KR100609017B1 - A combination Structure for an electric expansion valve - Google Patents

Abstract

The present invention relates to a coupling structure of the electric expansion valve, in the electric expansion valve, the yoke of the rotor is screwed on the inner side, the thread is formed on the outer periphery, the lower end is provided with a press-fit portion formed with a multi-stage indentation projection Rotor receiving part; And a valve body connected to a valve chamber having a predetermined space therein and having an opening for flowing in and out of the refrigerant, and having a press-fitted hole having a multi-stage press-fitted groove coupled to the press-fitted portion of the rotor receiving part at an upper end thereof. The receiving part is designed to be separated from the valve chamber and then press-fitted to the valve body.

Electric expansion valve, rotor support, valve body, stator, magnet, yoke

Description

A combination structure for an electric expansion valve             

1 is a cross-sectional view showing the structure of a conventional electric expansion valve.

2 is a cross-sectional view showing a coupling structure of the electric expansion valve as an embodiment of the present invention.

Figure 3 is a cross-sectional view showing in detail the coupling state as an electric expansion valve according to the present invention.

Figure 4 is a cross-sectional view showing the rotor receiving portion in the electric expansion valve according to the present invention.

5 is a cross-sectional view showing the valve body in the electric expansion valve according to the present invention.

♣ Explanation of symbols for main part of drawing ♣

100: case 111: upper case

112: lower case 120: rotor

121: magnet 124: bush

126: washer 127: spring

130: yoke 131, 142: refrigerant outlet

140: rotor support 141: thread

144, 144a: Indentation protrusion 145: Indentation part

150: valve body 151: valve chamber

152, 153: opening 155: orifice

156: indentation hole 157, 157a: indentation groove

The present invention relates to a coupling structure of an electric expansion valve, and more particularly, to a coupling structure of an electric expansion valve that is mounted in a refrigeration cycle such as an air conditioner, a refrigerator, or a heat pump, and used for precise flow rate control of a refrigerant or opening and closing of a flow path. It is about.

A general electric expansion valve is to convert a liquid refrigerant into a gaseous state. As a prior art of such an electric expansion valve, Patent Application No. 2000-523 (name of the invention; electric expansion valve for refrigeration cycle, Applicant; Samsung Electronics Co., Ltd.) Figure 1 (hereinafter, will be described with reference to arbitrarily given reference numerals for convenience). In the valve body, a first opening 19 for connecting the first flow path is provided directly below the axial direction, and at the same time a second opening 18 for connecting the second flow path is provided at the side thereof. The valve chamber 11 is formed so that the 1st opening 19 and the 2nd opening 18 may be connected from above.

And the upper part of the valve body is covered with a case 17, the lower cover is installed from the bottom. Inside the case 17, a magnet is provided on the outer circumference, and a rotor 15 made of a resin material having a magnet provided with a pin is provided at the center thereof, and the rotor 15 moves downward together with the pins therein. It is inserted in the valve chamber 11. A needle 13 is installed at the lower end of the pin, and the side is aligned with the inner wall of the valve chamber 11 so as to be free to rotate on the upper outer periphery of the needle 13, and a guide 11a is provided at the bottom thereof.

A female screw portion of the rotor 15 is formed on the outer circumference of the protrusion 14 (yoke) provided below the rotor 15, and a male screw is provided on the inner wall of the valve chamber 11 facing the male screw portion of the rotor 15. An addition is formed, both of which are screwed together. When the rotor 15 rotates by this, the female threaded part is fixed, so that the screwed-in rotor 15 moves up and down, and the needle 13 integrated with the rotor 15 has a first opening 19. It moves up and down inside to control the flow rate. The upper end of the pin protrudes from the rotor 15 to face the inner side of the upper lid portion of the case 17. On the outer circumference of the rotor 15 and the inner circumference of the magnet, both surfaces face each other in the first cylindrical portion eccentric in the upper portion and the second cylindrical portion in the lower portion thereof, and both of these portions cannot rotate. Are combined. A portion of the lower end of the magnet of the rotor 15 is provided on the outer periphery of the receiving portion of the rotor 15 of the valve body, and a portion thereof is provided downward to form a downward protrusion 14, which is a downward protrusion 14. ) Is capable of contact with the stopper pin 17a fixed to the valve body.

In addition, the upper part of the magnet has an upper protrusion formed upward, and the upper protrusion can contact the upper stopper 17b provided below the outer circumference from the stopper member fixed to the inner circumference of the upper cover of the case 17. have. The coil is fixed to the cylindrical outer periphery of the case 17, and is connected to the outside by the connector.

In the flow-controlled electric control valve by the needle valve configured as described above, the rotor 15 is rotated by the rotation of the magnet by energization to the coil, and the rotor 15 is formed at the protrusion of the rotor 15. The rotor rotates up and down by rotating the female screw and the male screw portion formed on the inner wall of the valve chamber, whereby the needle 13 formed on the pin fixed to the rotor 15 moves up and down. The opening area of the opening 19 is changed to control the flow rate. Rotation of the rotor 15 is caused by the lower projection 14 of the magnet contacting the stopper pin 17c when the needle 13 completely closes the first opening 19, and when the needle 13 is completely opened, The protrusion 14 abuts against the upper stopper 17b of the stopper member 17d so that its rotation is forcibly stopped irrespective of the pulse supply to the stator 16. In the case 17 of the electric expansion valve, a mandrel is fixed to the center of the upper cover part, and a spiral guide ring 17c is wound around it, and the slider is wound on the spiral guide ring 17c at the same time. The movement is freely installed on the rotor 15 of the outer end of the slider.

Thus, in the conventional electric expansion valve, in order to fully open and close the valve, the protrusion part 14 and the recessed part are provided below the rotor 15, and the rotor part of the valve chamber 11 protrudes upwards. And a depression is provided, and a screw portion is formed by screwing the protrusion and the depression. In particular, since the valve chamber 11 and the rotor receiver are integrally processed, the processing is difficult, and the manufacturing process of the component is complicated and cumbersome, and problems related to dimension management and durability occur.

In addition, since the appearance is contaminated after the high frequency welding for coupling the connecting pipe to the first opening and the second opening in the valve chamber, the acid treatment process is performed. There arises a problem that the dimensional change of the screw portion of the electromagnetic receiving portion is generated, thereby lowering the reliability of the electric expansion valve.

According to the present invention for solving the above problems, an object of the present invention is to provide a coupling structure of an electric expansion valve that is designed to be separated from the rotor chamber and the valve chamber by press-fit to the valve body.

In addition, the object of the present invention is to simplify the assembly process by designing the yoke of the rotor in such a manner as to bond to the magnet after processing, and to be screwed to the rotor receiving portion.

In addition, an object of the present invention is to improve the reliability of the assembly process by automating and simplifying the assembly process of the needle coupled to the inside of the yoke of the rotor.

As a means for achieving the above object, the coupling structure of the electric expansion valve according to the present invention in the electric expansion valve,

A rotor receiving part which is screwed with the yoke of the rotor inside, a thread is formed on the outer circumference, and has a press-fitting part having a multi-stage indentation protrusion at the bottom thereof; And

An opening is formed to be connected to a valve chamber having a predetermined space therein, and an opening for flowing in and out of the refrigerant is formed, and a valve body having a press-fitted hole having a multi-stage press-fitting groove coupled to the press-fitting portion of the rotor receiver is formed at the top. have.

Hereinafter, with reference to the accompanying drawings will be described in detail the coupling structure of the electric expansion valve as an embodiment according to the present invention.

2 is a cross-sectional view showing a coupling structure of the electric expansion valve as an embodiment of the present invention, Figure 3 is a cross-sectional view showing in detail the coupling state as the electric expansion valve.

The electric expansion valve proposed in the present invention is to control the flow rate of the fluid, in particular the refrigerant, the coil is wound around the stator 200, and the inside of the stator is covered with a case 100 and includes a magnet and yoke The rotor 120, the rotor receiving portion 140 for supporting the rotation of the rotor, and the valve body 150 is provided with an opening and a valve chamber for the refrigerant flows out and has a combined structure.

Furthermore, the electric expansion valve of the present invention proposes a structure in which the rotor receiver 140, which is screwed to the yoke 130 of the rotor 120, is coupled to the valve body 150.

The rotor receiving portion 140 is screwed into the yoke 130 of the rotor 120 on the inside, the thread 141 is formed on the outer periphery, the multi-stage indentation protrusions (144, 144a) formed at the bottom An indentation portion 145 is provided (see FIG. 4).

It is preferable that a plurality of indentation protrusions 144 and 144a are formed on the outer circumference of the indentation part 145 according to the degree of protrusion.

The valve body 150 has openings 152 and 153 which are connected to the valve chamber 151 having a predetermined space therein and flow in and out of the refrigerant, and the press-fitting portion 145 of the rotor receiving part 140 at the upper end thereof. ) Is provided with a press-fitting hole 156 having a plurality of press-fitting grooves 157 and 157a coupled thereto.

In addition, a plurality of indentation grooves 157 are formed at the inner circumference of the indentation hole 156 by being press-fitted with the indentation protrusions 144 and 144a of the indentation part 145 formed in the rotor receiving part 140. 157a) is preferably formed (see FIG. 5).

The indentation grooves 157 and 157a are formed in multiple stages in the indentation protrusions 144 and 144a of the rotor receiving part 140 and the indentation hole 156 of the valve body 150 from the rotor of the valve body 150. The receiving unit 140 is intended to be firmly fixed without being easily separated. The surfaces of the indentation protrusions 144 and 144a and the indentation grooves 157 and 157a are preferably hard plated to maintain durability after being indented and indented.

A coolant outlet inlet 142 is formed at a lower end of the rotor receiver 140 to allow the coolant and the foreign matter contained in the coolant to flow in and out. That is, when the refrigerant flows in and out through the valve chamber 151 through the openings 152 and 153, the foreign matter contained in the refrigerant is screwed into the rotor receiving part 140 coupled to the valve body 150. 130 or the yoke 130 and the needle 149, etc. are introduced to prevent clogging or jamming. Furthermore, a coolant outlet inlet 131 is formed at one side of the yoke 130 to allow the coolant and the foreign matter contained in the coolant to flow in and out.

The yoke 130 is bonded and fixed to the inside of the magnet 121, the needle 149 is coupled to the inside of the yoke 130 by the bush 124, the washer 126 and the spring 127, the magnet ( As the yoke 130 moves up and down from the rotor receiving unit 140 by the forward and reverse rotation of 121, one end of the needle 149 opens and closes the orifice 155 formed in the valve chamber 151 to adjust the flow rate of the refrigerant. .

The needle 149 is provided inside the yoke 130 that is bonded to the magnet 121 of the rotor 120, and the cylindrical bush 124 magnet 121 when assembling the needle 149 and the yoke 130. ) Is pressed into one end of the needle 149 to be coupled to the inside. The bush 124 prevents the needle 149 from escaping from the magnet 121. And the needle 149 is coupled to the yoke 130, the spring 127 is installed to maintain a constant pressing force, the washer 126 is assembled integrally for the smooth operation of the spring 127.

In addition, in the electric expansion valve of the present invention, the rotor receiving part 140 on the upper end of the valve body 150 is press-fitted and fixed by the indentation protrusions 144 and 144a and the indentation grooves 157 and 157a formed in multiple stages, The yoke 130 having the needle 149 installed therein is screwed into the rotor receiving part 140, and the yoke 130 has a structure fixed by being compressed with the magnet 121. In addition, the upper end of the valve body 150 is provided with a case 100 covering the rotor 120, that is, the upper case 111 and the lower case 112, respectively, coupled and fixed by welding or the like. The outer periphery of the case 100 is provided with a stator 200 and a fixing means 160 for fixing.

While the invention has been shown and described in connection with specific embodiments thereof, it is well known in the art that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the claims. Anyone who has a can easily know.

According to the present invention as described above, in order to secure the rotor receiving portion to the valve body in the electric expansion valve by pressing the multi-stepped indentation projection in the indentation portion of the rotor receiving portion multi-stage press-in groove into the press-in hole of the rotor receiving portion By combining, more firm fixing and assembly are achieved. In addition, the assembly of the rotor receiver and the yoke of the rotor are screwed together to simplify the assembly process. This improves the precision of the parts processing of the electric expansion valve and facilitates the dimensional management. Increasing the properties has the effect of improving the reliability of the electric expansion valve.

Claims (3)

In the electric expansion valve, The inner screw is coupled to the yoke 130 of the rotor 120, the screw thread 141 is formed on the outer periphery, the lower end is provided with a press-fit portion 145 having a multi-stage press-fit projections (144, 144a) Electronic receiving unit 140; And Openings 152 and 153 connected to the valve chamber 151 having a predetermined space therein are formed to flow in and out of the refrigerant, and are coupled to the press-fitting portion 145 of the rotor receiving part 140 at an upper end thereof. A valve body 150 having a press-fit hole 156 having press-fit grooves 157 and 157a formed therein; Coupling structure of the electric expansion valve, characterized in that consisting of. The method of claim 1, Refrigerant and coupling structure of the electric expansion valve, characterized in that the coolant outlet inlet 142 is formed in the lower end of the rotor receiving unit 140 and the foreign matter contained in the refrigerant flows in and out. The method of claim 1, The yoke 130 is bonded and fixed to the inside of the magnet 121, the needle 149 is coupled to the inside of the yoke 130 by the bush 124, the washer 126 and the spring 127, the magnet ( As the yoke 130 moves up and down from the rotor receiver 140 by the forward and reverse rotation of 121, one end of the needle 149 opens and closes the orifice 155 formed in the valve chamber 151 to adjust the flow rate of the refrigerant. Coupling structure of the electric expansion valve, characterized in that.

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