KR20200043566A - Electronic expansion valve - Google Patents

Abstract

The present invention relates to an electronic expansion valve for a cooling and heating system and, particularly, to an electronic expansion valve for a cooling and heating system, enabling a refrigerant to flow at more flow rate for performing enough heating capability. The electronic expansion valve (1000) for the cooling and heating system according to the present invention comprises: a stepping motor part (1100) which has a needle (1130) moving in a linear direction according to supply of power; and a valve part (1200) assembled under the stepping motor part and equipped with a body (1210) in which a first flow path (1213) and a second flow path (1214) are established side by side between a first entrance and exit hole (1211) provided on one side surface and a second entrance and exit hole (1212) provided on the other side surface, wherein a first valve seat (1220a) installed on the first flow path controls the flow rate of the refrigerant during cooling within a first movement range of the needle, a second valve seat (1220b) installed on the second flow path opens and closes a passage of the refrigerant during heating within a second movement range of the needle, a second flow path valve member (1230) installed on the second valve seat has a through hole (1231a) to enable the needle to move up and down in the direction of a central shaft and is pressed in the closing direction of the second valve seat by a pressing member (1240) installed on the upper part of the second flow path valve member, a driving portion (1131) provided at a predetermined position of the needle is configured to drive the second flow path valve member in the opening direction of the second valve seat to open and close the second valve seat, and the passage of the refrigerant is arranged between a pressure distribution chamber and the first entrance and exit hole, wherein the pressure distribution chamber is formed by the body and an adaptor (1250) coupled to the upper part of the body.

Description

ELECTRONIC EXPANSION VALVE

The present invention relates to an electronic expansion valve for an air-conditioning system, and more particularly, to an electronic expansion valve for an air-conditioning system capable of flowing a larger flow rate of refrigerant in order to sufficiently exhibit heating capacity.

Conventional air conditioning and heating systems (heat pump cycles) switch between the compressor and the cooling or heating operation, so the switching valve for switching the refrigerant flow path, the outdoor heat exchanger and the distributor through which the refrigerant passes during heating, and the thermal expansion valve and the cooling temperature. It consists of a check valve through which the refrigerant passes, a temperature-type thermal expansion valve with a check valve through which the refrigerant passes during cooling and heating, and an indoor heat exchanger.

Therefore, when cooling, the refrigerant compressed by the compressor flows into the outdoor heat exchanger, the distributor and the check valve, and the temperature type thermal expansion valve and the indoor heat exchanger and the compressor, and in the heating, the refrigerant flows in the opposite direction.

In the cooling / cooling system, the refrigerant gas compressed by the compressor flows into the outdoor heat exchanger through a switching valve during cooling, condenses by exchanging heat with outside air, and then flows into the temperature-type thermal expansion valve with a check valve through a check valve and expands adiabatically. , It exchanges heat with indoor air in an indoor heat exchanger to evaporate and cool the indoor.

On the other hand, during heating, the refrigerant gas compressed by the compressor flows into the indoor heat exchanger through a switching valve, heat exchanges with the indoor air, condenses, and then heats the room, then heats the temperature-thermal expansion valve through the temperature-type thermal expansion valve with a check valve. It is depressurized by entering into the product, evaporates from the outdoor heat exchanger through a distributor, and then returns to the compressor.

The temperature-type thermal expansion valve with a check valve used in the air-conditioning system has a built-in check valve and controls the flow rate by the expansion valve part at constant flow (when cooling) and the check valve part at reflux (when heating). Passes. Here, the flow rate of the refrigerant in the check valve portion is a large flow rate with respect to the positive flow, and it is necessary to flow a flow equivalent to that of the connecting pipe so that almost no pressure loss occurs.

However, the conventional electric valve includes a valve body having a first flow path and a second flow path communicating with the valve chamber, a valve body contacting the valve seat of the valve body, a stator coil and a sealing case disposed outside the cylindrical sealing case and the sealing case. A screw thread and a valve that open and close the valve body against the valve seat through a screw shaft by a screw feed action between a rotor rotated by energization of the stator coil on the inside and movable in the valve opening direction and a valve shaft holder according to the rotation of the rotor. A shaft holder and the like are provided. The rotor consists of a permanent magnet and a valve shaft holder fixed to the permanent magnet by means of a loop.

The electric valve having the above configuration, when opening and closing the valve, energizes the stator coil, rotates the rotor, and rotates the valve shaft holder. The rotational movement of the valve shaft holder is converted to the vertical movement of the valve shaft, and when the valve shaft descends, the flow path is closed when the valve body comes into contact with the valve seat, and when the valve shaft rises and the valve body is separated from the valve seat, the flow path is opened. .

In such an air-conditioning system, a temperature expansion valve with a check valve or a pipe connected in parallel with a temperature expansion valve and a check valve is used. This check valve part has an expansion valve opening diameter to reduce pressure loss. Compared to the large-diameter, the check valve built-in type has a complicated structure of the temperature expansion valve itself, which increases the size and increases the cost.

In addition, since the temperature expansion valve and the check valve are connected in parallel, extra connecting piping and joining work are required, which increases the size and cost.

And in order to improve the energy saving efficiency, the same problem occurred when an electromagnetic expansion valve was used as a replacement for the temperature expansion valve.

In order to solve this problem, there is no need to separately connect the check valves in parallel, and an electric valve for an air conditioning system that can satisfy performance without having a built-in check valve is known from Japanese Patent No. 50202120. It is used in an air-conditioning and cooling system that performs cooling and heating by controlling the flow. It is equipped with a valve body that moves more linearly to an electric motor and controls the valve opening of the valve seat of the valve body. The valve controls the refrigerant flow rate during cooling in the first valve opening range, and at the same time, when the heating is performed in the second valve opening range, the refrigerant at a flow rate of 4 times or more of the maximum fluid flow rate of the controllable refrigerant during heating can pass. In order to do this, the tip portion of the valve body is formed as a conical object that is reduced toward the tip side, and at the same time, the conical object It is configured to control the fluid flow rate between the minute side surface and the inner peripheral surface of the valve seat, and the angle formed between the side surface of the conical target and the axis of the valve body is 15 ° or less, and for the total amount of pulse movement of the valve body, from the side surface The ratio of the length in the axial direction is set to 0.7 or less.

As described above, in the heating and cooling system, there is no need to separately connect the check valves in parallel, and the performance can be satisfied with one unit without a check valve, and cost reduction and miniaturization can be achieved.

However, although the Japanese Patent No. 5022120 may flow a larger refrigerant flow rate during cooling than during cooling, the desire to improve the technology of allowing a larger refrigerant flow rate to flow to sufficiently exhibit heating capability continues.

Reference: Japanese Patent No. 5022120 Invention name "Electric valve for cooling and heating system".

The present invention has been devised to solve the above-mentioned requirements, as well as using a large-diameter second flow path valve member to largely flow the refrigerant flow rate, so that the second flow path valve member is not subjected to the force of the refrigerant pressure. Accordingly, an object of the present invention is to provide an electronic expansion valve for an air-conditioning system capable of opening and closing a refrigerant passage at a flow rate under a high-pressure refrigerant with a small driving force.

An electronic expansion valve for an air-conditioning system according to the present invention for achieving the above object includes a stepping motor unit having a needle moving in a linear direction while rotating forward and backward according to the supply of power; In addition to being assembled to the lower portion of the stepping motor, the first flow path is provided between the first inlet and outlet provided on one side and the second inlet and outlet provided on the other side so as to control the refrigerant flow rate according to the cooling and heating according to the movement amount of the needle. While having a body in which a second flow path is juxtaposed, the first toilet seat installed in the first flow path controls the refrigerant flow rate during cooling in the first moving range of the needle, and the second toilet seat installed in the second flow path is the needle 2 Opens and closes the refrigerant passage during heating in the movement range, and the second flow path valve member installed in the second toilet seat is formed with a through hole so that the needle can move up and down in the direction of the central axis, and the second flow path valve member It is pressed in the closing direction of the second toilet seat by a pressing member installed on the upper side, and a driving portion provided at a predetermined position of the needle drives the second flow path valve member in the opening direction of the second toilet seat, and thus the second side It is configured to open and close, and between the body and an adapter fastened to the upper portion of the body, there is a refrigerant passage through which a refrigerant can flow between the back pressure chamber and the first inlet and outlet, where the pressure member and the second flow valve member are installed. Includes; provided valve portion.

Here, the refrigerant passage is characterized in that it is one of a gap between the needle through hole for the needle installation of the second flow path valve member and the needle, and a communication hole between the back pressure chamber and the first inlet and outlet.

In addition, the driving portion installed on the needle is characterized in that any one of a protrusion projecting on the outer peripheral surface of the needle, a step formed on the outer peripheral surface of the needle, and an E-ring installed on the outer peripheral surface of the needle.

In addition, the stepping motor unit is press-fitted into an adapter fastened to the upper portion of the valve unit, and a guide pin is inserted into the upper portion, a holder screwed in the upper central axis direction of the guide, and a central axis direction of the holder A needle fitted in the central axis direction of the guide and the adapter, a spring fitted into the space between the upper portion of the needle and the holder, a stopper fitted on the upper portion of the holder to prevent rotation about the holder, and A magnet fitted to the upper portion of the holder and in contact with the upper portion of the stopper while being prevented from rotating relative to the holder, and a cap fitted to accommodate the upper portion of the holder together with the upper portion of the needle, and located on the upper portion of the cap So that the spring fitted on the upper part of the needle, and fixed on the upper part of the adapter to accommodate the spring and the magnet In addition to the ribs, fitted to accommodate the sleeve, there is a mold molded with a coil, a stator, a terminal, and a bobbin accommodated therein. It is made of a bracket fixed to the fastening screw.

On the other hand, the valve unit is assembled to the lower portion of the stepping motor, and the first inlet and outlet provided on one side and the second inlet and outlet provided on the other side to control the refrigerant flow rate during cooling and heating according to the movement amount of the needle. A body in which a first flow path and a second flow path are interposed therebetween; It is installed between the first inlet and the second inlet and at the same time, while communicating with the first and second channels, the first toilet seat opening and closing the first channel while in close contact with the lower end of the needle, and the second penetrating from the top to the bottom A valve body having a second toilet seat for opening and closing the flow path; It is seated on the upper part of the valve body to open and close the second toilet seat in the second flow path, and a through hole is formed at the center of the shaft to allow the needle to move in the axial direction, and is pressed upward by a driving part installed at a predetermined position of the needle. A second flow path valve member capable of moving upward; A pressing member having one side on the upper surface of the second flow path valve member and the other side on the adapter; While being fastened so that the outer circumferential surface is sealed on the upper portion of the body, the receiving groove is formed to receive the pressing member while being fastened to the upper portion of the valve body, while the guide assembly hole is formed at the center of the opposite axis of the receiving groove to press the guide. Adapter; characterized in that consisting of.

As described above, according to the electronic expansion valve for an air-conditioning system according to the present invention, in addition to using a large-diameter second flow path valve member to largely flow the refrigerant flow rate, the second flow path valve member does not receive the force of the refrigerant pressure. Thus, there is an effect that can open and close the refrigerant passage of the flow rate under a high-pressure refrigerant with a small driving force.

1 is a perspective view showing an electronic expansion valve for an air-conditioning system according to an embodiment of the present invention,
Figure 2 is a front view of Figure 1,
3 is a plan view of FIG. 1,
4 is a left side view of FIG. 1,
5 is a right side view of FIG. 1,
6 is a rear view of FIG. 1,
7 is a cross-sectional view taken along line A-3 in FIG. 3;
8 is a sectional view taken along line B-B in FIG. 3,
9 is a cross-sectional view taken along line C-C in FIG. 3;
10 is a sectional view taken along line D-D in FIG. 3,
11 is an exploded perspective view of FIG. 1.

Hereinafter, an electronic expansion valve for an air-conditioning system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In adding the quotation marks to the components of the drawings, the same components have the same reference numerals as possible even though they are displayed on different drawings, and a known function determined to unnecessarily obscure the subject matter of the present invention And detailed description of the configuration is omitted. In addition, directional terms such as 'top', 'bottom', 'front', 'back', 'tip', 'front', 'end' and the like are used in connection with the orientation of the disclosed drawing (s). Since the components of the embodiments of the present invention can be positioned in various orientations, the directional terms are used for illustrative purposes and are not limiting.

The electronic expansion valve 1000 for an air-conditioning system according to the present invention, as shown in FIGS. 1 to 11, a stepping motor unit having a needle 1130 moving in a linear direction while forward and reverse rotation according to the supply of power. (1100); The first inlet 1211 provided on one side and the second inlet 1212 provided on the other side so as to be assembled to the lower portion of the stepping motor and control the refrigerant flow rate according to the amount of needle movement during cooling and heating. While having a body 1210 in which a first flow path 1213 and a second flow path 1214 are juxtaposed, the first toilet seat 1220a installed in the first flow path is in a first movement range of the needle 1130. Controlling the flow rate of the refrigerant during cooling, the second toilet seat 1220b installed in the second flow path 1214 opens and closes the refrigerant passage during heating in the second movement range of the needle 1130, and the second toilet seat The installed second flow path valve member 1230 is formed with a through hole 1231a so that the needle can move up and down in the direction of the central axis, and the second flow path valve member is provided by the pressing member 1240 installed on top of the second flow path valve member. 2 The driving part is pressed in the closing direction of the toilet seat and provided at a predetermined position of the needle (1131) is configured to drive the second flow path valve member 1230 in the opening direction of the second toilet seat to open and close the second flow path 1222, and the body and an adapter fastened to the upper portion of the body A valve unit provided with a refrigerant passage through which refrigerant is circulated between the back pressure chamber (P1) in which the pressing member 1240 and the second flow valve member 1230 are installed between the 1250 and the first inlet / outlet 1211. (1200).

Therefore, when the needle 1130 of the stepping motor unit 1100 moves in the first movement range, only a certain amount of the first toilet seat 1220a is opened and the refrigerant flow rate during cooling is controlled, and the needle 1130 moves secondly. When moving in the range, while the second toilet seat 1220b is opened, it is possible to control the refrigerant flow rate during heating, while the second flow path valve member 1230 is installed in the back pressure chamber P1 formed by the refrigerant passage. It is easy to move upward by the driving portion 1131 provided on the needle 1130.

Here, the stepping motor part 1100, the guide 1110 with a pin 1111 fitted in the upper part, as well as a press fit into the adapter 1250 fastened to the upper part of the valve part 1200, and the upper part of the guide In the space between the holder 1120 screwed in the central axis direction, the needle 1130 fitted in the central axis direction of the guide and the adapter, and fitted in the central axis direction of the holder, and the space between the upper portion of the needle and the holder A spring 1140 to be fitted, a stopper 1150 fitted to the upper portion of the holder to prevent rotation relative to the holder, and fitted to the upper portion of the holder and tightly attached to the upper portion of the stopper while being prevented from rotating relative to the holder The magnet 1160, the cap 1170 fitted to accommodate the upper portion of the holder together with the upper portion of the needle, and the spring 1180 fitted to the upper portion of the needle to be located above the cap, and the spring ( 11 80) and a sleeve 1190 fixed to the upper portion of the adapter 1250 to accommodate the magnet 1160, and fitted to accommodate the sleeve 1190, and a coil 1191a and a stator 1191b therein. And the mold 1191 molded with the terminal 1191c and the bobbin 1181d accommodated therein, and sandwiched between the body 1210 and the packing 1300 while being inserted into and fused to a protrusion protruding from the bottom of the mold. It consists of a bracket 1192 fixed with a fastening screw 1400.

Therefore, when a signal is supplied to the terminal 1191c of the mold 1191, the magnet 1160 is rotated a certain amount in the clockwise or counterclockwise direction. At this time, the holder 1120 is guided 1110 by rotation of the magnet. ) Is screwed on the inner circumferential surface of the needle 1130 while rotating a certain amount in the clockwise or counterclockwise direction, the needle 1130 moves linearly in a fixed amount in the axial direction d.

In addition, the valve unit 1200 is assembled to the lower portion of the stepping motor unit 1100 and is provided with a first inlet and outlet provided on one side to control the refrigerant flow rate according to cooling and heating according to the movement amount of the needle 1130. A body 1210 in which a first flow path 1213 and a second flow path 1214 are disposed between the 1211 and the second entry / exit 1212 provided on the other side; While being installed between the first inlet and outlet 1211 and the second inlet and outlet 1212 and communicating with the first flow path 1213 and the second flow path 1214, the first flow path is in close contact with the lower end of the needle 1130. A valve body 1220 having a first toilet seat 1220a to open and close, and a second toilet seat 1220b to open and close a second flow path penetrating from the top to the bottom; It is seated on the upper portion of the valve body to open and close the second toilet seat 1220b of the second flow path, and a needle 1130 is formed at the center of the shaft so that the needle 1130 is movable in the axial direction and the needle 1130 is formed. A second flow path valve member 1230 which is pressed upward to be moved upward by a driving portion 1131 installed at a predetermined position of); A pressing member 1240 with one side positioned on the upper surface of the second flow path valve member 1230 and the other side positioned at an adapter; While the outer circumferential surface of the body is fastened so as to be sealed, the receiving groove 1251 is formed to receive the pressing member 1240 while being fastened to the upper portion of the valve body, while the guide 1110 is located at the opposite axis center of the receiving groove. ) Is formed of an adapter 1250 having a guide assembly hole 1252 formed to be pressed.

Reference numerals 1260 and 1270 are O-rings for sealing.

Here, the first movement range of the needle 1130, the wedge-shaped end of the needle 1130 rises in the axial direction in close contact with the first toilet seat 1220a of the valve body 1220, and the driving part ( 1131) refers to the state immediately before being in close contact with the lower surface of the second flow path valve member 1230, and in the second movement range of the needle 1130, the driving part 1131 is the second flow path valve member 1230 ) Refers to the state immediately before the upper surface of the needle contacts the upper part of the sleeve 1190 from the point of contact with the lower surface.

Therefore, as the needle 1130 moves up and down in the axial direction to the first toilet seat 1220a installed in the valve body 1220, the lower end of the wedge shape is closely or dropped, and the opening and closing amount of the first flow path 1213 is adjusted to cool. The second flow path valve member is driven by the driving part 1131 while the needle 1130 rises to control the flow rate of the refrigerant in the city and to flow a large amount of refrigerant when heating from the second inlet and outlet 1212. When the periphery of the through hole 1231a of 1230 is pressed upward, the second flow path valve member 1230 is separated from the second toilet seat 1220b, and the valve body is connected to the second flow path 1212 through the second flow path 1212. Directly through the second flow path 1222 of 1220, a large flow rate passes through the first flow path 1221 of the valve body 1220 to the first flow path 1213 and the first inlet and outlet 1211 of the body 1210. Will move.

In addition, as the valve body 1220, the adapter 1250, and the guide 1110 are assembled, a space in which the second flow path valve member 1230 and the pressing member 1240 are installed is composed of a back pressure chamber P1.

Therefore, the refrigerant entering the first inlet and outlet 1211 is a through hole 1231a which is a refrigerant passage of the first passage 1221 and the second passage valve member 1230 of the valve body 1220 through the first passage 1213. The refrigerant is supplied to the back pressure chamber (P1) through.

On the other hand, the valve body 1220, the first passage 1213 of the body 1210 and the second passage 1214, the lower portion is sealed on the lower outer circumferential surface so that the O-ring 1270 is fitted and seated, this On the upper side where the O-ring is fitted, a first flow path 1221 is formed of a flow path passing through the shaft center at the outer circumferential surface and a driving portion movement flow path formed in an axial direction with a diameter larger than this flow path. A first toilet seat 1220a in which the lower end of the wedge-shaped needle is seated is formed while passing through the lower portion, and a male screw portion formed with the adapter 1250 is formed on the upper outer circumferential surface, and the pressing member 1240 and the upper shaft center are formed. 2 As the flow path valve member 1230 is installed, a back pressure chamber forming groove constituting the back pressure chamber P1 is formed, and at least one second flow path 1222 penetrating downward from the bottom surface of the back pressure chamber forming groove is formed. The second side on the upper surface of the second passage A (1220b) are formed.

Therefore, the lower portion of the valve body 1220 is sealed to be sealed between the first flow path 1213 and the second flow path 1214 of the body 1210 by the O-ring 1270, and to the first flow path 1221. The refrigerant flowing into the first inlet 1211 flows in, and the refrigerant is supplied to the back pressure chamber P1 through the through hole 1231a of the second flow path valve member 1230, and the needle is supplied from the first toilet seat 1220a. When the lower end portion of the 1130 falls to the first movement range, the refrigerant flowing into the first inlet 1211 through the first toilet 1212a through the first toilet seat 1220a, the second flow path 1214 and the second inlet and outlet The refrigerant flows through (1212).

In addition, when the needle 1130 is moved to the second movement range, the driving part 1131 installed on the needle 1130 lifts the second flow path valve member 1230 upward, and the second toilet seat 1220b is opened. A refrigerant having a large flow rate from the inlet / outlet 1212 is supplied to the first flow path 1221 through the second flow path 1222, and the first flow path 1213 having a larger diameter than the outer circumferential surface of the valve body 1220 of the body 1210 Through is moved to the first entrance and exit (1211).

In addition, the second flow path valve member 1230 includes a through-hole 1231a through which a needle 1130 is fitted into the shaft center, a pressing member seating portion 1231b on which a pressing member is seated on an upper surface, and a rubber chamber at a lower portion. It is composed of a valve body cover (1231) provided with a locking projection (1231c), and a rubber chamber (1232) fitted to the lower portion of the valve body cover and in close contact with the second toilet seat (1220b) of the valve body (1220).

Therefore, while the second flow path valve member 1230 moves in the axial direction, the rubber chamber 1322 can be opened and closed while being in close contact with the second toilet seat 1220b, and the needle 1130 is moved upward. When the driving portion 1131 provided on the needle 1130 is in close contact with the periphery of the through hole 1231a, the second flow path valve member 1230 is moved upward to face the elastic force of the pressing member 1240. .

Also, in the present embodiment, the refrigerant passage is formed by a gap with a needle by a through hole 1231a of the valve body cover 1231 constituting the second flow path valve member 1230, but the back pressure chamber (P1) And it may be made of a communication hole (not shown) formed between the first inlet and outlet 1211.

In addition, the driving part 1131 installed on the needle 1130 is made of an E-ring fitted in a groove formed at a predetermined position of the needle in this embodiment, but a protrusion or needle protruding from the outer circumferential surface of the needle 1131 Of course, it can be configured as any one of the steps formed on the outer peripheral surface of the.

The embodiments described above and illustrated in the drawings should not be interpreted as limiting the technical spirit of the present invention. The scope of protection of the present invention is limited only by the items described in the claims, and a person having ordinary knowledge in the technical field of the present invention can improve and modify the technical spirit of the present invention in various forms. Therefore, such improvements and modifications will fall within the protection scope of the present invention if it is apparent to those skilled in the art.

1000: Electronic expansion valve for air conditioning system 1100: Stepping motor unit
1110: guide 1120: holder
1130: needle 1131: driving part
1140: spring 1150: stopper
1160: magnet 1170: cap
1180: spring 1190: sleeve
1191: mold 1192: bracket
1200: valve portion 1210: body
1220: valve body 1230: second flow valve member
1240: pressing member 1250: adapter
1300: Packing 1400: Fastening screw

Claims (5)

A stepping motor unit 1100 having a needle 1130 moving in a linear direction while rotating forward and backward according to the supply of power;
The first inlet 1211 provided on one side and the second inlet 1212 provided on the other side so as to be assembled to the lower portion of the stepping motor and control the refrigerant flow rate according to the amount of needle movement during cooling and heating. While having a body 1210 in which the first flow path 1213 and the second flow path 1214 are juxtaposed,
The first toilet seat 1220a installed in the first flow path controls the refrigerant flow rate during cooling in the first moving range of the needle 1130, and the second toilet seat 1220b installed in the second flow path 1214 is a needle ( Opens and closes the refrigerant passage during heating in the second moving range of 1130),
The second flow path valve member 1230 installed in the second toilet seat is formed with a through hole 1231a so that the needle can move up and down in the central axis direction, and a pressing member 1240 installed on the upper portion of the second flow path valve member ) Is pressed in the closing direction of the second toilet seat, and the driving part 1131 provided at a predetermined position of the needle drives the second flow path valve member 1230 in the opening direction of the second toilet seat, and the second It is configured to open and close the toilet seat 1220b,
Between the body and the adapter 1250 fastened to the upper portion of the body, between the back pressure chamber (P1) and the first inlet and outlet (1211) in which the pressing member (1240) and the second flow path valve member (1230) are installed. An electronic expansion valve for an air-conditioning and cooling system, including; a valve unit 1200 provided with a refrigerant passage through which refrigerant can be distributed. According to claim 1,
The refrigerant passage,
A gap between the needle and the through hole for needle installation of the second flow path valve member,
Electronic expansion valve for an air conditioning system, characterized in that it is one of the communication holes between the back pressure chamber and the first inlet and outlet. According to claim 1,
The driving portion installed on the needle,
An electronic expansion valve for an air-conditioning and heating system, characterized in that it is one of a protrusion projecting on the outer peripheral surface of the needle, a step formed on the outer peripheral surface of the needle, and an E-ring 1131 installed on the outer peripheral surface of the needle. According to claim 1,
The stepping motor unit 1100,
A guide 1110 in which a pin 1111 is fitted in the upper part, as well as a press fit into the adapter 1250 fastened to the upper part of the valve part 1200, and a holder 1120 screwed in the direction of the upper central axis of the guide ), A needle 1130 fitted in the center axis direction of the guide and adapter, and a spring 1140 fitted in a space between the upper part of the needle and the holder, and the holder. A stopper (1150) fitted to the upper portion of the holder and seated against rotation, and a magnet (1160) fitted to the upper portion of the holder and close to the upper portion of the stopper to prevent rotation with respect to the holder, and the needle The cap 1170 fitted to accommodate the upper portion of the holder together with the upper portion, and the spring 1180 fitted to the upper portion of the needle so as to be located above the cap, and the spring 1180 and the magnet 1160 are accommodated. So that The sleeve 1190 fixed to the upper portion of the adapter 1250, and fitted to accommodate the sleeve 1190, there is a coil 1191a, a stator 1191b, a terminal 1191c, and a bobbin 1191d inside. A mold 1191 molded into a state accommodated therein, and a bracket 1192 fixed by a fastening screw 1400 sandwiched between the body 1210 and the packing 1300 while being fused by being inserted into a protrusion protruding below the mold Electronic expansion valve for heating and cooling systems, characterized in that consisting of. According to claim 1,
The valve unit 1200,
In addition to being assembled to the lower portion of the stepping motor part 1100, the first inlet / outlet 1211 provided on one side and the other side provided on one side to control the refrigerant flow rate according to the cooling and heating according to the movement amount of the needle 1130 A body 1210 in which a first flow path 1213 and a second flow path 1214 are disposed between the second entry and exit 1212; While being installed between the first inlet and outlet 1211 and the second inlet and outlet 1212 and communicating with the first flow path 1213 and the second flow path 1214, the first flow path is in close contact with the lower end of the needle 1130. A valve body 1220 having a first toilet seat 1220a to open and close, and a second toilet seat 1220b to open and close a second flow path penetrating from the top to the bottom; It is seated on the upper portion of the valve body to open and close the second toilet seat 1220b of the second flow path, and a needle 1130 is formed at the center of the shaft so that the needle 1130 is movable in the axial direction and the needle 1130 is formed. A second flow path valve member 1230 which is pressed upward to be moved upward by a driving portion 1131 installed at a predetermined position of); A pressing member 1240 with one side positioned on the upper surface of the second flow path valve member 1230 and the other side positioned at an adapter; While the outer circumferential surface is fastened to the upper portion of the body, the receiving groove 1251 is formed to receive the pressing member 1240 while being fastened to the upper portion of the valve body, while the guide 1110 is located at the opposite axis center of the receiving groove. ) An adapter 1250 having a guide assembly hole 1252 formed to be press-fitted; an electronic expansion valve for an air-conditioning and heating system.

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