KR101275733B1 - electronic expansion valve - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic expansion valve, and more particularly, to an electronic expansion valve in which the weight of a part is not only light and the assembly process is simplified.

Electronic expansion valve of the present invention, the motor case 130 fixed to the upper portion of the gear case 110 by the adhesive agent 120, and the pulse motor fixed to the upper portion of the upper plate (140) fixed to the upper portion of the gear case ( First intermediate gear 170 that rotates in engagement with the drive gear 160 is installed in the lower portion of the upper plate to rotate by the operation of 150, and the middle of the middle plate installed at regular intervals in the lower portion of the upper plate to rotate in engagement with the intermediate gear The second intermediate gear 190 installed between the plate 180 and the lower portion of the gear case, the bearing shaft 200 provided at the lower portion of the gear case, and the second intermediate gear are rotated to be screwed to the bearing shaft while rotating. The outlet of the fluid by the needle shaft 212 provided on the output shaft is fastened to the output shaft 210 to be moved up and down and the lock nut 230 rotatably installed via the stopper ring 220 at the bottom of the gear case Valve body with flow path 40) and a fluid discharge pipe 260 fixed in the axial direction of the valve body so that the fluid introduced through the fluid inlet pipe 250 installed at right angles to the axial direction of the valve body is discharged to the opposite side of the output shaft. do.

Gear case, pulse motor, output shaft, needle

Description

Electronic expansion valve {ELECTRONIC EXPANSION VALVE}

1 is a partial longitudinal cross-sectional view of an electronic expansion valve according to an embodiment of the present invention,

2 is a left side view of FIG. 1;

3 is a longitudinal sectional view of an electronic expansion valve according to a first embodiment of the present invention;

4 is a longitudinal sectional view of an electronic expansion valve according to a second embodiment of the present invention;

5 is a cross-sectional view seen from another direction of FIG. 4.

<Brief Description of Drawings>

110 Gear case 120 Adhesive real

130 Motor case 140 Upper plate

150 pulse motor 160 drive gear

170 1st intermediate gear 180 stop plate

190 2nd intermediate gear 200 bearing

210 Output shaft 211 Output gear

212 Needle part 212a Backflow blocker

213 Threaded 220 Stopper Ring

230 Locknut 240 Valve Body

250 Fluid inlet tube 260 Fluid outlet tube

The present invention relates to an electronic expansion valve, and more particularly to an electronic expansion valve used for flow control.

In general, the electronic expansion valve is practically used to control the flow of the fluid by the needle moving up and down while rotating by using the rotational force of the pulse motor.

Conventional electronic expansion valve, as shown in Figure 3, the rotational output of the pulse motor 51 using a reduction gear 52, the flat head screw is supported by the bearing 53 and the screw coupling plate 54 The reduction gear mechanism output shaft 52a is coupled to the shaft 55 in the form of a flat-blade screwdriver to lower and raise the needle valve 57 supported by the bellows 56 by forward and reverse rotation, thereby providing The flow rate is controlled by adjusting the contact surface 58 to open and close.

Such an electronic expansion valve has a problem in that the gear case and the motor case are integrally weighted and difficult to assemble.

In view of this, the proposed electronic expansion valve has a lock nut (1), a stopper ring (2), an output shaft (3), a steel ball (4), a stopper ring (5), as shown in FIGS. Output bearing (6), output gear (7), intermediate gear (8), shaft column (9), intermediate gear (10), motor pinion (11), output force bearing (12), stop plate (13), Upper plate (14), spring pin (15), color (16), gear case (17), motor case (18), motor feed line (19) made of flexible printed cable, protective bush (20), lead wire (21) ), The pulse motor 22, and the actual (23, 24).

That is, the lock nut 1 is fitted to the lower portion of the gear case 17, so that it is not released by the stopper ring (2). Moreover, the tip of the gear case 17 of the engaging portion is a knife edge, and the knife edge is hermetically bonded to the needle by fixing the lock nut 1.

Therefore, the assembly cost is reduced only by sequentially inserting reduction gears and fingerboards in the assembly, and since the gear case 17 and the motor case 18 are separated, the bottom of the gear case 17 is shallow. It is easy to assemble, and it is advantageous in terms of cost and small size.

In addition, the defect can be reduced by sealing on the ring of the gear case 17 and the motor case 18, and since a flexible printed cable is used for the motor feed line 190, the pulse motor (or 22 may be seated and the motor case 18 may be seated in a sealed state.

However, such an electronic expansion valve has a drawback in that the gear case 17 is manufactured by die casting, and the motor case 18 is also made of metal, which is heavy and of course expensive.

In addition, the valve 57 and the steel ball 4 is manufactured separately from the screw shaft 55 and the output shaft 3 which are rotated by the pulse motors (51, 22), so that manufacturing and parts assembly processes are unnecessary. There is this.

The present invention has been made to solve the conventional problems as described above, by manufacturing the gear case and the motor case by injection molding not only the light weight, but also the low manufacturing cost, the electrical leakage of the pulse motor It is a first object to provide an electronic expansion valve that is not caused in advance.

The present invention has a second object to provide an electronic expansion valve that is provided with a needle portion for selectively sealing the flow path in the output shaft that is rotated by receiving the rotational force of the pulse motor does not require a separate assembly process during manufacturing.

An electronic expansion valve of the present invention for achieving the above object, the gear case, the motor case fixed to the upper portion of the gear case actually bonded, the upper plate fixed to the upper portion of the gear case, the upper portion of the upper plate A pulse motor fixed to the motor, a drive gear installed at the lower portion of the upper plate to rotate by the operation of the pulse motor, a first intermediate gear that rotates in engagement with the drive gear, and the upper gear that rotates in engagement with the intermediate gear. A second intermediate gear provided between a stop plate provided at a lower portion of the fingerboard and a lower portion of the gear case, a bearing support shaft provided at a lower portion of the gear case, and the bearing bearing shaft being rotated in engagement with the second intermediate gear. An output shaft configured to move up and down by screwing in the upper and lower parts of the gear case, and a lock nut rotatably installed through the stopper ring; A valve body having a flow path which is fastened to the lock nut to close the outlet of the fluid by the needle part provided at the output shaft, and a fluid inlet pipe installed at a predetermined position of the valve body at right angles to the axial direction of the valve body; It characterized in that it comprises a fluid discharge pipe fixed in the axial direction of the valve body so that the fluid introduced through the fluid inlet pipe is discharged to the opposite side of the output shaft.

In the electronic expansion valve of the present invention, the gear case and the motor case are injection-molded with excellent insulation plastic, and one end of the output shaft to selectively block the flow of fluid to the other end and the output gear meshed with the second intermediate gear. An integrally formed needle portion and a screw portion screwed with the bearing shaft between the output gear and the needle portion are integrally provided.

In the electronic expansion valve of the present invention, the needle portion has a predetermined length of the reverse flow blocking portion which is in close contact with the inner surface of the valve body while moving up and down so that the fluid flowing into the valve body through the fluid inlet pipe does not flow backward toward the lock nut. Characterized in that provided.

Hereinafter, with reference to the accompanying drawings will be described an electronic expansion valve according to a preferred embodiment of the present invention.

1 is a partial longitudinal cross-sectional view of an electronic expansion valve according to an embodiment of the present invention, Figure 2 is a left side view of FIG.

1 and 2, the electronic expansion valve of the present invention includes a gear case 110, a motor case 130 fixed to an upper portion of the gear case by an adhesive agent 120, and an upper portion of the gear case. The upper plate 140 fixed to the upper plate, a pulse motor 150 fixed to the upper portion of the upper plate, a drive gear 160 installed below the upper plate to rotate by the operation of the pulse motor, and A first intermediate gear 170 that rotates in engagement with the drive gear, and a second intermediate gear installed between the stop plate 180 provided at a lower distance from the upper plate to rotate in engagement with the intermediate gear and the lower portion of the gear case. 190, the bearing shaft 200 provided in the lower portion of the gear case, the output shaft 210 to move up and down by screwing to the bearing shaft while rotating in engagement with the second intermediate gear, the gear Stopper ring 220 at the bottom of the case The open-circuit comprises a rotatably installed lock nut 230.

Here, the gear case 110 and the motor case 130 are molded in plastic by injection molding, so the weight is light, and the manufacturing cost is also low. The gear case 110 and the motor case 130 are made of plastic. Since the insulation is excellent, it is possible to operate the pulse motor 150 stably.

And a valve body 240 fastened to the lock nut 230 so as to close the outlet of the fluid by the needle part 212 described later provided on the output shaft 210, and a predetermined position of the valve body. The fluid inlet pipe 250 installed at right angles to the axial direction of the valve body 240 and the fluid fixed in the axial direction of the valve body such that the fluid introduced through the fluid inlet pipe is discharged to the opposite side of the output shaft 210. The discharge pipe 260 is included.

Therefore, the valve body 240 and the fluid inlet pipe 250 and the fluid discharge pipe 260 are easily separated from the gear case 110 and the lock nut 230 so that the valve body 240 and the fluid inlet pipe 250 can be easily separated. And when the fluid discharge pipe 260 is clogged or sounds are easy to repair.

Here, at one end of the output shaft 210, an output gear 211 engaged with the second intermediate gear, a needle portion 212 integrally formed to selectively block flow of fluid at the other end, and between the output gear and the needle portion. Is provided with a screw portion 213 that is screwed with the bearing shaft 200.

Therefore, since the needle part 212 is integrally formed on the output shaft 210, a process that needs to be assembled separately is not necessary, and assembly is simple.

In addition, the valve body 240 is in close contact with the needle portion 212 is provided with a needle contact surface 241 to block the fluid from being discharged to the fluid discharge pipe 260.

On the other hand, the needle portion 212 is in close contact with the inner surface of the valve body 240 while moving up and down so that the fluid introduced into the valve body 240 through the fluid inlet pipe 250 does not flow back toward the lock nut 230. The reverse flow blocking part 212a of a predetermined length is provided.

Therefore, when the pulse motor 150 operates, the driving gear 160 rotates to rotate the first and second intermediate gears 170 and 190, and the output gear 211 of the output shaft 210 meshed with the second intermediate gear is rotated. While rotating, the output shaft 210 is synchronously rotated. In this case, the output shaft is screwed to the bearing shaft 200 so that the output shaft 210 is lowered up and down by the forward and reverse rotation of the pulse motor 150, the needle portion when the output shaft 210 descends When the 212 is in close contact with the needle contact surface 241 of the valve body 240, the fluid introduced into the valve body 240 through the fluid inlet pipe 250 may not be discharged to the fluid discharge pipe 260. do.

An embodiment of the present invention described above and illustrated in the drawings should not be construed as limiting the technical spirit of the present invention. The scope of protection of the present invention is limited only by the matters described in the claims, and those skilled in the art will be able to modify the technical idea of the present invention in various forms. Accordingly, such improvements and modifications will fall within the scope of the present invention as long as they are obvious to those skilled in the art.

As described above, according to the present invention, the gear case and the motor case are manufactured by injection molding, so that the weight is not only light, the manufacturing cost is low, and the electrical leakage of the pulse motor can be generated in advance.

According to the present invention, the needle portion for selectively sealing the flow path is formed on the output shaft to receive the rotational force of the pulse motor, there is an effect that no separate assembly process is required during manufacturing.

Claims (3)

A gear case 110, a motor case 130 fixed to the upper part of the gear case with an adhesive agent 120, a upper plate 140 fixed to an upper portion of the gear case, and a fixed upper part of the upper plate. A pulse motor 150, a drive gear 160 provided at a lower portion of the upper plate to rotate by operation of the pulse motor, a first intermediate gear 170 that rotates in engagement with the drive gear, and the intermediate gear. And a second intermediate gear 190 installed between the stop plate 180 and a lower portion of the gear case provided at regular intervals at a lower portion of the upper plate to rotate in engagement with the upper support plate, and a support shaft 200 provided at the lower portion of the gear case. And an output shaft 210 which is engaged with the second intermediate gear and rotates up and down by screwing to the bearing shaft, and a lock nut rotatably installed at a lower portion of the gear case via a stopper ring 220. 230 and a sieve to the lock nut 230 And a valve body 240 having a flow path in which the outlet of the fluid is closed by the needle part 212 provided in the output shaft 210, and perpendicular to the axial direction of the valve body 240 at a predetermined position of the valve body. And an fluid inlet pipe (250) installed at the valve and a fluid outlet pipe (260) fixed in the axial direction of the valve body such that the fluid introduced through the fluid inlet pipe is discharged to the opposite side of the output shaft (210). The method of claim 1, The gear case 110 and the motor case 130 are injection molded from a plastic having excellent insulation, At one end of the output shaft 210, an output gear 211 engaged with the second intermediate gear, a needle portion 212 integrally formed to selectively block the flow of fluid at the other end, and between the output gear and the needle portion Electronic expansion valve, characterized in that provided integrally with the screw portion 213 is screwed to the bearing shaft (200). The method according to claim 1 or 2, The needle portion 212 is in close contact with the inner surface of the valve body 240 while moving up and down so that the fluid introduced into the valve body 240 through the fluid inlet pipe 250 does not flow back toward the lock nut 230. Electronic expansion valve, characterized in that provided with a predetermined length of the reverse flow block (212a).

Images