KR100717382B1 - Solenoid valve - Google Patents

Abstract

The present invention relates to a solenoid valve, and more particularly to a solenoid valve having a structure characterized in that the supply of power is required only when the valve is opened and closed. Disclosed is a structure of a solenoid valve including a mechanical holding means composed of a combination of a guide groove formed and a groove fastening means (eg, a sphere) engaged with the guide groove, whereby the opening and closing operation of the valve is applied to the generation of a magnetic field through power supply. And the maintenance of the open / closed state of the valve is mechanically carried out by the holding means, whereby continuous supply of power is not fundamentally required, thereby causing breakage of the coils and consequently caused by continuous supply of power. It is possible to prevent the risk of fire, and furthermore, Because to be able to operate with only a much smaller amount of power compared to the conventional valve can be driven.

Solenoid valve, retaining means, guide groove, sphere, groove fastening means, stator, mover, disc, stem, stem guide

Description

Solenoid Valve

1 is a cross-sectional view showing an example of a conventional solenoid valve;

2 is a graph showing an operating state of a general valve;

3 is a graph showing a state of power supplied to the solenoid valve of FIG.

4 is a cross-sectional view showing a solenoid valve according to an embodiment of the present invention;

5A is an exploded view showing the shape of the guide groove in the stem guide of FIG. 4 in a plan view;

FIG. 5B is a cross-sectional view illustrating a state taken along a line A-A of FIG. 4; FIG.

6a to 6c sequentially show the operating state of the solenoid valve of FIG. And

7 is a graph illustrating a state of power supplied to the solenoid valve of FIG. 4.

<Description of Symbols for Main Parts of Drawings>

200, 200a, 200b, 200c: solenoid valve

110: body 112: inlet

114: outlet 116: sheet

120: disk 122: contact surface

124: disk pin 130: stem

132: end 134: sphere support groove

140: stem guide 142: guide holder

144: upper guide 144a: lower surface of the upper guide

144b: upper vertex 146: lower guide

146a: upper surface of the lower guide 146b: lower vertex

148a and 148b: leading slope 150: stem driving means

152: mover 154: stator

156: coil 158: frame

162: nut 164: spring washer

166: upper frame washer 168: lower frame washer

170: guide groove 180: sphere

190: holding means

B: Fixing bolt O: O-Ring

S: elastic means P1: first position

P2: second position P3: third position

h1-h7: the location of the sphere

The present invention relates to a solenoid valve, and more particularly to a solenoid valve having a structure characterized in that the supply of power is required only when opening and closing the valve.

The valve widely used as a means for opening and closing the flow of the fluid may be configured in various forms, in particular, the valve of the type that drives the opening and closing of the valve using a magnetic field generated by the supply of power is called a solenoid valve.

These solenoid valves can be remotely controlled, simple to use, and have a fast reaction speed (operating speed), which is mainly used in pneumatic or hydraulic systems, and controls various control conditions (water level, temperature, pressure, etc.) of the fluid flowing into the pipe. Used to do so.

Hereinafter, with reference to the accompanying drawings, look at the structure and operation principle of the solenoid valve according to a conventional example as follows.

1 is a cross-sectional view showing an example of a conventional solenoid valve, FIG. 2 is a graph showing an operating state of a general valve, and FIG. 3 is a graph showing a state of power supplied to the solenoid valve of FIG.

As shown in FIG. 1, the conventional solenoid valve 100 includes a body 10 in which a flow path connecting the inlet 12 and the outlet 14 is formed, and one point of the flow path (for example, the seat part 16). The disk 20 for opening and closing the flow path in the), the stem 30 is fastened to the disk and the end 32 is protruded through the body at one side of the body, and the stem formed in the through portion of the stem to support the stem The guide 40, the elastic means S for urging the disk to the closed position (the seat portion direction) of the flow path, and the end portion 32 of the stem are formed on one side of the protruding body, and the stem is supplied by power supply. It comprises a stem driving means 50 for driving in the direction opposite to the pressing direction of the elastic means.

The stem drive means 50 includes a mover 52 coupled to an end 32 of the stem, a stator 54 corresponding to the mover, and a coil for driving the mover to the stator side by generating a magnetic field by supplying power ( 56, and a frame 58 that encloses and accommodates these movers, stators, and coils.

In addition, the O-ring (O) is generally interposed between the frame 58 and the body 10 of the stem driving means 50.

In the solenoid valve of the above structure, the disk staying in the closed position by the pressurizing of the elastic means, the mover moves to the stator side by the magnetic field generated by the supply of power, the stem and the disk fastened together with the mover The valve is driven in an open manner by being driven to an open position. Then, when the valve is to be closed, the disk is restored to the closed position again by pressing by the elastic means by stopping the supply of power.

The solenoid valve 100 of such a structure can be used to adjust the control conditions (temperature, pressure, water level, etc.) of the fluid to a desired set value as shown in FIG. For example, the valve is opened when the control condition of the fluid reaches the minimum value of the set point, and the valve is closed when the control condition reaches the maximum value of the set point, and then the opening and closing of the valve are controlled by the control condition of the fluid. By repeated implementation, the fluid can be adjusted appropriately.

However, in order to control the fluid as described above, there was a inconvenience in that power must be continuously supplied to the solenoid valve, specifically, the coil of the stem driving means while the valve is opened. For example, as shown in FIG. 3, during the opening of the valve, 125 DCV power is continuously supplied to maintain the magnetic field in the coil so that the valve can be kept open.

As such, in the conventional solenoid valve, the power supply must be continuously maintained when the valve is driven (for example, the valve is opened), which causes the following problems. For example, when the power is continuously supplied for a long time, the electric heat generated by the resistance is generated in the coil to which the power is supplied, and the generated heat is not properly radiated, and thus the coil may burn out. In addition, if the coil burns out, the solenoid valve itself becomes inoperable, and a problem may occur that results in a fire caused by a surrounding material (eg, a ignitable substance and a volatile substance) exposed at the point where the solenoid valve is installed.

In addition, there is a problem that the amount of power consumed for the operation of the valve is greatly required because the supply of power must be made to continuously open the valve.

The present invention is to provide a solenoid valve having a structure that can be driven without a continuous supply of power.

The present invention also provides a solenoid valve in a manner in which power supply is required only when opening and closing the valve.

In order to achieve this object, the present invention and the body is formed with a flow path connecting the inlet and outlet; A disk for opening and closing the flow path at one point of the flow path; A stem which is engaged with the disk and whose end portion protrudes through the body at one side of the body; A stem guide formed at a through portion of the stem to support the stem; Elastic means interposed between the stem guide and the disk to press the disk to a closed position of the flow path; An end portion of the stem formed on one side of the protruding body, the stem driving means driving the stem in a direction opposite to the pressing direction of the elastic means by supply of power; A retaining means composed of a guide groove having a predetermined shape formed along the circumferential direction of the stem on the inner surface of the stem guide, and a groove fastening means that is engaged with the guide groove and driven along the guide groove. It provides a structure of a solenoid valve, characterized in that the driving state of the stem is mechanically held by the holding means.

In the present invention, the top apex of the guide groove corresponds to a first position at which the stem is driven by the stem driving means, and the bottom apex of the guide groove is a second position where the disc opens the flow path and a disc closes the flow path. Corresponding to the three positions alternately, the guide groove is formed in a zigzag manner of the first position-> the second position-> the first position-> the third position along the circumference of the stem.

In addition, in the present invention, the guide groove is formed by repeating a plurality of forms connected to the first position-> second position-> first position-> third position, and the groove fastening means is a series of repeats It is characterized by being formed corresponding to the number of times.

Further, in the present invention, the lower end corresponding to the upper end of the guide groove and the upper end corresponding to the lower end are respectively formed to form a preceding inclined surface preceding the corresponding vertex, and the groove fastening means is guided in one direction by the preceding inclined surfaces. It is characterized by.

Also in the present invention, the groove fastening means is a sphere, characterized in that the sphere is interposed between the sphere support groove formed along the circumference perpendicular to the center axis of the stem and the guide groove of the inner surface of the stem guide.

In addition, in the present invention, the sphere is driven along the guide groove, characterized in that to guide the disk coupled to the stem by the contact with the sphere support groove sequentially to the open position and the closed position.

In addition, in the present invention, the stem guide is formed of a guide holder engaged with the body and a pair of upper and lower guides inserted into the guide holder and engaged with the stem, and the lower surface of the upper guide and the upper surface of the lower guide have a predetermined distance. The spacing is formed spaced apart from each other is characterized in that the configuration of the guide groove.

Also in the present invention, the stem drive means includes: a mover engaged with an end of the stem protruding through the body; A stator disposed corresponding to the mover; A coil for generating a magnetic field by the supply of power to move the mover to the stator side; And a frame which is fastened to the body and in which a mover, a stator, and a coil are embedded.

Hereinafter, with reference to the accompanying drawings will be described the structure and operating principle of the solenoid valve according to a preferred embodiment of the present invention.

Figure 4 is a cross-sectional view showing a solenoid valve according to an embodiment of the present invention, Figure 5a is a plan view showing the shape of the guide groove in the stem guide of Figure 4 in a plan view, Figure 5b is along the line AA of Figure 4 It is sectional drawing which shows the cut | disconnected state. The structure of the solenoid valve 200 according to an embodiment of the present invention will be described with reference to FIGS. 4 to 5B as follows.

As shown in FIG. 4, the solenoid valve 200 according to the present invention includes a body 110 in which a flow path connecting the inlet 112 and the outlet 114 is formed, and a point of the flow path (for example, the seat part ( 116)) and the disk 120 for opening and closing the flow path, the stem 130 is fastened to the disk and the end 132 is protruded through the body at one side of the body and formed in the through portion of the stem to support the stem The stem guide 140, the elastic means (S) for pressing the disk to the closed position (sheet portion direction) of the flow path, and the end portion 132 of the stem is formed on one side of the protruding body, by the supply of power It comprises a stem driving means 150 for driving the stem in the direction opposite to the pressing direction of the elastic means.

The stem driving means 150 includes a mover 152 engaged with the end 132 of the stem, a stator 154 corresponding to the mover, and a coil for driving the mover to the stator side by generating a magnetic field by supplying power ( 156, and frames 158 that wrap around and accommodate these movers, stators, and coils.

The upper portion of the stem drive means 150 is fastened to the nut 162 via a spring washer 164, and the upper frame washer 166 and the lower frame washer (upper and lower) of the coil 156 in the frame 150, respectively. 168 may be interposed.

In addition, the O-ring (O) is generally interposed between the frame 158 of the stem driving unit 150 and the engaging portion of the body 110.

Such stem driving means is disclosed as an embodiment of the present invention, but the present invention is not limited thereto. It is apparent that any form of means can be used, for example, which can drive the stem in the opposite direction of the pressing direction of the elastic means via the supply of power.

In addition, the solenoid valve 200 of the present invention is characterized in that it further comprises a holding means 190 of the following structure. The solenoid valve of the present invention may include a guide groove 170 formed on the inner surface of the stem guide 140 and a groove fastening means 180 such as a sphere engaged with the guide groove and driven together with the stem.

For example, in order to form a guide groove on the inner surface of the stem guide 140, the stem guide is fastened at the inner surface of the guide holder 142 and the guide holder 142, which meshes with the body 110, and engages the stem 130. The physics is formed by a pair of upper and lower guides 144 and 146, wherein a predetermined shape (eg, zigzag) is formed between the lower surface 144a of the upper guide 144 and the upper surface 146a of the lower guide 146. The guide groove 170 may be configured by having a gap formed therein. The pair of upper and lower guides 144 and 146 may be fastened in the guide holder 142 and fixed by the fixing bolt B.

The structure of this guide groove is shown more clearly in FIGS. 5A and 5B. Referring to FIG. 5, the guide groove 170 has an upper vertex 144b corresponding to the first position where the stem (ie, the disc) is driven to the maximum by the stem driving means, and the second position where the disc opens the flow path. And lower vertices 146b that alternately correspond to a third position in which the disc closes the flow path, whereby the guide grooves respectively correspond to the first position-> second position-> first position-> third position. It has a series of forms arranged in order of vertices.

That is, when it is described based on the position of the sphere 180 engaged with the guide groove 170, the sphere in the closed state (sphere on the left side of Figure 5a) by the action of the stem drive means (power supply) It moves upward along the guide groove (h1 position), and moves along the inclined surface of the upper guide to the upper peak (h2 position), that is, to the first position (P1). It moves downward (h3 position), and moves along the inclined surface of the lower guide to the lower apex (h4 position), that is, the second position (P2) to keep the valve open. Then, with the valve open, the sphere again moves upward along the guide groove (h5 position) by the action of the stem driving means (power supply), and the top vertex (h6 position) along the inclined surface of the upper guide, i.e., the first After moving to the position P1, when the supply of power is stopped, it moves downward by pressurizing the elastic means (h7 position), and moves along the inclined surface of the lower guide to the lower peak, that is, the third position P3. Is kept closed.

As such, while the sphere 180 moves along the guide groove 170, each of the vertices, in particular, the bottom vertices 146b formed in the lower guide, so that the state of the disk can be maintained mechanically. In particular, such a series of forms can be formed repeatedly, and the sphere can be provided in accordance with the number of repetitions so that the open / close state of the valve can be maintained more stably. In addition, when the valve is moved upward or downward by the force of the stem driving means and the elastic means, the inclined surfaces of the guide grooves corresponding thereto are constituted by the inclined surfaces 148a and 148b which are formed earlier than the apex. Thus, each sphere is able to move sequentially in one direction (for example, the direction of the arrow of Figure 5b).

Although the number of spheres is shown as four in this embodiment, the present invention is not limited thereto, and three or more spheres are preferably applied to stably support the driving of the stem.

Next, referring to Figures 6a to 6c, the operating state of the solenoid valve of the present invention will be described.

FIG. 6A shows the solenoid valve 200a with the power supplied to the stem drive means 150 moving the mover 152 toward the stator 154, with the disk 120 in the first position P1. 6B shows that the disk 120 is held in the open position, that is, the second position P2 by the mechanical action of the holding means (the process of moving the sphere along the guide groove) after the supply of power is stopped. The solenoid valve 200b in a state is shown, and FIG. 6C shows the solenoid valve 200c in a state where the disk 120 is again maintained at the closed position, that is, the third position P3, through FIG. 6A.

Thus, the solenoid valve according to the present invention has a feature that the power supply is made only when opening and closing the valve as shown in FIG. For example, the valve can be operated in such a way that 125 DCV of power is temporarily supplied to open the valve and then stopped, and then 125 DCV is temporarily supplied to power to close the valve.

For reference, in the present embodiment, the power supplied is disclosed as 125 DCV, but this is described as an example, and it is obvious that the present invention is not limited thereto. For example, power sources of various voltages, such as 24 DCV supplied to homes, can be used.

As described above, unlike the conventional case, the solenoid valve according to the present invention does not continuously supply power while the valve is opened, but only temporarily at the moment for opening or closing the valve. It is characterized in that the state of the valve by supplying to change the state of the valve and then by the mechanical holding means using the engagement of the guide groove and the sphere (groove fastening means).

As described above, the solenoid valve according to the present invention, the opening and closing operation of the valve by the magnetic field generation through the power supply, and the maintenance of the opening and closing state of the valve is mechanical maintenance by the engagement of the guide groove and the sphere (groove fastening means) Characterized by the means. Therefore, the solenoid valve according to the present invention does not basically require continuous supply of power, thereby preventing the damage of the coil and the risk of fire caused by the continuous supply of power, and thus the instantaneous power supply. Since the valve can be operated only by supply, the valve can be driven with a much smaller amount of power than in the related art.

Claims (8)

A body having a flow path connecting the inlet and the outlet; A disk for opening and closing the flow path at one point of the flow path; A stem which is engaged with the disk and whose end portion protrudes through the body at one side of the body; A stem guide formed at a through portion of the stem to support the stem; Elastic means interposed between the stem guide and the disk to press the disk to a closed position of the flow path; An end portion of the stem formed on one side of the protruding body, the stem driving means driving the stem in a direction opposite to the pressing direction of the elastic means by supply of power; A holding means composed of a guide groove having a predetermined shape formed along the circumferential direction of the stem on the inner surface of the stem guide, and a groove fastening means engaged with the guide groove and driven along the guide groove with the stem; And a driving state of the stem by the power supply is mechanically maintained by the holding means, the groove fastening means is a sphere, and the sphere is a sphere support groove formed along a circumference perpendicular to the central axis of the stem. Solenoid valve, characterized in that interposed between the guide groove. The upper end of the guide groove corresponds to a first position in which the stem is driven by the stem driving means, and the lower end of the guide groove is a second position in which the disk opens the flow path, and The disks alternately correspond to the third position of closing the flow path, so that the guide groove is formed in a zigzag manner of first position-> second position-> first position-> third position along the circumference of the stem. Solenoid valve, characterized in that. The method of claim 2, wherein the guide groove is formed by repeating a plurality of forms connected to the first position-> second position-> first position-> third position, the groove fastening means is a series of A solenoid valve, characterized in that formed corresponding to the number of repetitions of the form. The method of claim 2, wherein the lower end corresponding to the upper end of the guide groove and the upper end corresponding to the lower end are respectively formed to form a preceding inclined surface preceding the corresponding vertex, the groove fastening means by the preceding inclined surfaces A solenoid valve, characterized in that guided in the direction. delete 2. The solenoid valve according to claim 1, wherein the sphere is driven along the guide groove and sequentially guides the disc engaged with the stem by contact with the sphere support groove to an open position and a closed position. The method of claim 1, wherein the stem guide is formed of a guide holder that is engaged with the body and a pair of upper and lower guides inserted into the guide holder and engaged with the stem, the lower surface of the upper guide and the lower guide A solenoid valve, characterized in that the upper surface is formed by being spaced apart at a predetermined interval to form a guide groove. The method of claim 1, wherein the stem drive means: A mover engaged with an end of the stem protruding through the body; A stator disposed corresponding to the mover; A coil for generating a magnetic field by supply of power to move the mover to the stator side; And Solenoid valve comprising a; is coupled to the body, the frame in which the mover, the stator and the coil is embedded.

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