are connected. With any arrangement of the corresponding quenching elements and rectifiers relative to the stationary contacts of the relay and circuit from the relay coil and threshold element connected in series, the current will always flow through the first or second quenching elements during the corresponding periods of the timer operation. In any period of the timer and in any half-period of the supply voltage, either the first or second damping elements will fulfill their function of extinguishing excessive voltage.

When using half-wave rectifiers, we were able to vary the relative positions of the rectifier and the damping element. This is important from the point of view of constructive execution of the timer under severe restrictions in the volume of the device. The possibility of such a maneuver makes it possible to achieve a denser layout of the timer circuit, especially considering that the quenching elements (especially if resistors play their role) must be spaced relative to each other in terms of compliance with safety requirements.

Thus, the use of two half-wave rectifiers in the timer circuit instead of one half-wave rectifier will provide the possibility of varying the location of the circuit elements relative to each other, which will, to a large extent, subject to all safety requirements, more densely position the elements relative to each other, thereby providing additional opportunities to reduce the dimensions of the timer .

The introduction of the second rectifier did not lead to an increase in the dimensions of the timer compared to the prototype, because the dimensions of the rectifiers are much smaller than the dimensions of the quenching elements, as well as the dimensions of the half-wave rectifiers are smaller than the dimensions of the half-wave.

Due to the absence of circuit elements (in this case, quenching elements) connected in parallel to the rectifiers, when the latter is powered, there are no unproductive energy losses.

In the proposed timer circuit, the main function of the quenching elements is to ensure the accumulation of energy at the output of the rectifiers, sufficient for the relay to operate, and to keep the three-pin relay in the activated state.

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 quenching elements is determined only by the necessary response time of the three-contact relay and depends on what value it will ensure that the relay is maintained in the tripped 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, a reduction in energy losses during the operation of the timer, as well as an increase in its versatility due to the fact that the choice of circuit elements (first and second extinguishing elements) is determined only by their functions and is not dependent on 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 proposed timer design is intended for use in types of refrigeration devices, the electrical circuit of which provides for connecting the common output of the time counter to the fixed contact of the electromagnetic relay, for example, in STINOL freezers - 106, 112.

From the prior art there are no timer designs characterized by the claimed combination of features, therefore, the present invention meets the patentability criterion - “novelty”.

The claimed combination of features of the invention, which ensures the achievement of the technical task, 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 second fixed contact of the relay 2 and through the sensor 10 of the end of the defrost is connected to the first pole 12 of the power source. The common output of the time counter 1 is connected through a normally closed contact "a" of the switching contacts 8 of the electromagnetic relay 2 with the second pole 13 of the power source and through the compressor 11 with the first pole 12 of the power source. The output of the counter 1 is connected to the second fixed contact of the relay “b” through connected in series: relay coil 2, threshold element 3, rectifier 4 and resistor 6. In addition, the output of the counter 1 is connected to the second pole of the power source through connected in series: relay coil 2, threshold element 3, the second rectifier 5 and resistor 7. Rectifiers 4 and 5 are designed to power the relay coil 2; resistors 6 and 7 act as quenching elements. Rectifiers 4 and 5 are made full-wave and provide current flow: rectifier 4 - from the second pole 13 of the power source, time counter 1, relay coil 2, threshold element 3, rectifier 4, resistor 6, heater 9, sensor 10 to the first pole 12 of the power source ; rectifier 5 - from the second pole 13 of the power source, resistor 7, rectifier 5, threshold element 3, relay coil 2, time counter 1, compressor 11, first pole 12 of the power source.

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 the relay 2 is in the normally closed state "a" of the switching contacts 8.

From the second pole 13 of the power source, the current through the normally-closed contact "a", counter 1 and the sensor 10 of the end of the defrost of the refrigerator, the contacts of which are closed after a cold set, goes to the first pole 12 of the power source, ensuring the operation of the counter 1, which starts to count the operating time compressor 11, proportional to the number of oscillations of the supply network (or internal clock). At the same time, the process of establishing the output voltage of the rectifier 4 is in progress.

Upon reaching a voltage sufficient for reliable operation of the electromagnetic relay 2, the threshold element 3 opens and supplies the supply voltage to the second terminal of the coil of the electromagnetic relay 2.

When switching contacts 8 from position “a” to position “b”, the heating element 9 is turned on, defrosting of the refrigerator begins. At the same time, voltage is supplied to the rectifier 5.

When the defrost has occurred, when the set temperature is reached, the contacts of the sensor 10 open. The current from the second pole 13 of the power source through the relay contact, closed in position “b”, idle heater 9, counter 1, idle compressor 11 is supplied to the first pole 12 of the power source. Counter 1 counts the pause time after the defrost.

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

Claims (1)

Defrost timer on half-wave rectifiers, containing a power source, time counter, heater, defrost end sensor, compressor, first and second half-wave rectifiers, first and second blanking elements, three-pin 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 first fixed contact of the relay and through the compressor is connected to the first 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 output of the time counter is connected to the second fixed relay contact via 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; the counter output is connected to the second pole of the power source also 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 (third circuit) - by the second rectifier and the second blanking element.