KR19990075612A - Flow control valve - Google Patents

Abstract

The present invention relates to a flow regulating valve, the inlet and outlet are formed on both sides and the cover plate is fixed to the upper surface of the base plate, the support plate is supported on the upper surface of the base plate inside the cover plate and a predetermined recessed portion at the top A disk formed, a bellows fixed to the bottom of the recess and filled with a thermal expansion liquid, a diaphragm fixed to an outer periphery of the upper surface of the disk to form a space filled with a refrigerant between the cover plate and the disk; And a vacuum layer formed in the recess between the bellows and the diaphragm to surround the bellows, and heating means for heating the bellows thermal expansion liquid.

According to the present invention as described above, the heat exchange between the high-temperature thermal expansion liquid and the low-temperature refrigerant is not well achieved, thereby preventing the high temperature thermal expansion liquid from lowering the temperature by the low-temperature refrigerant to expand the thermal expansion liquid By making it more certain, the reliability of the operation is improved.

Description

Flow control valve

The present invention relates to a flow control valve, and more particularly, it is possible to sufficiently secure the reliability of operation by preventing the phenomenon in which the high-temperature thermal expansion liquid is lowered by the low-temperature refrigerant, thereby making the expansion action of the thermal expansion liquid more reliably. To a flow regulating valve.

Generally, a refrigeration cycle is basically composed of an evaporator, a compressor, a condenser and an expansion valve to reduce the ambient temperature while evaporating, compressing, condensing and expanding the refrigerant. Perform the function.

In more detail, the liquefied refrigerant inside the evaporator is evaporated by evaporation. At this time, the refrigerant liquid deprives the latent heat of evaporation necessary for evaporation from the air around the cooling tube and continues to evaporate itself. The air deprived of heat is cooled to lower the temperature, and the air keeps the inside of the inside at low temperature by natural convection or a blowing fan. In the evaporator, the refrigerant liquid supplied from the expansion valve and the evaporated refrigerant vapor coexist, and a change from liquid to steam proceeds, and a constant relationship is established between the evaporation pressure and the evaporation temperature during this state change. .

The refrigerant vapor vaporized in the evaporator is sucked into the compressor. This action is intended to keep the refrigerant pressure inside the evaporator low so that the liquid refrigerant can continue to evaporate vigorously even under low temperature conditions. In addition, the refrigerant vapor sucked into the compressor is compressed by the piston inside the cylinder, and the pressure is increased, so that the refrigerant vapor can be easily liquefied even when cooled by cooling water or cooling air at room temperature.

Thereafter, the compressed gas exiting the compressor is cooled by the condenser to liquefy condensation. In the case of such a condensation action, as in the case of evaporation, the refrigerant is in a state where the vapor and the liquid coexist, and a constant relationship is established between the condensation pressure and the condensation temperature while changing from gas to liquid.

The action of lowering the pressure to a state that is easy to evaporate before the refrigerant liquefied by the condenser is called expansion is referred to as expansion, and the expansion valve acts as a depressurizing action and performs flow rate control of the refrigerant liquid. In other words, the amount of refrigerant evaporating inside the evaporator is determined according to the amount of heat to be removed in the furnace under a predetermined evaporation temperature (evaporation pressure). to be.

In other words, the expansion valve functions as a flow control valve for thermally expanding and expanding the high-temperature and high-pressure liquid refrigerant to a low-temperature low-pressure state by the throttling action, and at the same time, maintaining a proper refrigerant supply amount according to the load of the evaporator.

The expansion valve is known in various forms according to the operation method and structure, and in recent years, a thermopneumatic flow control valve is known that has a high driving force, fine driving, and reduced manufacturing cost, Exemplary embodiments will be described with reference to the accompanying drawings.

As shown in FIG. 1, a cap 1 having a predetermined shape, a heating element bottom plate 3 made of ceramic material having an expansion liquid inlet 2 formed on both sides thereof, and a Ta-Al heating electrode in a middle portion thereof. (4) is provided and is fixed to the upper surface of the heating element base plate 3 and the Al electrode 5, and the outer peripheral portion of the upper surface of the Al electrode 5 via a spacer (6) for example And a membrane 7 formed of a Cu material, interposed between an upper surface of the Al electrode 5 and a lower surface of the spacer 6, and an upper surface of the spacer 6 and a lower surface of the diaphragm 7, respectively. An adhesive layer (also referred to as a 'filler') 8 (9) for improving strength, a thermal expansion solution 10 filled in a space formed between the Al electrode 5 and the diaphragm 7, and the heating element It is composed of a sealing bottom plate 11 fixed to the bottom surface of the bottom plate 3 to close the expansion liquid inlet 2.

Reference numeral 12 in the figure shows a power line.

The cap 1 has a predetermined space portion 1a through which the liquid refrigerant passes, and an inlet port 1b for introducing the liquid refrigerant and an outlet port 1c for discharging the refrigerant on both sides of the upper portion. It is formed so that 1a may pass.

In constructing the thermopneumatic flow control valve as described above, the Al electrode 5 having the Ta-Al heating electrode 4 is first fixed to the upper surface of the bottom plate 3 of the heating element, and the Al electrode 5 is The lower bonding layer 8, the spacer 6, the upper bonding layer 9, and the diaphragm 7 are sequentially bonded and fixed on the upper surface, and the inside of the Al electrode 5, the spacer 6, and the diaphragm 7 is fixed. The predetermined space is formed in the.

Thereafter, the thermal expansion liquid 10 is injected from the lower side of the heating element bottom plate 3 through the expansion liquid inlet 2, and the sealing bottom plate 11 is attached and fixed to the lower surface of the heating element bottom plate 3 to expand the expansion liquid. After the injection port 2 is sealed, the sealing bottom plate 11 is attached and fixed to the bottom of the cap 1, and the power supply line 12 of the Al electrode 5 is led out to the outside of the cap 1.

At this time, the central portion of the diaphragm 7 is located directly under the discharge port 1c formed in the cap (1).

In the conventional flow control valve as described above, the liquid refrigerant flows in through the inlet 1b of the cap 1, passes through the space 1a formed therein, and then through the outlet 1c. When the flow rate of the liquid refrigerant needs to be adjusted when it is discharged to the evaporator, when the power is applied to the Al electrode 5 through the power line 12 drawn out of the cap 1, the Al electrode 5 The Ta-Al heating electrode 4 emits heat, so that the thermal expansion liquid 10 filled in the Al electrode 5 and a predetermined space formed inside the spacer 6 and the diaphragm 7 is formed. As shown in FIG. 2, the intermediate portion of the diaphragm 7 swells toward the discharge port 1c of the cap 1 by the thermal expansion action of the thermal expansion liquid 10, and accordingly the discharge port 1c. By controlling the amount of liquid refrigerant discharged to) to control the overall amount of fluid.

However, the flow control valve according to the prior art as described above has a disadvantage in that the refrigerant and the thermal expansion liquid 10 are blocked only by the diaphragm 7, so that the heat exchange action is easily performed.

That is, when power is applied to the Al electrode 5, the Ta-Al heating electrode 4 generates heat while being heated, and the temperature of the thermal expansion liquid 10 rises by the heat, and the thermal expansion liquid ( As the high temperature of 10) is transferred to the low temperature refrigerant through the diaphragm 7, the thermal expansion liquid 10 does not maintain the high temperature as it is, and thus the thermal expansion action of the thermal expansion liquid 10 is not smooth. There was a problem that does not perform properly to adversely affect the reliability of the product.

It is a main object of the present invention to provide a flow control valve which prevents heat exchange between a high temperature thermal expansion liquid and a low temperature refrigerant.

Another object of the present invention is to provide a flow regulating valve that can ensure the expansion of the thermal expansion liquid more securely by preventing the phenomenon that the high temperature thermal expansion liquid is lowered by the low temperature refrigerant to ensure the expansion of the thermal expansion liquid more reliably. will be.

1 and 2 show the configuration and operation of the flow control valve according to the prior art,

1 is a cross-sectional view showing a state in which the thermal expansion liquid does not expand.

2 is a cross-sectional view showing a state in which the thermal expansion liquid is expanded and the diaphragm swells.

3 is a cross-sectional view showing the configuration of a flow control valve according to the present invention.

Figure 4 is a cross-sectional view showing the configuration of a flow control valve to which another embodiment of the heating means according to the present invention is applied.

Figure 5a and 5b shows another embodiment of the heating means constituting the flow control valve of the present invention,

5A is a sectional view.

5B is a perspective view.

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

21; Base plate 21a; Home

22; Cover plate 22a; Inlet

22b; Outlet 22d; Storage

24,24 ', 24 "; disc 24a; recess

24b; Step surface 25; Thermal expansion liquid

26; Bellows 26a; projection part

27; Diaphragm 28; Vacuum layer

29; O-ring 30; PTC device

31,31 '; Terminal electrodes 41,41 '; Rod electrode

42; Heating coil 51,51 '; Thin film electrode

52,52 '; Terminal lugs 53; Fever Thin Film

In order to achieve the above object of the present invention, the base plate, the cover plate is formed on both sides of the inlet and outlet and is fixed to the upper surface of the base plate, and is supported on the upper surface of the base plate inside the cover plate A disk having a predetermined recessed portion in the recess, a bellows fixed to the bottom of the recessed portion and filled with a thermal expansion liquid, and a space portion fixed to the outer periphery of the upper surface of the disk to fill the refrigerant between the cover plate and the disk. And a vacuum layer formed on the concave portion between the bellows and the diaphragm to surround the bellows, and heating means for heating the bellows thermal expansion liquid.

The upper portion of the bellows is formed in the central portion of the upper surface of the diaphragm in contact with the central portion of the diaphragm to minimize the contact area between the bellows and the expansion action of the bellows is configured to be transmitted to the diaphragm more quickly and accurately.

A stepped surface is formed in a middle portion of the bottom surface of the disk to a predetermined depth, and the bottom peripheral edge of the bellows is fixed to the inner peripheral surface of the stepped surface.

It is preferable to integrally form a thermal expansion liquid inlet tube communicating with the inside of the bellows at the central portion of the lower surface of the disc.

An accommodating groove is formed on the lower surface of the cover plate to a predetermined depth, and an airtight holding member such as an O ring is inserted therein to prevent leakage of the refrigerant between the cover plate and the disc.

According to one embodiment of the heating means, it is configured to include a PTC element provided below the disk to heat the disk.

According to another embodiment of the heating means, it comprises a bar electrode extending through each of the lower side of the disk and a heating coil such as a nichrome wire connecting the upper end of the bar electrode.

The rod electrode preferably forms a thermal expansion liquid inlet hole communicating with the inside of the bellows to serve as an inlet for the thermal expansion liquid.

According to still another embodiment of the heating means, a thin film electrode formed on both sides of the upper surface of the disk, a terminal lug electrically connected to the thin film electrode and extending downwardly on both sides of the disk, It comprises a heat generating thin film formed in the middle of the upper surface in electrical communication with the thin film electrode.

Hereinafter, the flow control valve according to the present invention will be described according to the embodiment shown in the accompanying drawings.

Figure 3 is a cross-sectional view showing the configuration of the flow control valve according to the present invention, as shown in the flow control valve according to an embodiment of the present invention, the base plate 21, the inlet port 22a and both sides and A discharge plate 22b is formed, and the cover plate 22 is fixed to the upper surface of the base plate 21 by several fixing bolts 23, and the upper surface of the base plate 21 in the cover plate 22. A disc 24 which is supported and has a predetermined recessed portion 24a formed thereon, and bellows 26 fixed to the bottom of the recessed portion 24a and filled with a thermal expansion liquid 25 therein. ), A diaphragm 27 fixed to an outer circumferential edge of the upper surface of the disk 24 to form a space portion 22c between the cover plate 22 and the disk 24 and filled with a refrigerant, and the bellows ( Jean formed in the indentation part 24a between 26 and the diaphragm 27 and surrounding the bellows 26 And a heating means for heating the thermal expansion liquid 25 of the bellows 26.

The outlet 22b of the cover plate 22 and the central portion of the diaphragm 27 are preferably arranged on the same line, and a protrusion is formed at the upper surface central portion of the bellows 26 positioned directly below the diaphragm 27. A 26a is formed so that the expansion action of the bellows 26 is transmitted to the diaphragm 27 more quickly and accurately while minimizing the contact area between the diaphragm 27 and the bellows 26.

In addition, the disk 24 is preferably formed of a ceramic material, and the stepped surface 24b is formed at a predetermined depth in the middle of the bottom surface, and the bellows 26 is formed on the inner circumferential surface of the stepped surface 24b. Secure the outer peripheral edge of the bottom).

At this time, although not shown in detail in the drawing, the inner circumferential surface of the stepped surface 24b and the lower end of the outer circumferential surface of the bellows 26 are soldered or bonded by epoxy bonding to form a thermal expansion liquid (filled in the bellows 26). It is desirable to prevent leakage of 25).

In the disk 24, the thermal expansion liquid injection tube 24c is formed integrally with the inside of the bellows 26 at the center of the lower surface thereof, so that the thermal expansion liquid 25 can be injected.

According to the embodiment of the present invention described above, although the fixing bolt 23 is used as a fixing means for fixing the cover plate 22 to the base plate 21, it is not necessarily limited thereto and by applying other fixing means. It is okay.

The flow control valve of the present invention described above includes a sealing structure to prevent leakage of the liquid refrigerant.

That is, the receiving groove 22d is formed in the lower surface of the cover plate 22 to a predetermined depth, and an O ring 29 is inserted therein.

Meanwhile, various forms of heating means for heating the thermal expansion liquid 10 of the flow control valve as described above will be described in more detail with reference to the accompanying drawings.

Figure 3 shows a state in which an embodiment of the heating means is applied to the flow rate control valve according to the present invention, looking at its configuration, forming a seating groove (21a) to a predetermined depth in the middle of the upper surface of the base plate 21 In addition, the PTC (Positive Temperature Coefficient) element 30 which is in surface contact with the lower surface of the disk 24 is fixed to the seating groove 21a, and terminal lugs (top and bottom terminals) are disposed on the upper and lower surfaces of the PTC element 30. 31 and 31 'are connected to each other, and power lines 32 and 32' are respectively connected to lower ends of the terminal lugs 31 and 31 '.

The PTC device 30 is a ceramic material and has a property of generating heat when a power supply V is applied, and the temperature of the PTC device 30 may be adjusted by applying a power supply V suitable for a specific temperature.

In the flow control valve according to the present invention configured as described above, as shown in FIG. 3, a thermal expansion liquid 25 is filled in the bellows 26 mounted in the disk 24, and the disk ( The vacuum layer 28 is formed between the diaphragm 27 and the bellows 26 which are fixed to the upper end part of 24, and the high thermal expansion liquid 25 of the thermal expansion liquid 25 is prevented by the thermal insulation effect of the vacuum layer 28, ie, the heat insulation effect. By minimizing a portion of heat directly contacting the refrigerant through the diaphragm 27, the heat exchange between the high temperature thermal expansion liquid 25 and the low temperature refrigerant is suppressed.

Hereinafter, the operation of the flow control valve according to the present invention in detail.

As shown in FIG. 3, since the PTC element 30 is not heated in the state in which the power supply V is not applied to the heating means, the expansion action of the thermal expansion liquid 25 is not performed, and thus the bellows 26 is deformed. Does not occur, and the phenomenon that the diaphragm 27 swells toward the outlet 22b of the cover plate 22 does not occur.

Accordingly, the liquid refrigerant flowing into the inlet port 22a of the cover plate 22 passes through the space portion 22c of the cover plate 22 and then is discharged to the evaporator side through the outlet port 22b.

On the other hand, when reducing the flow rate of the liquid refrigerant, when the appropriate power supply V required for the system is applied, the PTC element 30 is heated to heat the thermal expansion liquid 24 filled in the bellows 26. .

When the thermal expansion liquid 25 is heated, the bellows 26 is expanded due to the expansion of the thermal expansion liquid 25, and the center portion of the diaphragm 27 is expanded by the expansion of the bellows 26. By pushing up and swelling toward the outlet 22b of the cover plate 22, the amount of the liquid refrigerant discharged to the outlet 22b is reduced.

At this time, the vacuum layer 28 formed between the bellows 26 and the diaphragm 27 serves to block the high temperature of the thermal expansion liquid 25 from being transferred to the low temperature refrigerant through the diaphragm 27. The temperature drop of the thermal expansion liquid 25 is prevented.

On the other hand, Figure 4 shows another embodiment of the heating means constituting the flow control valve according to the present invention, the rod electrode 41 and 41 'extending through each of the lower sides of the disk 24' and And a heating coil 42 connecting upper ends of the bar electrodes 41 and 41 '. It is preferable that the heating coil 42 uses nichrome wire.

The rod electrodes 41 and 41 'have inlet holes 41a and 41'a formed therein, respectively, to serve as injection holes for the thermal expansion liquid 25.

Although not shown in the drawing, the bar electrodes 41 and 41 'are connected to power lines, respectively, so that power can be applied.

According to another embodiment of the present invention as described above, since the heating coil 42 is not heated in a state where power is not applied, the bellows 26 and the diaphragm 27 are not deformed, and thus the cover plate 22 is not formed. After passing through the space portion 22c of the cover plate 22, the liquid refrigerant flowing into the inlet port 22a of the cover plate 22 is discharged to the evaporator side through the outlet port 22b and, conversely, is fixed to the rod electrodes 41 and 41 ′. When the heating coil 42 is heated by applying a power source, the bellows 26 and the diaphragm 27 are deformed by the expansion of the thermal expansion liquid 25 to reduce the amount of liquid refrigerant discharged to the outlet 22b. .

5a and 5b show another embodiment of the heating means constituting the flow control valve according to the present invention.

According to still another embodiment of the above heating means, the thin film electrodes 51 and 51 'formed on both sides of the upper surface of the disk 24 &quot; and the thin film electrodes 51 and 51' are electrically connected to each other. In addition, the terminal lugs 52 and 52 'which are respectively penetrated downwardly on both sides of the disk 24 "and electrically connected to the thin film electrodes 51 and 51' in the middle of the upper surface of the disk 24". It includes a heat generating thin film 53 formed to pass through.

The thin film electrodes 51 and 51 ′ may be formed of Al, and the heating thin film 53 may be formed of Ta—Al.

The terminal lugs 52 and 52 'are connected to power lines 54 and 54', respectively, to heat the heat generating thin film 53 as the power supply V is applied.

At this time, the temperature of the heat generating thin film 53 is changed according to the size of the power supply V, and thus, the temperature of the heat generating thin film 53 can be accurately adjusted by applying a power supply V suitable for a specific temperature.

5a and 5b, the bellows 26 is omitted for convenience, and reference numerals 52a and 52'a show expansion fluid injection holes, respectively.

In another embodiment of the present invention as described above, as the power supply V is applied to the thin film electrodes 51 and 51 ′, the exothermic thin film 53 is heated to expand the thermal expansion liquid 25, and thus the bellows 26 ) And the diaphragm 27 is modified to perform an action of adjusting the amount of the liquid refrigerant discharged to the outlet 22b of the cover plate 22, the detailed description thereof is the same as described above will be omitted.

As described above, the flow control valve according to the present invention includes a cover plate having inlets and outlets formed on both sides thereof and fixed to an upper surface of the base plate, and being supported on the upper surface of the base plate inside the cover plate. A disk having a predetermined recessed portion in the recess, a bellows fixed to the bottom of the recessed portion and filled with a thermal expansion liquid, and a space portion fixed to the outer periphery of the upper surface of the disk to fill the refrigerant between the cover plate and the disk. A diaphragm, a vacuum layer formed around the bellows and the diaphragm to enclose the bellows, and a heating means for heating the bellows thermal expansion liquid. So that it does not work well, so that the high temperature thermal expansion liquid The effect of lowering the temperature by the low-temperature refrigerant and making the expansion action of the thermal expansion liquid more reliably improves the reliability of the operation.

Claims (9)

With base plate, A cover plate having inlets and outlets formed at both sides thereof and fixed to an upper surface of the base plate; A disk which is supported on the upper surface of the base plate inside the cover plate and has a predetermined recess in the upper part; A bellows fixed to the bottom of the recess and filled with a thermal expansion liquid therein; A diaphragm fixed to an outer circumferential edge of the upper surface of the disk to form a space portion in which a refrigerant is filled between the cover plate and the disk; And a vacuum layer formed on the concave portion between the bellows and the diaphragm to surround the bellows, and heating means for heating the bellows thermal expansion liquid. 2. The method of claim 1, wherein a protrusion is formed at the center of the upper surface of the bellows so as to contact the central portion of the lower surface of the diaphragm so that the expansion action of the bellows is more quickly and accurately transmitted to the diaphragm while minimizing a contact area between the diaphragm and the bellows. Flow control valve. 3. The flow regulating valve according to claim 2, wherein a stepped surface is formed at a predetermined depth at an intermediate portion of the bottom surface of the disk, and a lower end peripheral edge of the bellows is fixed to an inner peripheral surface of the stepped surface. 4. The flow regulating valve according to claim 3, wherein a thermal expansion liquid inlet tube communicating with the inside of the bellows is integrally formed at the center of the lower surface of the disk. The flow regulating valve according to claim 1, wherein an accommodating groove is formed on a lower surface of the cover plate at a predetermined depth, and an airtight holding member is inserted therein to prevent leakage of the refrigerant between the cover plate and the disk. The flow regulating valve according to claim 1, wherein the heating means includes a PTC element installed under the disk to heat the disk. The flow regulating valve according to claim 1, wherein the heating means comprises a rod electrode extending downwardly on both sides of the disk, and a heating coil connecting the upper end of the rod electrode. 8. The flow regulating valve according to claim 7, wherein the rod electrode is formed so that a thermal expansion liquid inlet hole communicating with the inside of the bellows is formed therein to serve as an inlet for the thermal expansion liquid. The disk according to claim 1, wherein the heating means comprises a thin film electrode formed on both sides of an upper surface of the disk, a terminal lug electrically connected to the thin film electrode and extending through both sides of the disk, respectively, and an upper surface of the disk. A flow control valve comprising a heat generating thin film formed to be in electrical communication with the thin film electrode in the middle portion.