KR930006882B1 - Solenoid valve - Google Patents

Abstract

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Description

Solenoid valve

1 is a cross-sectional view of a solenoid valve of the prior art.

2 is a sectional view of the solenoid valve of FIG. 1 with the plunger inclined toward the guide road.

3 is a cross-sectional view of the first embodiment of the present invention.

4 is a sectional view of principal parts of the first embodiment.

5 is an electric circuit having a first solenoid and a second solenoid of a first embodiment.

6 is a sectional view of a second embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

14: first solenoid 15: second solenoid

25 valve body 102 passage

103 housing 110: plunger

111: bottom wall 112: cylindrical side wall

113,114: annular rib 120: core

124: support member 126: annular groove

130 contact member 131 spacer

141: to the first 142: to the second

The present invention relates to a solenoid valve for opening and closing a passage to block or distribute the flow of fuel gas to a domestic gas device such as a gas water heater. In general, when the solenoid valve is open, the amount of current applied to the solenoid of the solenoid valve is smaller than the amount of current applied when the solenoid valve in the closed state is opened. Nevertheless, if a magnetic leak occurs in the gap between the excited core and the armature, the solenoid valve will remain open even if the solenoid valve is open. The amount of current required is greater than the amount of current desired.

The present inventors have an auxiliary solenoid in addition to a normal solenoid to generate magnetic flux in a fully closed magnetic path in Japanese Patent Application No. 64-17075 so that only a small current is required for the solenoid valve to remain open. A solenoid valve is proposed.

1 and 2 show the structure of the proposed solenoid valve. In the drawing, a core 10 made of a conventional magnetic soft-alloy includes a column portion 11, a flange portion 12 formed at one end of the column portion 11, and a column portion 11. It holds the support part 13 formed in the other end.

The first solenoid 14 is provided adjacent to the column portion 11, and the second solenoid 15 is located in an annular groove 16 formed on the outer end surface of the support 13. The guide rod 17 is connected to the center of the bottom wall 21 of the comb-type plunger or the armature 20 by a soldering iron 19 so as to be slidably supported by the guide hole 18 formed in the shaft portion of the core 10. Is inserted as possible. The valve body 25 is provided at the end of the guide rod 17 and is biased by the spring 26 in a direction for closing the passage (not shown).

As shown in FIG. 1, since a current is applied to the solenoids 14 and 15 so that the plunger 20 is attracted by the core 10, the valve body 25 is opened against the elastic force of the spring 26. do. That is, since the inner surface of the bottom wall 21 is in contact with the outer end surface of the support portion 13, an annular space 22 is formed between the lower peripheral portion 23 and the flanger portion 12.

The solenoid valve is operated as follows.

When the valve body 25 is positioned upward in the figure, that is, when the passage is closed, the inner surface of the bottom wall 21 is separated from the end surface of the support portion 13, and the lower peripheral portion 23 and the flange portion (of the plunger 20) ( 12) are separated from each other widely. Therefore, in order to open the valve body 25, a large current is applied to the first solenoid 14 so that the plunger 20 is attracted toward the core 10, and after the valve body 25 is opened, the valve In order to keep the sieve 25 open, a small current is applied to the second solenoid 15 and the application of the current to the first solenoid 14 is stopped. That is, the valve body 25 is kept open by a small electric current. The current may be applied to the first and second solenoids 14 and 15 at the same time to open the valve, and after the valve body 25 is opened, the application of the current to the first solenoid 14 may be stopped. have. Therefore, the magnetic path generated by applying current to the second solenoid 15 is formed of a magnetic circuit completely closed through the bottom wall 21 and the support part 13, thereby keeping the valve body 25 in an open state. To this end, the amount of current applied to the second solenoid 15 is reduced. However, the solenoid valve having the novel structure has the following problems. When the guide rod 17 is fixed to the plunger 20 by soldering 19 inclined to the axis of the plunger 20, as shown in FIG. 2, the entire surface of the inner surface of the bottom wall 21 is supported by the support 13. Since the end face is not in contact with, the large amount of current must be applied to the second solenoid 15 to keep the valve open after the valve is opened.

Similarly, if the attracting force generated in the lower peripheral portion 23 to attract the lower peripheral portion 23 to the center of the core 10 is not the same over the entire circumference of the peripheral portion 23, the solder 19 is burnt. Since it is deformed sexually and the plunger 20 can be inclined with respect to the guide rod 17, the entire surface of the inner surface of the bottom wall 21 does not contact the end surface of the support 13. Moreover, if the attraction force generated in the lower periphery 23 to attract the lower periphery 23 to the center of the core 10 is not the same over the entire circumference of the periphery 23, the guide rod 17 guides the guide hole 18. The lower end of the rod 17 is in contact with the inner surface of the guide hole 18, the guide rod 17 is not guided smoothly by the guide hole 18, the smoothness of the plunger 20 No operation is obtained.

In addition, when the plunger 20 is inclined by an unbalanced force, since a part of the peripheral portion 23 is connected to the flange portion 12, the downward movement of the plunger 20 is hindered.

The magnetic flux 28 generated by applying a current to the first solenoid 14 and the magnetic flux 29 generated by applying a current to the second solenoid 15 pass through the bottom wall 21 and the valve is in a closed state. When opened at, a high current having a high magnetization-intensity is applied to the first solenoid 14. Therefore, since the plunger 20 is attracted to the core 10 even after the current applied to the second solenoid 15 is blocked by the residual magnetism present in the bottom wall 21 after the current is interrupted, the valve The closing operation of the machine is delayed. This delay may be caused by the residual magnetism of the bottom wall 21 generated by applying current to the second solenoid 15. Therefore, it is an object of the present invention to provide a solenoid valve in which the amount of current applied to the second solenoid to keep the valve open is less than the amount of current required in the conventional valve.

Another object of the present invention is to provide a solenoid valve in which the plunger smoothly moves up and down with respect to the core.

Yet another object of the present invention is to provide a solenoid valve in which the valve is closed with little delay from the open state.

According to the present invention, a solenoid valve includes a valve body for opening and closing a passage, a housing, and a plunger and a plunger connected to the valve body for moving the valve body so as to be movable in the housing to open and close the passage. Between a core installed in the core, a support member connected to the core and disposed near the bottom wall of the plunger, a contact member positioned in the plunger and connected to the plunger and inclined with respect to the bottom wall so as to be in close contact with the support member. It consists of a spacer installed to form a space in the. The plunger has a cup-shaped bottom wall and a cylindrical shaft wall. The core, the plunger and the cylindrical side wall form a first path. The support member is provided with a second solenoid to which a current lower than that applied to the first solenoid is applied. The contact member and the support member form a second path. Since the housing is provided with an annular rib formed on the inner wall thereof, the outer surface of the cylindrical inner wall of the plunger is guided by the annular rib to ensure that the plunger moves along its central axis. The contact member and the support member may be made of a magnetic material having low residual magnetic, such as permalloy.

Hereinafter, the present invention will be described with reference to the embodiments shown in the drawings.

3 to 5 show a first embodiment of the solenoid valve according to the present invention. In this figure, the same parts as those shown in FIGS. 1 and 2 are denoted by the same reference numerals.

3 and 4, the valve body 25 moves up and down to open and close the passage 102 through which fluid such as fuel gas passes, and comes into contact with or separates between the annular valves 101. As shown in FIG. The solenoid valve and the housing 103 are processed in the main body 104 in which the passage 102 is formed. The solenoid valve is provided with a first solenoid 14 and a second solenoid 15 and terminals 105 and 106 which protrude from the bottom 108 of the housing 103 and are connected to the electrical circuit shown in FIG. have. The plunger 110 has a bottom wall 111 and a cylindrical side wall 112 in a cup shape and is movably received in the housing 103. The plunger 110 is slidably supported by two annular ribs 113 and 114 formed on the inner wall of the housing 103 with the bottom wall 111 proximate to the main body 104, so that the plunger 110 can be slid therefrom. It is positioned in such a way that it is guided to move along the central axis. If the plunger 110 is guided by the entire inner surface of the housing 103, the frictional resistance between the plunger 110 and the housing 103 becomes too high. Therefore, although the plunger 110 is guided by only two annular ribs 113 and 114 in this embodiment, it is not limited thereto. The housing 103 is provided with a cover 115 that forms a barrier between the passageway 102 and the housing 103.

Since the valve body 25 is connected to the bottom wall 111 through the connecting rod 118 extending through the cover 115, the valve body 25 and the plunger 110 is moved up and down as a heat insulator. The spring 26 is disposed between the lid 115 and the valve body 25 to apply an elastic force such that the valve body 25 closely adheres to the sheath 101 to close the passage 102. The bottom wall 111 is provided with a hole 116 through which air passes between the inside and the outside of the plunger 110. If a current is not applied to the solenoids 14 and 15 as described below, the plunger 110 is urged upward by the spring 26 so that the valve body 25 closes the passage 102. This state is indicated in the right half of FIG. Conversely, when current is applied to solenoid 14, plunger 110 is attracted by core 120 to move downwards against spring 26 to open passage 102. This state is indicated in the left half of FIG. The core 12 is located in the plunger 110, and is provided with a column portion 121, a flange portion 122, and a large diameter portion 13.

The first solenoid 14 is installed in the column portion 21 and is located between the flange portion 122 and the large diameter portion 123. The support member 124 is fitted to the end portion 125 of the column portion 121 and is connected to the large diameter portion 123 of the column portion 121. The support member 124 is provided with an annular groove 126 located adjacent to the bottom wall 111 and into which the second solenoid 15 is fitted. The lower end 119 of the connecting rod 118 protrudes from the bottom wall 111 and is connected to the contact member 130. That is, the contact member 130 is located in the plunger 110 to face the outer end surface of the support member 124. Since the contact member 130 is a plate or a disk and is connected to the lower end 119 so as to be inclined with respect to the bottom wall 111, the contact member 130 may contact the outer surface of the support member 124. Since the spacer 131 is installed between the bottom wall 111 and the contact member 130, a space is formed between the bottom wall 111 and the contact member 130. Since the spacer 131 is made of a rubber nonmagnetic material such as a zero ring or the like, the contact member 130 is magnetically insulated from the plunger 110. The spacer 131 may be a coil spring ring made of a nonmagnetic material. The bottom 119 is caulked to connect the contact member 130 to the connecting rod 118 in such a way that the spacer 131 is slightly compressed. The support member 124 and the contact member 130 are made of a magnetic material with little residual magnetic, such as Furmaloy, and the core 120 is made of ordinary magnetic soft-iron.

As shown in FIG. 4, the core 130 and the cylindrical side wall 112 form the first passage 141, and the support member 124 and the contact member 130 form the second passage 142. . As shown in FIG. 5, the terminal 151 is connected to the first solenoid 141, the terminal 152 is connected to the second solenoid 15, and the terminal 153 is the solenoid 14, 15. Are commonly connected to. The switch 154 opens and closes a circuit including a first solenoid 14 and a power source 155 such as a battery lamp and the switch 156 includes a first solenoid 14 and a power source 155 such as a battery lamp. The circuit opens and closes and the switch 156 opens and closes a circuit including the second solenoid 15 and the power supply 155.

The resistor 157 is installed in the circuit of the second solenoid 15 to reduce the current applied to the second solenoid 15, so that a current lower than the current applied to the first solenoid 14 is lower than the second solenoid 15. Is applied. The solenoid valve of the first embodiment is operated as follows. If no current is supplied to each of the first and second solenoids 14, 15, the valve body 25 springs upwards 26 as indicated in the right half in FIG. 1 to close the passage 102. Is taxed by When the valve body 25 is opened, current is applied to the first and second solenoids 14 and 15 so that magnetic flux is formed around the first and second solenoids 14 and 15, so that the plunger 110 has a core. Attracted to 120 and moved down. As a result, the contact member 130 is in close contact with the end surface of the support member 124, that is, there is no gap between the contact member 130 and the support member 124, and the valve body for opening the passage 102 in the city is shown. 25 is moved down. After this opening operation, the application of the current to the first solenoid 14 is stopped, and the current is applied only to the second solenoid 15 to keep the valve body 25 open. In this state, the contact member 130 is in close contact with the support member 124, so that there is no magnetic flux leakage from the contact member 130 and the support member 124, so that the second valve body 25 is kept open. The current applied to the solenoid 15 is a small amount compared to the current applied to the conventional solenoid valve. When the application of the current to the second solenoid 15 is stopped, the valve body 25 and the plunger 110 are urged upward by the springs 26, so that the valve body 25 is closed to close the passage 102. The valve seat 101 is contacted.

In this closing operation, the support member 124 and the contact member 130 are made of a magnetic material having a small residual magnetic force, and the magnetic flux generated by applying a current to the second solenoid 15 immediately disappears, so that the closing operation is quickly performed. Is performed. In addition, the inner surfaces of the contact member 130 and the bottom wall 111 are separated into non-conductive bodies, and the outer surface of the support member 124 and the inner surface of the plunger 110 are separated from each other, thereby generating a current by applying a current to the first solenoid 14. The first passage 141 is formed only at the end of the column member 121, the flange portion 122, the side wall 112, and the support member 124 adjacent to the first solenoid 14. That is, since the first passage 141 is not formed in the contact member 130 or the bottom wall 111, the closing operation of the valve body 25 is not delayed by the residual magnetic flux. In the opening and closing of the valve body 25, that is, the shank east of the plunger 110, the outer surface of the plunger 110 is slidably by the annular ribs 113 and 114 which are guide members formed on the inner surface of the housing 103. You are guided. Therefore, the plunger 110 is not inclined with respect to the core 120 by, for example, an unbalance of the attraction force acting around the lower end 23 near the core 120, so that the plunger 110 is moved up and down along its axis. Since it moves smoothly, the valve body 25 opens and closes the passageway 102 smoothly. In addition, the present embodiment does not have a long guide rod inserted into the hole formed in the core 120 as in the prior art, so that the interference problem between the guide rod and the inner wall of the hole does not occur. Since the spacer 131 made of nonmagnetic material having elasticity is installed between the bottom wall 111 and the contact member 130, when the valve body 25 is opened, the contact member 13 and the support member 124 are provided. The impact caused by the contact between them is reduced.

As described above, even if the entire core 120 is made of a magnetic material having a small residual magnetic, the problem caused by the residual magnetic is solved. Nevertheless, the solenoid valve becomes expensive because the magnetic material having a small residual magnetic is expensive. On the contrary, according to the embodiment of the present invention, since the support member 124, not the core 120, is made of such a material, the valve price is low. 6 shows a second embodiment of the present invention.

In this embodiment, the support member 124 is a U-shaped member, and is made of a magnetic material having a small residual magnetic force such as a furmaloy or the like. The support member 124 is fitted to the lower end of the column portion 121 of the core 120 and fixed to the large diameter portion 123, and the second solenoid 15 is wound around the support member 124. The rest of the structure is the same as that of the first embodiment shown in FIGS. In the second embodiment, the operation of the solenoid valve is basically the same as that of the first embodiment, and the effect provided by the member of each solenoid valve is the same as the effect in the first embodiment. That is, the plunger 110 is guided by the annular ribs 113 and 114 so as to move up and down smoothly, and the valve body 25 closes the passage 102 quickly by low residual magnetism. In addition, when the valve body 25 is kept open, the amount of current applied is smaller than the amount of current in the prior art because the contact member 130 is in close contact with the support member 124. And when the contact member 130 is in contact with the U-shaped support member 124, the impact generated due to this contact is alleviated by the elastic spacer 131. Although embodiments of the present invention have been described with reference to the accompanying drawings, it is apparent that various changes and modifications can be made by those skilled in the art without departing from the scope of the present invention.

Claims (10)

The valve body 25 which opens and closes the passageway 102, the housing 103, and the bottom wall 111 and the cylindrical side wall 112 in a cup shape are housed in the housing 103, which is movable and is electrically mounted. A plunger 110 connected to the valve body 25 that has been electrically moved to move the valve body 25 that has opened and closed the passage 102 and a first solenoid 14 disposed in the plunger 110 which has been electrically installed. And a first solenoid placed and positioned adjacent to the bottom wall 111 connected to the core 120 and the core 120 forming the first path 141 together with the cylindrical side wall 112. The lower wall which is connected to the support member 124 to which the second solenoid 15 to which current lower than the current applied to 14 is applied, and the plunger 110 arranged in the electric plunger 110 and the electric plunger 110 are installed. A second side with the support member 124 which is inclined with respect to the 111 and is in close contact with the support member 124 described above ( A solenoid valve comprising a contact member (130) forming a 142, and a spacer (131) provided therebetween to form a space between the electric plunger (110) and the electric contact member (130). The solenoid valve according to claim 1, wherein the contact member (130) is made of a magnetic material that holds a small residual magnet such as a permalloy and the like. The solenoid valve according to claim 1, wherein the electrical contact member (130) is a plate. The solenoid valve according to claim 1, wherein the spacer 131 is made of a nonmagnetic material. The solenoid valve according to claim 1, wherein the spacer 131 is formed of an elastic member. The solenoid valve according to claim 1, wherein the support member (124) is provided with an annular groove (126) into which the second solenoid (15) is fitted. 2. The solenoid valve according to claim 1, wherein the supporting member (124) is a U-shaped member in which the second solenoid (15) is wound around it. The method of claim 6 or 7, wherein the support member 124 is made of a magnetic material having a small residual magnetic, the core 120 is characterized in that made of magnetic soft-iron (magnetic soft-iron) Solenoid valve. The device (100) according to claim 1, wherein the electrical housing (103) is provided with a device for guiding the outer surface of the electrical cylindrical side wall (112) of the plunger (110), which is electric so that the electrical plunger (110) moves along its central axis. Solenoid valve characterized in that. 10. The solenoid valve according to claim 9, wherein said guide device has two annular ribs (113) (114) formed separately on the inner surface of said housing (130).

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