KR20110054808A - Derection control valve for air conditioner - Google Patents

Abstract

PURPOSE: A direction control valve for an air conditioner is provided to reduce energy consumption by maintaining a mode without additional power supply. CONSTITUTION: A direction control valve for an air conditioner comprises a valve body(110), a switching spool(120), a drive shaft(130), a mode conversion unit, a pair of magnetic coils, and a pair of magnets. The valve body comprises an input terminal and a plurality of output terminals. The switching spool determines the fluid flow direction of a main valve according to the sliding position in the valve body and selects a cooling mode or heating mode of an air conditioner. One end of the drive shaft is coupled to the switching spool while the other end is projected to the outside of the valve body. The mode conversion unit includes one or more mode elements and moves the drive shaft to the inside or outside of the valve body when a magnetic force is applied to the mode elements. The magnetic coils are arranged along the side of the mode conversion unit, separate from the mode conversion unit, and selectively applied with voltage to create the magnetic force for moving the mode elements. The magnets fix the moved mode elements with the attractive force.

Description

Direction control valve for air conditioner {Derection control valve for air conditioner}

The present invention relates to a directional control valve for an air conditioner, and more particularly, to move a switching spool through a spaced magnet and a magnetic coil, and to turn off a voltage applied to the magnetic coil after the switching spool is moved. Even if the position of the switching spool by the magnet relates to an air conditioner directional control valve that can save energy.

In general, a combined heat and heat pump air conditioner for controlling air flow in a hydraulic or high pressure circuit to realize cooling and heating is widely used.As a well known heat and cooling combined heat pump air conditioner, heat is naturally transferred from a high temperature side to a low temperature side. In order to move heat from the low temperature side to the high temperature side, some action must be applied from the outside.

Such a heat pump air conditioner has a transport mechanism for heat that is transferred to a cycle consisting of compression, condensation, expansion and evaporation of a refrigerant, and generates the cold air required for cooling or the warm air required for heating through heat exchange during condensation and evaporation.

The choice of cooling or heating can be done by changing the positions of the heat exchangers (condensers and evaporators) used in the condensation and evaporation processes, but it is practically impossible to change the positions of the condensers and evaporators. A four-way control valve is used to convert the refrigerant flow to the condenser and the evaporator.

1 is a flow chart of the air conditioner when the air conditioner using a conventional four-way control valve, Figure 2 is a flow chart of the air conditioner when heating using a conventional four-way control valve.

1 and 2, the conventional four-way control valve is composed of a four-port two-position solenoid-hydraulic actuating valve of the inner filer type combined with the main valve 10 and the pilot valve 20.

The main valve 10 has four ports (P, B, R, A) and two pilot connection ports located at both ends. The main valve 10 has four refrigerant connecting pipes for connecting each port to the discharge and intake ports of the compressor 1 of the air conditioner elements, the outdoor heat exchanger 4 and the indoor heat exchanger 2, respectively. It is connected.

That is, as shown in Figure 1, when the cooling operation is selected, the pilot spool 25 is in the normal position, wherein the pilot pressure in one chamber 15 of the main valve 10 is higher than the other chamber (16) Works. Then, the main spool 17 of the main valve 10 is moved to the left side so that the supply side port P is connected to the load side port R.

Therefore, in the air conditioner, the refrigerant discharged from the discharge port of the compressor 1 is transferred to the outdoor heat exchanger 4 through ports P and A of the main valve 10, so that the outdoor heat exchanger 4 serves as a condenser. From the indoor heat exchanger 2, a refrigeration cycle in which the refrigerant is transferred to the inlet of the compressor 1 through ports B and R of the main valve 10 is performed.

On the other hand, when the heating operation is selected, as shown in Figure 2, the pilot spool 25 is moved to the right side at this time, the pilot pressure of the other chamber 16 of the main valve 10 acts higher than the one side chamber 15 . Then, the main spool 17 of the main valve 100 is moved to the right side so that the supply side port P is connected to the load side port B and the other load side port A is connected to the drain side port R.

Therefore, in the air conditioner, the refrigerant discharged from the discharge port of the compressor 1 is transferred to the indoor heat exchanger 2 through ports P and B of the main valve 10, so that the indoor heat exchanger 2 serves as a condenser. And the refrigerant decompressed by the expansion mechanism 3 is then transferred to the outdoor side heat exchanger 4 so that the outdoor side heat exchanger 4 acts as an evaporator, and from the outdoor side heat exchanger 4 Is a heat cycle in which the refrigerant is transferred to the inlet of the compressor 1 through the ports A and R of the main valve 10.

Such a pilot valve 20 may be referred to as a direction control valve because it is installed to change the direction of the main spool 17 in the main valve 10.

3 is a detailed view of a conventional pilot valve 20. Referring to FIG. 3, in the air conditioner as described above, the conventional pilot valve 20 is a four-port two-position spring offset solenoid operated type, connected to the main valve through four capillaries, and connected to the switching spool 25. The movable body 28 of the predetermined metal material is coupled to the position by the solenoid coil 27.

Further, by moving the moving body 28 interlocked with the pilot spool 25 to the normal position by the spring 26 or the conversion position by the electromagnetic force when the solenoid coil 27 is excited, either the load side ports A and B are supplied to the supply side. Connect to port P and connect the other to drain port R.

At this time, the excitation current of the solenoid coil 27 is cut off at the cooling operation of the air conditioner and is applied only at the heating operation.

That is, during heating operation, the current consumption of the entire system is rapidly increased by continuously applying current to the solenoid coil 27 to fix the position of the mobile body 28 coupled to the pilot spool 25.

Accordingly, an object of the present invention is to solve such a conventional problem, and provides a directional valve for an air conditioner that can fix the position of the switching spool without applying a separate power after switching to the cooling mode or the heating mode. Is in.

In addition, there is provided a direction switching valve for the air conditioner that can save energy by not requiring a separate power for the mode maintenance.

The above object is, according to the present invention, in the air conditioner direction control valve for controlling the main valve for implementing the cooling mode or heating mode of the air conditioner according to the movement direction of the fluid, the input end and the plurality of output end is A valve body formed; A switching spool configured to determine a cooling direction or a heating mode of the air conditioner by determining a fluid movement direction of the main valve according to a sliding movement position in the valve body; One side is coupled to the switching spool, the other side is a drive shaft is installed to protrude to the outside of the valve body; is coupled to the other side of the drive shaft, including at least one mode body magnetic force or magnetic force to the mode body A mode switching unit which moves the drive shaft to the inside or the outside of the valve body when applied; A pair of magnetic coils spaced apart side by side along the side of the mode switching unit, and selectively applied with a voltage to move the mode body by magnetic force; And a pair of magnets fixed between the magnetic coil and the mode switching unit to fix the mode body moved by the attraction force.

Here, the mode switching unit includes a mode body provided in pairs, wherein the pair of mode bodies are installed on the other side of the drive shaft with a distance shorter than the separation distance of the pair of magnets is applied to the magnetic The magnetic force of the coil and the magnetic force of the adjacent magnets move to face the adjacent magnets and the adjacent magnets determine the exact position of the switching spool, and the magnetic coil power is turned off after the switching spool moves. Even if it is off, it is preferable to be fixed by the magnet and the opposing force.

On the other hand, the mode switching unit, including a mode switching body and a pair of mode switching body coupled to the other side of the drive shaft, the pair of mode body is shorter than the separation distance of the pair of magnets to the mode switching body The magnetic force of the magnetic coil and the magnetic force of the adjacent magnets spaced apart from each other and moved to face the adjacent magnets to determine the exact position of the switching spool, and to face the adjacent magnets, Even if the power of the magnetic coil is turned off after the switching spool is moved, it can be fixed by the magnet and the opposing force.

In addition, the magnetic coil and the magnet may be arranged on both sides of the upper side and the lower side with respect to the mode switching unit.

The magnetic coil to which the voltage is applied among the pair of magnetic coils is preferably turned off after the mode body is moved to face any one of the magnets.

On the other hand, the pair of modulators are provided with permanent magnets having different polarities from each other, and the pair of magnets have different polarities from the adjacent modulators so that attractive forces with the adjacent modulators act. It is preferable to be provided.

According to the present invention, there is provided a direction switching valve for an air conditioner that can fix the position of the switching spool without applying a separate power after switching to the cooling mode or the heating mode.

In addition, there is provided a direction switching valve for the air conditioner to save energy by not requiring a separate power for mode maintenance.

Prior to the description, in the various embodiments, components having the same configuration will be representatively described in the first embodiment using the same reference numerals, and in other embodiments, different configurations from the first embodiment will be described. do.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the air conditioner direction switching valve according to the first embodiment of the present invention.

4 is a schematic view of a direction change valve for an air conditioner according to a first embodiment of the present invention. Referring to FIG. 4, the direction change valve 100 for an air conditioner according to the first embodiment of the present invention includes a valve body 110, a switching spool 120, a driving shaft 130, and a driving unit 140. .

The valve body 110 is a predetermined housing, the input end and the plurality of output end through which the fluid is introduced and discharged is formed, the input end and the plurality of output end in the prior art through a predetermined capillary (L1, L2, L3, L4) It is connected to the main valve as described.

The switching spool 120 is provided to slide in the valve body 110 by the driving unit 140 to be described later.

In particular, by selectively outputting the fluid input to any one of the plurality of output terminals according to the sliding position of the switching spool 120 by the drive of the drive unit 140 to be described later to determine the fluid movement direction of the main valve to cool the air conditioner Allow the mode or heating mode to be selected.

The drive shaft 130 is coupled to the switching spool 120 on the left side, and the right side is installed to protrude to the outside of the valve body 110 and is coupled to the driving unit 140 to be described later.

That is, the drive shaft 130 serves to connect the switching spool 120 and the driving unit 140 so that the switching spool 120 slides inside the valve body 110.

5 is an enlarged view of the driving unit of FIG. 4. Referring to FIG. 5, the driving unit 140 includes a housing 1410, a mode switching unit 1420, a magnetic coil 1430, and a magnet 1440.

The housing 1410 is coupled to the right side of the valve body 110, it is coupled so that the fluid contained in the valve body 110 is completely sealed by the movement to the inside and outside of the drive shaft (130).

In addition, a mode switching unit 1420 and a magnet 1440 to be described later are installed inside the housing 1410, and a magnetic coil 1430 is installed outside.

The mode switching unit 1420 includes a mode switching body 1421 and a pair of mode bodies 1422 and 1423.

The mode shifter 1421 is coupled to the driving shaft 13 described above so as to be movable in the longitudinal direction from the inside of the housing 1410.

The pair of mode bodies are the first mode body 1422 and the second mode body 1423, which are provided as permanent magnets having different polarities and are spaced apart from the mode switching body 1421.

Here, the separation distance between the first mode body 1422 and the second mode body 1423 is spaced shorter than the separation distance between the first magnet 1442 and the second magnet 1442, which will be described later.

The magnetic coil 1430 is provided as a pair of the first magnetic coil 1431 and the second magnetic coil 1432 and spaced apart side by side along the side of the mode switching unit 1420 described above.

In addition, each magnetic coil is connected to a predetermined power source (not shown) so that a magnetic force is generated when a voltage is applied. The bar is shown spaced apart along the side of the mode switching unit 1420 and is installed outside the housing 1410.

On the other hand, the separation distance of the magnetic coil 1430 is preferably spaced apart to correspond to the separation distance of the magnet 1440 to be described later.

In addition, each magnetic coil generates a magnetic force when voltage is applied, but after the movement is completed so that the above-described mode and the magnet to be described later face each other, the power is turned off to lose the magnetic force. Is installed.

The magnet 1440 is a permanent magnet provided as a pair of the first magnet 1441 and the second magnet 1442, and is installed between the mode switching unit 1420 and the magnetic coil 1430.

Specifically, they are spaced apart side by side along the side of the mode switching unit 1420 described above, and are installed inside the housing 1410.

At this time, the separation distance is preferably separated by a distance longer than the separation distance of the pair of the mode body described above.

In addition, the polarity of the first magnet 1442 is provided to have a polarity different from that of the first mode body 1422 described above, so that mutual attraction is applied to the polarity of the second magnet 1442. The polarity is provided so as to have a polarity different from that of the second mode body 1423 described above, and mutual attraction acts.

On the other hand, the above-described pair of magnetic coils and a pair of magnets and the upper side with respect to the mode switching unit 1420 to facilitate the movement of the mode switching unit 1420 even if a small magnetic force generated in the magnetic coil It may be disposed on both sides of the lower side.

The operation of the first embodiment of the directional valve for the air conditioner described above will now be described. 6 and 7 are operational state diagrams of FIG.

Referring to FIG. 6, in the mode switching body 1421, the first mode body 1422 is provided as the N pole, and the second mode body 1423 is provided as the permanent magnet of the S pole and spaced apart from each other, and the first magnet 1441 is provided. The silver S pole and the second magnet 1442 are provided as the N poles and are spaced apart from the side of the mode switching unit 1420.

At this time, when a voltage is applied to the first magnetic coil 1431 to generate a magnetic force, the magnetic force of the first magnetic 1441 and the magnetic force of the first magnet 1442 are applied to the first mode body 1422 and the attraction force. The mode switching body 1421 is moved to the left by being attracted by.

At this time, the mode switching body 1421 moves until the first mode body 1422 and the first magnet 1442 face each other, and after the movement is completed, the power applied to the first magnetic coil 1431 is turned off. The mode switching body 1421 is fixed by the attraction force between the first magnet 1442 and the first mode body 1422.

That is, the driving shaft 130 and the switching spool 120 may be moved to the left to be selected as any one mode and then maintain the state of the corresponding mode even if the power applied to the first magnetic coil 1441 is turned off. .

Meanwhile, referring to FIG. 7, when a voltage is applied to the second magnetic coil 1432 to generate a magnetic force during the mode switching, the second magnetic force is generated by the magnetic force of the second magnetic 1432 and the magnetic force of the second magnet 1442. The mode body 1422 is attracted by the attractive force, and the mode switching body 1421 moves to the right.

At this time, the mode switching body 1421 moves until the second mode body 1423 and the second magnet 1442 face each other, and after the movement is completed, the power applied to the second magnetic coil 1432 is turned off. The mode switching body 1421 is fixed by the attraction force between the second magnet 1442 and the second mode body 1423.

That is, the drive shaft 130 and the switching spool 120 are moved to the right, so that the output terminal of the fluid is selected to the output terminal different from FIG. 6 so that the direction of movement of the fluid is changed to change the mode of the entire air conditioner. do.

This is one of the conventional cooling mode or heating mode has to be continuously powered to maintain the mode, compared to the power off (off) can maintain the mode state can significantly reduce the power consumption, so This can also increase the energy efficiency of the whole air conditioner.

On the other hand, in the first embodiment has been described that the first mode body and the second mode body is provided in the mode switching body provided separately, it may be installed in the drive shaft protruding to the outside of the valve body.

The scope of the present invention is not limited to the above-described embodiment, but may be embodied in various forms of embodiments within the scope of the appended claims. Without departing from the gist of the invention claimed in the claims, it is intended that any person skilled in the art to which the present invention pertains falls within the scope of the claims described herein to various extents that can be modified.

1 is a flow chart of the air conditioner during cooling using a conventional four-way control valve,

Figure 2 is a fluid flow diagram of the air conditioner when heating using a conventional four-way control valve,

3 is a detailed view of a conventional pilot valve 20,

4 is a schematic view of a direction change valve for an air conditioner according to a first embodiment of the present invention;

5 is an enlarged view of the driving unit of FIG. 4;

6 and 7 are operational state diagrams of FIG.

<Explanation of symbols for the main parts of the drawings>

100: air conditioner direction switching valve 110: valve body

120: switching spool 130: drive shaft

140: drive unit 1410: housing

1420: mode switching unit 1421: mode switching body

1422: first mode body 1423: second mode body

1430: magnetic coil 1431: first magnetic coil

1432: Second magnetic coil 1440: Magnet

1441: first magnet 1442: second magnet

Claims (6)

In the air conditioner direction control valve for controlling the main valve to implement the cooling mode or heating mode of the air conditioner according to the direction of movement of the fluid, A valve body having an input end and a plurality of output ends through which fluid is introduced and discharged; A switching spool configured to determine a cooling direction or a heating mode of the air conditioner by determining a fluid movement direction of the main valve according to a sliding movement position in the valve body; One side is coupled to the switching spool, the other side is the drive shaft is installed to protrude to the outside of the valve body; A mode switching unit coupled to the other side of the drive shaft and including at least one mode body to move the drive shaft to the inside or the outside of the valve body when a magnetic force or a magnetic force is applied to the mode body; A pair of magnetic coils spaced apart side by side along the side of the mode switching unit, and selectively applied with a voltage to move the mode body by magnetic force; And a pair of magnets installed between the magnetic coil and the mode switching unit to fix the mode body moved by the attraction force. The method of claim 1, The mode switching unit includes a mode body provided in pairs, The pair of modulators are installed on the other side of the drive shaft at a distance shorter than the distance of the pair of magnets so that the magnetic force of the magnetic coil to which the voltage is applied and the magnetic force of the adjacent magnet are applied. Directional valve for the air conditioner, characterized in that to move to face the adjacent magnets by. The method of claim 1, The mode switching unit, And a mode body provided in pairs with a mode converter coupled to the other side of the drive shaft, wherein the pair of mode bodies are spaced apart by a distance shorter than the separation distance of the pair of magnets in the mode converter. And a magnetic force of the applied magnetic coil and a magnetic force of an adjacent magnet so as to face the adjacent magnet. The method of claim 1, The magnetic coil and the magnet is a direction switching valve for the air conditioner, characterized in that arranged on both sides of the upper side and the lower side with respect to the mode switching unit. 5. The method according to any one of claims 1 to 4, The magnetic coil to which a voltage is applied among the pair of magnetic coils is turned off after the mode body is moved to face any one of the magnets. The method of claim 2 or 3, The pair of modulators are provided with permanent magnets having different polarities, and the pair of magnets have different polarities from the adjacent modulators so that attractive forces with the adjacent modulators act. Directional valve for air conditioners, characterized in that provided.

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