KR101884350B1 - Controller for Solenoid valve - Google Patents

Abstract

The present invention relates to a control valve control apparatus. The present invention provides a refrigerator comprising: a capacitor charged when an external power source is supplied to a refrigerator and discharged when an external power source is not supplied; The refrigerator according to any one of claims 1 to 3, wherein when the external power is supplied to the refrigerator, a power is outputted in a first direction, and when the external power is not supplied to the refrigerator A power direction switching circuit for outputting power; And a solenoid valve which is supplied with power from the power source direction switching circuit and locks if the direction of the power source is the first direction and opens when the power source is in the second direction, And a solenoid coil for driving the moving core unit. The solenoid coil unit includes a solenoid coil, an outflow port, a moving core unit for opening and closing the outlet, and a solenoid coil for driving the moving core unit.

Description

[0001] The present invention relates to a controller for a solenoid valve,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control apparatus for a solenoid valve for operating a system for preventing a power failure.

Generally, a refrigerator utilizes a working fluid that changes phase by temperature in order to refrigerate or store foods, etc., and absorbs the heat inside the refrigerator into the refrigerator when the working fluid is vaporized to cool the inside of the refrigerator. It is a device which repeatedly performs the operation of radiating one heat.

A typical structure used in a refrigerator is a refrigeration cycle consisting of a compressor, a condenser, an inflator and an evaporator. A compressor is disposed in a rear lower region of the main body, and an evaporator for heat exchange with air in the freezing chamber is disposed on a rear wall of the freezing chamber.

The operation of such a refrigerator is not a problem because cold air is continuously supplied to maintain the internal temperature when the power is normally supplied and the compressor operates normally, but there is a problem in the cooling cycle such as a power failure or a failure of the compressor, The temperature inside the refrigerator rises.

In particular, there is a problem that the temperature of the refrigerating chamber, which is prone to deterioration of the food, rises easily, and the food is broken, and a technique for preventing the temperature of the refrigerating compartment from being lowered in preparation for a power failure is required.

The present invention provides a solenoid-operated valve control apparatus that opens a flow path so that a fluid can move in a solenoid valve when a power failure occurs, and closes the flow path without moving the fluid when the refrigerator normally operates.

The present invention provides a refrigerator comprising: a capacitor charged when an external power source is supplied to a refrigerator and discharged when an external power source is not supplied; The refrigerator according to any one of claims 1 to 3, wherein when the external power is supplied to the refrigerator, a power is outputted in a first direction, and when the external power is not supplied to the refrigerator A power direction switching circuit for outputting power; And a solenoid valve which is supplied with power from the power source direction switching circuit and locks if the direction of the power source is the first direction and opens when the power source is in the second direction, And a solenoid coil for driving the moving core unit. The solenoid coil unit includes a solenoid coil, an outflow port, a moving core unit for opening and closing the outlet, and a solenoid coil for driving the moving core unit.

The electromagnetic valve control device of the present invention can operate the solenoid valve to be opened to preserve the fridge freezer in the mechanical refrigerator without the micom even during the power failure so that the food stored in the fridge can be prevented from being deteriorated.

In addition, the present invention can operate the solenoid valve to be opened for saving cold air in the refrigerator room even in the refrigerator equipped with the micom, so that the food stored in the refrigerating chamber can be prevented from being deteriorated.

In addition, since the power supply is not continuously supplied in order to maintain the locked or open state of the valve, power consumption is low and the valve is not overheated.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 shows a refrigerator cycle and a heat siphon.
2 is a view showing a solenoid-operated valve control apparatus according to an embodiment of the present invention;
Figures 3 and 4 show the solenoid valve of the present invention.
5 to 7 are diagrams showing an operating state of a control apparatus for a solenoid valve according to an embodiment of the present invention.
8 and 9 are diagrams showing a control method of a solenoid valve according to an embodiment of the present invention.
10 is a view showing a solenoid-operated valve control apparatus according to another embodiment of the present invention.
11 to 13 are diagrams showing an operating state of a control apparatus for a solenoid valve according to another embodiment of the present invention.
14 is a view showing a control method of a solenoid valve according to another embodiment of the present invention.

Hereinafter, the control device and control method of the electromagnetic valve 130 will be described in detail with reference to the drawings. The same reference numerals denote the same components, and duplicate descriptions are omitted.

1 is a conceptual view showing a refrigerator cooling cycle 15 and a heat siphon 20. FIG. 1 shows a refrigerator body 10 and a refrigeration cycle 15 and a heat siphon 20 for cooling the refrigerator.

The refrigerator body 10 is divided into a freezing chamber 11 and a refrigerating chamber 12 with a partition 13 therebetween and a cooling cycle 15 for cooling the inside of the refrigerator body 10.

The cooling cycle 15 artificially compresses the refrigerant using the compressor 17 and changes the liquid state from the condenser 18. The refrigerant changed into the liquid state is subjected to heat exchange in the expansion device (19) and the evaporator (16) through the expansion and decompression to the gaseous state, and as a result, the ambient temperature is lowered.

The evaporator 16 of the cooling cycle 15 is installed in the freezing chamber 11 to cool the freezing chamber 11 and maintain the temperature of the refrigerating chamber 12 with the freezing air. In order to cool the inside of the refrigerator body 10 continuously, the compressor 17 must be operated so that the cooling cycle 15 is continuously operated. Therefore, during a power failure, the operation of the compressor 17 is stopped, So that the temperature of the heat exchanger is increased.

The freezing chamber 11 is provided with a material for storing cool air such as phase change material in a state where the power supply is interrupted and the cooling cycle 15 is not operated so that the temperature can be prevented from rising by using the cool air stored in advance .

However, since the temperature of the refrigerating chamber 12 is relatively higher than that of the freezing chamber 11, it is difficult to use the phase-change material. A heat siphon 20 may be used to minimize the temperature drop of the refrigerating chamber 12 by using the cold air of the freezing chamber 11. [

A thermosiphon (20) is a refrigerant that absorbs and discharges heat by changing its phase depending on the temperature. The refrigerant that absorbs cold air by gravity moves downward and changes to a gaseous state. . That is, the heat siphon is a device that transfers heat without using any additional electrical energy using the phase change principle of the refrigerant.

1, a part of the heat siphon 20 is located in the refrigerating chamber 12 and a part of the refrigerant is circulated between the freezing chamber 11 and the refrigerating chamber 12, To exchange heat. The heat siphon 20 includes a condenser 21, an evaporator 22, a first connecting pipe 24, and a second connecting pipe 23.

The condenser 21 is located in the freezing chamber 11, and the refrigerant is liquefied to absorb cold air. The evaporator (22) is located in the refrigerating chamber (12) and connects the outlet of the evaporator and the inlet of the evaporator to which the refrigerant vaporizes.

The first connection pipe 24 guides the refrigerant from the evaporator 22 to the condenser 21 and the second connection pipe 23 connects the outlet of the condenser and the inlet of the evaporator So that the refrigerant is guided from the condensing part (21) to the evaporating part (22).

When the refrigerator is normally operated, the heat siphon 20 is located in the freezer compartment without releasing the refrigerant, so the heat siphon 20 is required to store heat and cool air. Therefore, the heat siphon 20 is provided with the valve 29 in the circulation structure of the heat siphon, Prevents circulation of refrigerant. The valve 29 can prevent the circulation of the refrigerant even where it is located in the thermal siphon 20. However, in order to allow the refrigerant to remain liquefied in the freezing chamber, it is preferable that the refrigerant is located in the second connection pipe 23 as shown in FIG.

The valve 29 may be mechanically operated using a bimetal or the like, but an electronically operated solenoid valve 130 is preferably used for the reliability of the refrigerator. The electromagnetic valve 130 will be described in detail below with reference to the drawings. The solenoid valve 130 has a structure in which an on-off operation for controlling the flow rate is performed electronically, and the moving core portion in the solenoid coil is located. When a current is applied to the coil, a magnetic field is formed and the moving core moves by the magnetic field to open and close the electromagnetic valve 130 to control the flow rate.

The opening and closing of the solenoid valve 130 can be performed by supplying power. Therefore, the closing operation is possible when the power is supplied, but the operation to open when the power supply is interrupted as in the case of power failure is a problem. The solenoid valve 130 must be opened so that the refrigerant in the heat siphon 20 is circulated in order to maintain the temperature of the refrigerating chamber 12 during a power failure. The present invention provides a control device and a control method capable of supplying power to the solenoid valve (130) even during a power failure.

2 is a circuit diagram of a control device of a solenoid valve 130 according to the present invention and includes a capacitor 110, a power source direction switching circuit 120, a solenoid valve 130, a time delay circuit 140, Circuit 150 is disclosed.

Capacitor 110 is a device for collecting an electric field in a space between two conductive plates. Two conductor plates and an insulator are interposed therebetween, and the charge is reserved at the boundary between the surface of each plate and the insulator. The larger the capacity of the capacitor 110, the more charge can be stored. The capacity of the capacitor 110 is proportional to the size of the plate and inversely proportional to the distance.

The capacitor 110 of the present invention plays a role of reserving the charge when the external power is normally input and discharging the charge reserved when the external power is input to supply the necessary power. It is difficult for the capacitor 110 to reserve enough energy to operate the entire refrigerator. As the capacity of the capacitor 110 increases, the cost of the capacitor 110 increases and the total cost increases. Therefore, it is preferable to use a capacity capable of supplying the minimum energy.

At this time, since DC power must be supplied to the capacitor 110, it is necessary to rectify the AC power when the external power source is AC. A rectifier is a device configured to allow current to flow in only one direction using a diode, and is a device or device that converts alternating current that changes in positive and negative into direct current having only one direction. The rectifier 160 is not limited to the shape shown in the drawing, but can be configured in various shapes that function to convert AC to DC power.

3 and 4) in the solenoid coil 136 (see FIGS. 3 and 4), and the solenoid coil 136 A magnetic field is formed and the moving core portion 137 moves by the magnetic field to open and close the electromagnetic valve 130 to control the flow rate.

The solenoid valve 130 may be a two-way valve that simply opens and closes a flow path in one direction, but a three-way valve may be used to control fluid flow in various directions.

As described above, the solenoid valve 130 can be operated only when power is applied. In general, when the power is inputted, if the power is not applied, if the power is not applied while maintaining the open or closed state, Or open state. Since the solenoid valve 130 must be continuously supplied with power in order to maintain a specific state, it is suitable for a device having a relatively long time when the power is not applied.

For example, if the valve is open only for a short time, a valve requiring a power supply is used to maintain the open state. On the contrary, if the valve is open normally and then closed for a short time, a valve requiring power supply for closing can be used .

In the present invention, since the thermal siphon 20 is used only during a power failure, the solenoid valve 130 normally closes the flow path and opens the flow path only during a power failure. However, if the solenoid valve 130 is continuously supplied with power to maintain the normally closed state, there is a problem that unnecessary energy consumption is increased.

Accordingly, in the present invention, if the power is applied only at the moment when the open / close state is changed and the power is not applied, the latch valve that maintains the state by the permanent magnet can be used as the solenoid valve 130. 3 and 4 illustrate a latch valve type solenoid valve 130. Since the solenoid valve 130 uses less power and does not need to be continuously powered, the problem of overheating the solenoid valve 130 can be solved do.

3 is a view showing a solenoid valve of the present invention. This will be described below with reference to Fig. 3, the electromagnetic valve 130 shows a state in which the flow path is opened so that the fluid can move. That is, a state in which a thermal siphon can be driven when a power failure occurs.

The solenoid valve 130 is disposed in the vicinity of the fluid inlet 133, the fluid outlet 134, the solenoid coil 136, the power input portions 131 and 132, the moving core portion 137, and the moving core portion 137 And a permanent magnet 135 disposed therein.

On the other hand, the entire body of the electromagnetic valve 130 is preferably made of a ferromagnetic material.

In particular, the electromagnetic valve 130 may further include an injection tube 230 capable of injecting fluid from the outside. At this time, the injection tube 230 may perform a function of initially injecting the fluid into the thermal siphon for driving the thermal siphon.

The inlet 133 and the inlet 230 are formed on the same side of the electromagnetic valve 130 and the outlet 134 is formed on the other side of the electromagnetic valve 130 desirable.

In order for heat siphon to occur, the fluid must be circulated internally, and the circulating fluid should not leak to the outside. Therefore, it is not preferable to form the inlet for injecting the fluid into the first connection pipe 24, the second connection pipe 23, the condenser 21 and the evaporator 22 in the structure in which the heat siphon is circulated.

To this end, the injection valve 230 is provided at one side of the solenoid valve 130, which is separate from the inlet 133 and the outlet 134. Meanwhile, the injection tube 230 may be sealed after initially injecting a sufficient amount of fluid for thermal siphon.

Alternatively, the injection tube 230 may be communicated with the second connection pipe 23 or the condenser 21. At this time, the portion where the injection tube 230 is connected is located on the upper side of the second connection pipe 23, and the condensing portion 21 is in a state where the electromagnetic valve 130 closes the flow path, So that cold air can be accumulated in the air.

The moving core portion 137 includes a case 137a made of a ferromagnetic material. The case 137a can selectively open and close the flow path of the electromagnetic valve 130 while moving on the space formed inside the electromagnetic valve 130. [

In addition, a first through hole 137b and a second through hole 137c may be formed at both ends of the case 137a. At this time, a first protruding piece 137c is movably installed in the first through hole 137b, and a second protruding piece 137d is movably installed in the second through hole 137c. At this time, the first protruding piece 137c and the second protruding piece 137d may be arranged to face each other.

At this time, the first projecting piece 137c can seal the injection tube 230, and the second projecting piece 137d can seal the outflow opening 134. [

The first projecting piece 137c and the second projecting piece 137d may have a tapered shape at one end in an angular shape. The angular portions are inserted into the injection tube 230 and the outlet 134, respectively, so that the flow path can be sealed.

The first projecting piece 137c and the second projecting piece 137d may be made of a deformable material such as rubber or silicone. So that the flow control by the solenoid valve 130 can be stably performed even if wear is caused by long use.

The case 137a is provided with an elastic member 137e for elastically supporting the first projecting piece 137c and the second projecting piece 137d at both ends of the case 137a. At this time, the elastic member 137e may be formed of a coil spring.

Since one end of the elastic member 137e is fixed to the first projecting piece 137c and the other end is fixed to the second projecting piece 137d and elastically supported, the first projecting piece 137c, The flow path can be stably controlled even if abrasion occurs on the two projecting pieces 137d.

The first through hole 137b and the second through hole 137c have a tapered shape to guide a path through which the first projecting piece 137c and the second projecting piece 137d can move . At this time, the tapered shape of the first through hole 137b has a shape narrowing toward the upper side, and the tapered shape of the second through hole 137c has a shape of narrowing the hole toward the lower side Do.

In case of a power failure, the fluid introduced through the inlet 133 can be moved downward through the outlet 134. At this time, the inlet 133 is connected to the freezing chamber, and the outlet 134 is connected to the refrigerating chamber, so that thermal siphoning can be performed.

When electric power is supplied to the solenoid coil 136, a magnetic field is formed and the direction of the magnetic field changes according to the direction of the power supplied to the solenoid coil 136. The magnetic force generated by the solenoid coil 136 is stronger than the magnetic force generated by the permanent magnet, and the moving core portion 137 is moved.

The moving core portion 137 is made of a ferromagnetic material and is magnetized by a magnetic field around the moving core portion 137. 3, positive (+) is applied to the first power input part 131 and negative (-) is applied to the second power input part 132, the moving core 137 receives force upward from below, Move. The moving core 137 moved upward moves the fluid outlet 134 to discharge the fluid introduced into the fluid inlet 133 to the fluid outlet 134. That is, the open state.

The permanent magnet 135 is characterized in that the inner side 135a and the outer side 136b have different polarities. Even if the power source is shut off, the moving core (137) 137 are kept open.

At this time, as the moving core portion 137 moves upward, the first projecting piece 137c closes the injection tube 230. Of course, if the fluid is sealed in the infusion tube 230 after the initial infusion, the first protrusion piece 137c may enhance the sealing of the infusion tube 230. [

On the other hand, if the injection tube 230 is connected to the upper side of the second connection pipe 23 or to the condenser 21, the injection tube 230 is closed .

FIG. 4 shows a state in which the solenoid valve 130 is opened. When a power source opposite to that of FIG. 3 is applied to the power input units 131 and 132, a magnetic field in the direction opposite to that of FIG. 3 is formed, The core 137 moves downward to close the outlet 134. [

That is, Fig. 4 shows a state in which power is normally supplied to the refrigerator, so that driving by the thermal siphon is not required.

The electromagnetic valve 130 is locked and the moving core portion 137 is magnetized in the direction opposite to that of FIG. 3 to be closed by the permanent magnet 135 even when power is not applied to the solenoid coil 136 State is maintained.

At this time, when the injection tube 230 is initially closed after the fluid is injected, the fluid is stopped.

On the other hand, if the injection pipe 230 is connected to the second connection pipe 23 or the condenser 21, the fluid can be moved through the injection pipe 230. In this case, however, since the fluid does not circulate the entire system of the thermal siphon, cold accumulation occurs in the condenser 21.

As described above, the solenoid valve 130 of the present invention is opened or closed depending on the direction in which power is input. The solenoid valve 130 is closed when negative (-) is input to the first power input unit 131 and positive (+) is input to the second power input unit 132 as shown in FIG. 5, The solenoid valve 130 is opened when positive (+) is input to the first power input unit 131 and negative (-) is input to the second power input unit 132 as shown in FIG. 6 shows a state in which the power is not applied after the solenoid valve 130 is closed, and the solenoid valve 130 remains closed.

In order to open and close the solenoid valve 130, it is necessary to change the direction of the power input to the first power input unit 131 and the second power input unit 132. The power direction switching circuit 120 is disposed between the external power supply unit 100 and the solenoid valve 130 to change the direction of power supplied to the solenoid valve 130.

The power source direction switching circuit 120 receives external power supplied to the refrigerator or power source discharged from the capacitor 110 and outputs the power in a first direction or a second direction. A signal is input for output in the first direction or the second direction, and the direction of the current changes as the connection state changes according to the signal.

As the power direction switching circuit 120, a relay for controlling the current flow by changing the connection state of the circuit by using an electromagnet can be used. 2, a pair of terminals 121 and 122 connected to the external power supply or the capacitor 110, a pair of terminals 123 and 124 connected to the solenoid valve 130, And an input unit 125.

The power direction switching circuit 120 switches the direction of the power source to be output in the first direction or the second direction depending on whether a signal is input to the signal input unit 125. [

The power direction switching circuit 120 shown in FIGS. 5 to 7 illustrates an embodiment of the present invention. (-) is applied to the third terminal 123 and the negative terminal is connected to the fourth terminal 124 ((-)), the first terminal 121 is positive and the second terminal 121 is negative. (+) Is output to the third terminal 123, and (-) is output to the fourth terminal 124. In this case,

The first direction and the second direction may be reversely determined depending on the connection state with the solenoid valve (130).

In the power direction switching circuit 120 of the present invention, when a signal is input to the signal input unit 125, a current flows in a first direction and a current flows in a second direction if no signal is input. 5 shows a power source direction switching circuit 120 in a state in which a current flows in a first direction, and Fig. 7 shows a power source direction switching circuit 120 in a state in which a current flows in a second direction.

5 shows an operation state at the moment when external power is not supplied but external power is supplied. First, when an external power source is supplied to the refrigerator, external power is input through the first terminal 121 and the second terminal 122. At this time, if the external power source is AC, rectifier 160 rectifies the input power to DC.

The signal input unit 125 moves the switches 126 and 127 according to a signal input. The signal input unit 125 of the present invention includes a coil and a signal is input when power is applied to the signal input unit 125. When a signal is input to the signal input unit 125, a magnetic field is generated with a current flowing through the coil, and the switches 126 and 127 move.

The signal input unit 125 is connected to an external power source and recognizes the external power source as a signal. That is, when an external power source is supplied to the refrigerator, power is applied to the signal input unit 125 and a current flows through the coil of the signal input unit 125, thereby changing the connection state of the switch as shown in FIG. The first terminal 121a and the fourth terminal 124 are connected and the second terminal 122a and the third terminal 123 are connected.

Accordingly, when the external power is supplied, the power source inputted to the power direction switching circuit 120 is the first terminal 121, the second terminal 122, and the signal input unit 125, The third terminal 123 is negative, and the fourth terminal 124 is positive. That is, the current flows in the first direction. The first power input unit 131 of the electromagnetic valve 130 becomes (+) and the second power input unit 132 becomes (-).

7 is a diagram showing an operation state of the control device of the electromagnetic valve 130 when external power is not supplied, that is, when a power failure occurs. Since the external power is not supplied, the charge stored in the capacitor 110 is discharged and supplied to the power direction switching circuit 120.

 The signal input unit 125 connected to the external power supply unit 100 is not supplied with the external power. Accordingly, the first terminal 121b and the third terminal 123 are connected to each other and the second terminal 122b and the fourth terminal are connected to each other, as shown in FIG.

The direction of the power source input to the power direction switching circuit 120 by the capacitor 110 is such that the first terminal 121 is positive and the second terminal 122 is negative, (+) And the fourth terminal 124 is (-). The direction of the power source applied to the solenoid valve 130 is the second direction as opposed to the case of FIG. Accordingly, the first power input part 131 of the solenoid valve 130 becomes (+) and the second power input part 132 becomes (-).

When the power is continuously supplied to the solenoid valve 130, the solenoid valve 130 generates heat. Therefore, when the solenoid valve 130 is opened or closed, it is necessary to shut off the power supply . By shutting off the power supply, the electromagnetic valve 130 can be prevented from overheating and power consumption can be prevented.

Therefore, the solenoid valve 130 may further include a power applying unit for controlling whether or not the power is applied. The power applying apparatus includes a power cutoff circuit 150 and a time delay circuit 140.

The power supply cut-off circuit 150 cuts off the power supplied to the solenoid valve 150 by disconnecting the power supply line from the solenoid valve 150. The power direction switching circuit 120 may be located anywhere between the external power supply 100 and the solenoid valve 130 and may be located anywhere between the external power supply 100 and the power direction switching circuit 120, And may be interposed between the power source direction switching circuit 120 and the solenoid valve 130 as shown in FIG.

Hereinafter, the power-off circuit 150 is interposed between the power direction switching circuit 120 and the solenoid valve 130 for convenience of explanation, but the present invention is not limited thereto.

The power direction switching circuit 120 and the solenoid valve 130 may be connected or disconnected. The connection or disconnection of the power direction switching circuit 120 is determined depending on whether a signal is input to the signal input unit 153.

If no signal is input to the signal input unit 153, the switch 154 disconnects the connection between the first terminal 151 and the second terminal 152, thereby switching the power direction switching circuit 120 and the solenoid valve 130 , And the state of this power-off circuit 150 is shown in FIG.

When a signal is input to the signal input unit 153, the switch connects the first terminal 151 and the second terminal 152 to connect the power direction switching circuit 120 and the solenoid valve 130 The state of this power-off circuit 150 is shown in Fig.

The signal input to the signal input unit 153 is a power supply delayed from the time delay circuit 140 for a predetermined time. The time delay circuit 140 outputs the external power supplied to the refrigerator with a time delay. The delay time can be set in a range of 0.1 second to 5 seconds with a time sufficient to complete the opening and closing of the electromagnetic valve 130. [

5, a signal is not inputted to the signal input part 153 of the power supply cut-off circuit 150 by the time delay circuit 140 when the external power supply is started, so that the power supply cut-off circuit 150 Connects between the power source direction switching circuit 120 and the solenoid valve 130.

However, after a predetermined time has elapsed, power is also output from the time delay circuit 140 and a signal is input to the signal input section 153 of the power cutoff circuit 150. Therefore, as shown in FIG. 6, the switch of the power-off circuit 150 is opened and the connection between the power direction switching circuit 120 and the solenoid valve 130 is disconnected. Therefore, power is not applied to the solenoid valve 130 after the elapse of a predetermined time after the solenoid valve 130 is locked, thereby preventing heat from being generated.

6, when the external power is not supplied, the time delay circuit 140 can no longer apply a signal to the signal input unit 153 of the power cutoff circuit 150, The switch 154 is closed. The power source direction switching circuit 120 and the solenoid valve 130 are connected and power is supplied to the solenoid valve 130 so that the solenoid valve 130 is opened.

Next, a control method of the solenoid valve 130 according to another aspect of the present invention will be described with reference to FIGS. 5 to 7 along the flowcharts of FIGS. 8 and 9. FIG.

FIG. 8 is a flowchart illustrating a method of controlling the solenoid valve 130 of the present invention when an external power is supplied, and FIG. 9 is a flowchart illustrating a method of controlling the solenoid valve 130 of the present invention when external power is not supplied.

First, it is examined how the electromagnetic valve 130 is controlled when external power is supplied. When external power is supplied (S10), the capacitor 110 is charged (S15) and external power is applied to the power direction switching circuit 120 (S20). A signal is inputted to the signal input part 125 of the power source direction switching circuit 120 so that the power source direction switching circuit 120 switches between the first terminal 121a and the fourth terminal 124 And the second terminal 122a and the third terminal 123 are connected to each other. Thus, the third terminal 123 has the same potential as the second terminal 122a, and the fourth terminal 124 has the same potential as the first terminal 121a.

(-) is input to the first power input unit 131 and (+) is input to the second power input unit 132, so that the power valve is locked (S25).

When external power is supplied, power is also supplied to the time delay circuit 140, and the time delay circuit 140 outputs the power after a predetermined time elapses. When the external power is continuously supplied, there is no difference from the normal general circuit. However, when the external power is supplied, the power is supplied for a predetermined time delay as compared with the case where the external power is directly connected. The delay time can be set in a range of 0.1 second to 5 seconds with a time sufficient to complete the opening and closing of the electromagnetic valve 130. [

The signal input unit 153 of the power cutoff circuit 150 is connected to the time delay circuit 140 and a signal is input to the power cutoff circuit 150 after a predetermined time elapses.

5 shows a state in which power is not applied to the signal input unit 153 of the power cutoff circuit 150 immediately after the external power is input. When the power is not applied to the signal input unit 153, the first terminal 151 and the second terminal 152 of the power cutoff circuit 150 are connected.

6 shows a state in which a predetermined time has elapsed after an external power source has been inputted. The external power source passes the time delay circuit 140 and is applied to the signal input unit 153 of the power cutoff circuit 150 (S30 ). The switch 154 of the power supply cut-off circuit 150 is opened to disconnect the connection between the first terminal 151 and the second terminal 152.

That is, when the predetermined time has elapsed, the connection between the power source direction switching circuit 120 and the solenoid valve 130 is cut off as shown in FIG. 6, and the power supply to the solenoid valve 130 is stopped (S35). When the power supply to the solenoid valve 130 is stopped, the locked / unlocked state is fixed, so that the locked state of the solenoid valve 130 is maintained (S37).

Next, referring to FIG. 9, a method of controlling the electromagnetic valve 130 when external power is not supplied in a situation such as a power failure will be described. When the supply of external power is interrupted (S60), there is no power supplied to the capacitor 110, and the charged charge is discharged (S65). The direction of the power supplied to the first terminal 121 and the second terminal 122 of the power source direction switching circuit 120 is changed when the external power source is inputted The first terminal 121 becomes the (+) second terminal 122 and the negative terminal 122 becomes (-).

However, since the capacity of the capacitor 110 is limited, only the energy required to open the solenoid valve 130 is supplied, and when the charged charge is discharged, no further power is supplied.

When the supply of the external power is interrupted, no signal is inputted to the signal input unit 125 of the power direction switching circuit 120 (S70). 6, the switch of the power direction switching circuit 120 is connected to the first terminal 121b and the third terminal 123 and the second terminal 1222b and the fourth terminal 124 are connected to each other .

The power supply cut-off circuit 150 does not receive a signal from the signal input unit 153 when the external power supply is interrupted. However, since the signal is delayed for a predetermined time from the time delay circuit 140, the switch of the power shutoff circuit 150 may be changed as shown in FIG. 6 to FIG. 7 after a predetermined time has elapsed. The electromagnetic valve 130 should not be opened immediately after a power failure, and even if a predetermined time delay occurs, the temperature inside the refrigerator is not significantly affected by a power failure.

That is, when a signal is inputted to the power-off circuit 150 after a predetermined time elapses after a signal is inputted to the power-source direction switching circuit 120, a power source turned by the power direction switching circuit 120 is supplied to the solenoid- (130). In this case, the direction of the power applied to the solenoid valve 130 is opposite to that of FIG. 5 by applying (+) to the first terminal 131 and (-) to the second terminal 132, Is opened (S80).

As described above, the capacity of the capacitor 110 is limited. When the charged charge is completely discharged, no power is supplied to the solenoid valve 130 in step S90, and the solenoid valve 130 is opened (S95). Since the power supplied from the capacitor 110 to the solenoid valve 130 is supplied after the delay time set by the time delay circuit 140, the power supplied to the solenoid valve 130 is longer than the time delayed by the time delay circuit 140 It is desirable. The capacity of the capacitor 110 used in the present invention can be determined in consideration of the discharge time of the capacitor 110. [

10 is a view showing an electromagnetic valve control apparatus according to another embodiment of the present invention. This will be described below with reference to Fig.

10 shows another embodiment of the solenoid valve 130 control device of the present invention and includes a capacitor 110, a power source direction switching circuit 120, a solenoid valve 130, a microcomputer 240, 150) is disclosed.

As described above, the solenoid valve 130 can be operated only when power is applied. In general, when the power is inputted, if the power is not applied, if the power is not applied while maintaining the open or closed state, Or open state. Since the solenoid valve 130 must be continuously supplied with power in order to maintain a specific state, it is suitable for a device having a relatively long time when the power is not applied.

When electric power is supplied to the solenoid coil 136, a magnetic field is formed and the direction of the magnetic field changes according to the direction of the power supplied to the solenoid coil 136. The magnetic force generated by the solenoid coil 136 is stronger than the magnetic force generated by the permanent magnet, and the moving core portion 137 is moved.

As described above, the solenoid valve 130 of the present invention is opened or closed depending on the direction in which power is input. The solenoid valve 130 is closed when negative (-) is input to the first power input unit 131 and positive (+) is input to the second power input unit 132 as shown in FIG. 11, The solenoid valve 130 is opened when positive (+) is input to the first power input unit 131 and negative (-) is input to the second power input unit 132 as shown in FIG. FIG. 12 shows a state in which no power is applied after the electromagnetic valve 130 is closed, and the electromagnetic valve 130 is kept closed.

In order to open and close the solenoid valve 130, it is necessary to change the direction of the power input to the first power input unit 131 and the second power input unit 132. The power direction switching circuit 120 is disposed between the external power supply unit 100 and the solenoid valve 130 to change the direction of power supplied to the solenoid valve 130.

The power source direction switching circuit 120 receives external power supplied to the refrigerator or power source discharged from the capacitor 110 and outputs the power in a first direction or a second direction. A signal is input for output in the first direction or the second direction, and the direction of the current changes as the connection state changes according to the signal.

As the power direction switching circuit 120, a relay for controlling the current flow by changing the connection state of the circuit by using an electromagnet can be used. 10, a pair of terminals 121 and 122 connected to the external power supply or the capacitor 110, a pair of terminals 123 and 124 connected to the solenoid valve 130, And an input unit 125.

The power direction switching circuit 120 is connected to the microcomputer 240 so that the direction of the power output from the power direction switching circuit 120 is changed according to the control of the microcomputer 240. The signal input unit 125 of the power direction switching circuit 120 is connected to the microcomputer 240 so that the microcomputer 240 inputs a signal to the signal input unit 125.

The power direction switching circuit 120 shown in Figs. 11 to 13 shows another embodiment of the present invention. (-) is applied to the third terminal 123 and the negative terminal is connected to the fourth terminal 124 ((-)), the first terminal 121 is positive and the second terminal 121 is negative. (+) Is output to the third terminal 123, and (-) is output to the fourth terminal 124. In this case,

The first direction and the second direction may be reversely determined depending on the connection state with the solenoid valve (130).

When a signal is input from the microcomputer 240 to the signal input unit 125, a current flows in a first direction and a current flows in a second direction if no signal is input.

Fig. 11 shows a power source direction switching circuit 120 in a state in which a current flows in the first direction. Fig. 13 shows a power source direction switching circuit 120 in a state in which current flows in the second direction.

11 shows an operating state at the moment when external power is not supplied but external power is supplied. First, when an external power source is supplied to the refrigerator, external power is input through the first terminal 121 and the second terminal 122. At this time, if the external power source is AC, rectifier 160 rectifies the input power to DC.

The signal input unit 125 receives a signal from the microcomputer 240. The microcomputer 240 monitors whether the external power is supplied from the external power supply unit 100. When the external power is supplied to the refrigerator, And inputs a signal to the signal input unit 125. When a signal is input to the signal input unit 125, the direction of the switches 126 and 127 of the power direction conversion circuit is changed.

As an example of the power source direction conversion circuit 120, a method may be used in which a switch coil adjacent to the switches 126 and 127 is provided and current is supplied to the switch coil to change the position of the switch have. When a signal is applied to the signal input part 125, a current flows through the switch coil to change the positions of the switches 126 and 127, thereby changing the connection state inside the power direction switching circuit 120.

In the present invention, when a signal is input to the signal input unit 125, current flows through the switch coil to connect the first terminal 121a and the fourth terminal 124 and the second terminal 122a and the third terminal 123 are connected to each other. Accordingly, when the external power is not supplied, the direction of the power supplied to the solenoid valve 130 is the first direction, and the solenoid valve 130 is locked.

On the contrary, the microcomputer 240 does not apply a signal to the signal input unit 125 unless the external power is supplied from the external power supply unit 100. 13, the first terminal 121b and the third terminal 123 are connected to each other and the switches 126 and 127 are connected to each other so that the second terminal 122b and the fourth terminal are connected to each other. 127 are changed. Therefore, when the external power is not supplied, the direction of the power supplied to the solenoid valve 130 is changed to the second direction so that the solenoid valve 130 is opened.

As described above, the microcomputer 240 is connected to the signal input unit 125 of the power direction switching circuit 120 to apply a signal to the signal input unit 125 when the external power is supplied, So that the position of the switches 126 and 127 is moved as shown in FIG. 11 to supply power to the solenoid valve 130 in the first direction.

On the other hand, when the external power is not supplied, the microcomputer 240 does not apply the signal to the signal input unit 125, and the switch coil is not powered, So as to supply power to the electromagnetic valve 130 in the second direction.

The power supply cut-off circuit 150 cuts off power supplied to the solenoid valve 130 by disconnecting the power supply line from the solenoid valve 130. The power direction switching circuit 120 may be located anywhere between the external power supply 100 and the solenoid valve 130 and may be located anywhere between the external power supply 100 and the power direction switching circuit 120, And may be interposed between the power direction switching circuit 120 and the electromagnetic valve 130 as shown in FIG.

Hereinafter, the power-off circuit 150 is interposed between the power direction switching circuit 120 and the solenoid valve 130 for convenience of explanation, but the present invention is not limited thereto.

The power direction switching circuit 120 and the solenoid valve 130 may be connected or disconnected. The connection or disconnection of the power direction switching circuit 120 is determined depending on whether or not a signal is input to the signal input unit 153.

If no signal is input to the signal input unit 153, the switch 154 disconnects the connection between the first terminal 151 and the second terminal 152, thereby switching the power direction switching circuit 120 and the solenoid valve 130 , And the state of this power cut-off circuit 150 is shown in Fig.

A switch coil used to change the position of the switch 154 in the power direction switching circuit 120 may be used. When a signal is applied to the signal input unit 153 from the microcomputer 240, a current is applied to the switch coil, and the switch is opened as shown in FIG.

On the contrary, if no signal is applied to the signal input unit 153, no current flows through the switch coil, so that the switch is closed as shown in FIGS. 11 and 13, and the electromagnetic valve 130 and the power direction switching circuit 120 ).

The microcomputer 240 maintains the open state or the closed state even when the electromagnetic valve 130 is changed to the open or closed state and does not supply power any more. Therefore, the microcomputer 240 applies a signal to the power cutoff circuit 150, So that no more power is supplied to the valve 130. When the power is turned off, the energy consumption can be reduced and the electromagnetic valve 130 can be prevented from being overheated.

When the external power is continuously supplied and the solenoid valve 130 is closed, the external power is supplied to the solenoid valve 130, which may cause the solenoid valve 130 to overheat. As a result, It is necessary to shut off the power supplied to the solenoid valve 130 by using the power supply cut-off circuit 150.

However, since the power supplied from the capacitor 110 is supplied to the solenoid valve 130, the capacity of the capacitor 110 is limited. Therefore, when a predetermined time elapses, the power is supplied to the solenoid valve 130 The switch 154 of the power supply cut-off circuit 150 does not cause a problem even if the switch 154 is closed as shown in FIG.

The power supply cut-off circuit 150 is also controlled by the microcomputer 240. The microcomputer 240 applies a signal to the power cutoff circuit 150 after the solenoid valve 130 is closed, Can be cut off.

That is, after the power supply from the external power supply unit 100 starts and the operation of the solenoid valve 130 is completed, a signal is applied to the signal input unit 153 and the power shutoff circuit 150 So that the power applied to the solenoid valve 130 can be cut off.

Next, a control method of the solenoid valve 130 according to another aspect of the present invention will be described with reference to FIGS. 11 to 13 along the flowchart of FIG. The microcomputer 240 controls the direction of the power source applied to the solenoid valve 130 and whether or not the power source is applied according to whether the external power source is supplied or not to determine the opening and closing of the solenoid valve.

First, it is determined whether external power is supplied (S110). Charging the external power supply to the capacitor (110) and supplying the external power supply to the electromagnetic valve (130) in a first direction to lock the electromagnetic valve (130) when it is determined that the external power supply is supplied 1 operation steps (S120 to S146).

If it is determined that the external power is not supplied, the capacitor 110 discharges and supplies power to be discharged from the capacitor 110 to the electromagnetic valve 130 in the second direction to open the electromagnetic valve 130 (S150 to S172).

That is, the first operation step relates to the control method of the solenoid valve 130 when the external power source is supplied, and the second operation step relates to the solenoid valve control method when the external power source is not supplied .

First, a first operation step when external power is supplied will be described. When the external power is supplied, the capacitor 110 is charged (S120), and it is determined whether the solenoid valve 130 is in the locked state. As described above, the solenoid valve 130 maintains the lock / unlock state as long as power is not applied in the opposite direction even if power is not supplied. Therefore, when the solenoid valve 130 is in the locked state, Not required.

The method of determining whether the solenoid valve 130 is in the locked state can determine whether the solenoid valve 130 is locked using a sensor that directly senses whether the solenoid valve 130 is locked or not.

Or 1 is input when performing the operation of opening the electromagnetic valve 130 using a variable and when the operation of closing the electromagnetic valve 130 is performed, the operation state of the electromagnetic valve 130 can be determined by inputting 0.

An example of a method of inputting 1 or 0 into the variable is as follows. When the predetermined time has elapsed after applying the operating power to the power direction switching circuit 120, the solenoid valve 130 determines that the operation of the solenoid valve 130 is completed in the locked state and inputs 1 to the variable. If the external power is not supplied in the second operation step and the operating power is not applied to the power direction switching circuit 120, 0 is input to the variable.

When the membrane external power is supplied in the electrostatic condition, the solenoid valve 130 is in an open state, so the solenoid valve 130 must be closed.

The operating power is applied to the power direction switching circuit 120 so that the switches 126 and 127 of the power direction switching circuit 120 are positioned as shown in FIG. 11 (S130). The operation power is supplied when the operation signal is applied to the signal input unit S125 by the microcomputer, and a signal applied from the microcomputer 240 may be an operation power source.

At this time, the microcomputer 240 does not input a signal to the power-off circuit 150 and turns it off (S132). 11, the electromagnetic valve 130 and the power direction switching circuit 120 are connected to supply power to the solenoid valve 130 when the power shutoff circuit 150 is in the OFF state.

When the power direction switching circuit 120 is in the ON state and the power shutoff circuit 150 is in the OFF state, the power is output in the first direction (S134) and the solenoid valve 130 is in the locked state (S136).

After the solenoid valve 130 is locked, the microcomputer 240 controls the power-off circuit 150 to be turned on by applying a signal to the power-off circuit 150 (S140) The switch 154 is opened to shut off the power applied to the solenoid valve 130 as shown in FIG. 12 (S142). After the solenoid valve 130 is locked, the solenoid valve 130 is maintained in a locked state even if no power is applied to the solenoid valve 130 (S144).

Since the power is not supplied to the solenoid valve 130 by the power cut-off circuit 150, the state of the power direction switching circuit 120 is influenced by the state of the solenoid valve 130 whether the solenoid valve 130 is in the OFF state or the ON state The power source switching circuit 120 is turned off by turning off the operating power applied to the solenoid valve 130 at step S146. The operating power supplied to the power direction switching circuit 120 is also cut off, thereby minimizing energy consumption.

If the solenoid valve 130 is in the locked state, the power supply to the solenoid valve 130 is interrupted until the external power supply is stopped (S142) and the locked state is maintained (S144). Accordingly, the power-off circuit 150 is kept in the ON state (S140) and the power direction switching circuit 120 is placed in the OFF state (S146).

Next, the second operation step when the power supply is interrupted will be described. An external power source for operating the solenoid valve 130 is not supplied. Therefore, the power source is used as a power source for discharging the capacitor 110 (S150) and supplying the discharged power to the solenoid valve 130.

When the power direction switching circuit 120 is turned off (S160) by not applying a signal to the power source direction switching circuit 120, the power direction switching circuit 120 is turned on in the second direction Power is output (S164). At this time, the power shutoff circuit 150 is also turned off (S162), and power flowing in the second direction may be applied to the solenoid valve 130.

The solenoid valve 130 is opened by a power source in the second direction (S166). When the predetermined time has elapsed, the capacitor 110 is discharged and power supply to the solenoid valve 130 is stopped (S170). The capacitor 110 charges the amount of charge corresponding to the energy required to open the solenoid valve 130, and is capable of supplying power to the solenoid valve 130 for about 0.1 second to 5 seconds, for example. The capacitor 110 of FIG.

Even if power supply to the solenoid valve 130 is interrupted, the solenoid valve 130 is maintained in the open state until power is supplied to the solenoid valve 130 in the first direction (S172).

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept as defined by the appended claims.

10: Refrigerator body 11: Freezer
12: refrigerator compartment 13:
15: Cooling cycle 16: Evaporator
17: compressor 18: condenser
19: Inflator
20: heat siphon 21: condensation part
22: evaporator 29: valve
100: external power supply 110: capacitor
120: power supply direction switching circuit 130: solenoid valve
140: Time delay circuit 150: Power supply cut-off circuit
230: Injection tube 240: Microcomputer

Claims (13)

A capacitor charged when the external power is supplied to the refrigerator and discharged when the external power is not supplied;
The refrigerator according to any one of claims 1 to 3, wherein when the external power is supplied to the refrigerator, a power is outputted in a first direction, and when the external power is not supplied to the refrigerator A power direction switching circuit for outputting power; And
And a solenoid valve which is supplied with power from the power source direction switching circuit and is locked when the direction of the power source is the first direction and is opened when the power source is in the second direction,
The solenoid valve
An inflow port through which the fluid flows out to the outside and an inflow pipe separately provided from the inflow port and the inflow port so as to communicate with the inflow port and the flow path circulating through the inflow port; ,
Wherein the electromagnetic valve further comprises a moving core portion for opening and closing the injection tube, and a solenoid coil for driving the moving core portion.

The method according to claim 1,
Further comprising a cooling cycle that circulates the refrigerant of the refrigerator and is separated from the inlet and the outlet,
Wherein the injection tube is provided to inject coolant circulating the cooling cycle into the flow path of the electromagnetic valve in communication with the cooling cycle.
3. The method of claim 2,
Wherein the moving core portion includes a case made of a ferromagnetic material. The method of claim 3,
Wherein the first protruding piece and the second protruding piece are provided so as to face each other at both ends of the case. 5. The method of claim 4,
And an elastic member accommodated in the case and elastically supporting the first projecting piece and the second projecting piece to both ends of the case. 6. The method of claim 5,
Wherein the first protruding piece selectively seals the outlet port according to the movement of the moving core portion, or the second protruding piece seals the inlet tube. The method according to claim 1,
Further comprising a power applying device for controlling whether or not electrical connection is made between the solenoid valves from the power source direction switching circuit. 8. The method of claim 7,
The power applying apparatus includes:
A time delay circuit for outputting the external power supplied to the refrigerator with a time delay; And
And a switching circuit that disconnects the power source direction switching circuit and the solenoid valve when the output power of the time delay circuit is input, and when the output power of the time delay circuit is not inputted, And a power cut-off circuit for opening between the circuit and the solenoid valve. The method according to claim 1,
Further comprising a converter for rectifying the power input to the refrigerator, converting the power to DC power, and supplying the DC power to the capacitor and the power direction switching circuit. The method according to claim 1,
Further comprising a microcomputer for detecting the supply of the external power and for controlling the direction of the output power of the power direction switching circuit according to whether the external power is supplied or not. 11. The method of claim 10,
Further comprising a power cut-off circuit for electrically connecting or disconnecting the power source direction switching circuit and the solenoid valve. 12. The method of claim 11,
The microcomputer,
After the solenoid valve is operated by being supplied with power from the external power source or the capacitor, the power cutoff circuit interrupts the electrical connection between the power source direction switching circuit and the solenoid valve so as to prevent the solenoid valve from being powered Wherein the solenoid valve is a solenoid valve. The method according to claim 1,
Wherein the solenoid valve includes:
The refrigerator according to claim 1,
Wherein the injection tube is provided to inject refrigerant into the circulation passage of the heat siphon.

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