KR20190000119U - The solenoid valve - Google Patents

Abstract

The present invention relates to a solenoid valve for controlling the flow of a fluid while opening and closing the flow path by a diaphragm.
The solenoid valve according to the present invention includes a main body 100 having a flow path formed therein; A plunger cap (200) which hermetically closes the upper surface of the main body (100) and has an internal hollow pipe structure and coils (230) wound around the outer periphery; A diaphragm 300 for opening and closing the flow path of the main body 100; A pressure chamber (120) formed in the main body (100) and pressing and releasing the diaphragm (300) by the fluid entering and exiting; An inlet hole 312 for communicating the pressure chamber 120 and the inlet passage 112 and an outlet hole 314 for communicating the pressure chamber 120 and the outlet passage 114 are formed, A diaphragm holder 310 supporting the diaphragm 310; A plunger 210 which is located inside the plunger cap 200 and moves up and down by an electromagnetic force flowing along the coil and opens and closes the outflow hole 314; A return spring 220 for pressing the plunger 210 downward; And an additional spring 320 installed on the upper surface of the diaphragm holder 310 to press the diaphragm 300 in close contact with the valve seat 118. According to the present invention, it is possible to prevent a gap between the diaphragm and the valve seat when the pressure for pressing the diaphragm is lowered when the flow path is shut off, thereby preventing leakage.

Description

SOLENOID VALVE

More particularly, the present invention relates to a solenoid valve which controls the flow of a fluid by opening and closing a flow path by a diaphragm, and when a pressure for pressing the diaphragm is lowered when a flow path is shut off, The solenoid valve according to the present invention can prevent a clearance from being generated in the solenoid valve.

In general, a solenoid valve is a valve that uses the principle of electromagnetism. It generates a physical force in a certain direction by using the principle of electromagnetism, and converts the entrance and exit between the cylinder and the plunger by the physical force acting in a certain direction, (Flow path).

In the conventional diaphragm-type solenoid valve, when the flow path is shut off due to the descent of the plunger, the inflow fluid flows into the pressure chamber on the upper side of the diaphragm to increase the pressure in the pressure chamber, and thereby the diaphragm is pressed toward the valve seat . On the other hand, when the flow path is opened due to the rise of the plunger, the fluid in the pressure chamber is discharged, and the diaphragm opens the flow path as the pressure in the pressure chamber decreases.

In the conventional diaphragm type solenoid valve, when the diameter of the inlet hole through which the fluid flows into the pressure chamber is small and the inflow water pressure of the inlet side conduit is low at the time of interrupting the flow, the fluid can not flow into the pressure chamber, There is a problem that the pressure is lowered and leakage occurs.

In addition, due to the above-described problems, additional troubles have arisen due to selection and installation of an appropriate diaphragm according to the water pressure at the place where the valve is installed.

In addition, micro-crystals such as suspended solids and minerals are accumulated in the inlet hole into which the fluid flows into the pressure chamber, so that the inlet hole becomes narrower. As a result, the fluid does not flow into the pressure chamber, .

Korean Patent Registration No. 1466904 Korea Registered Utility Model No. 0237917 Korea Registered Utility Model No. 0461496

The present invention has been made in order to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a diaphragm having a structure capable of applying a pressing force to a diaphragm, And to provide a solenoid valve in accordance with a new type which is capable of sealing the valve body.

Another object of the present invention is to provide a structure capable of preventing foreign matter from accumulating in the fluid inflow hole of the diaphragm, thereby preventing the pressure in the pressure chamber for pressurizing the diaphragm from being reduced when the diaphragm is closed To provide a new type of solenoid valve.

According to an aspect of the present invention, there is provided a solenoid valve including: a main body communicating an inflow path and an outflow path of a fluid, a valve path communicating the inflow path and the outflow path, A plunger cap which hermetically closes an upper surface of the main body and has an inner hollow pipe structure and coils wound around the outer periphery; A diaphragm installed in the main body and opening / closing the valve channel; A pressure chamber formed in the upper space of the diaphragm in the main body and adapted to pressurize and depressurize the diaphragm by entering and exiting a fluid; A diaphragm holder for supporting the diaphragm, the diaphragm having an inlet hole communicating the pressure chamber and the inlet passage, and an outlet hole communicating the pressure chamber and the outlet passage; A plunger that is located inside the plunger cap and moves up and down by an electromagnetic force flowing along the coil and opens and closes the water outlet; A return spring installed above the plunger in the plunger cap and pressing the plunger so as to descend; And an additional spring installed on the upper surface of the diaphragm holder and pressing the diaphragm so as to closely contact the valve seat of the valve passage.

Here, the plunger is provided at its bottom surface with a plunger seal for sealing the cylinder of the plunger cap when the plunger is lifted, and the plunger is connected to the upper surface of the plunger, And a seating guide end for receiving the plunger packing is protruded upward so that the plunger packing can be accurately mounted on the outlet hole when the plunger is lowered.

According to the solenoid valve according to the present invention, the diaphragm can be pressed by a constant force when the valve is locked by the additional spring for pressing the diaphragm.

Therefore, even when the pressure of the pressure chamber for pressurizing the diaphragm does not satisfy the minimum condition, the diaphragm can be pressurized to a predetermined force or more.

That is, when the inflow water pressure is weaker than the force of the additional spring, the diaphragm is pressed by the force of the additional spring. On the other hand, when the inflow water pressure is higher than the force of the additional spring, The diaphragm is pressed.

Therefore, according to the solenoid valve according to the present invention, the inflow water pressure can be used without replacing the parts in both the low-pressure condition and the high-pressure condition, thereby improving convenience in installation work.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view showing a configuration of a solenoid valve according to one embodiment of the present invention, in which a flow path is blocked. FIG.
FIG. 2 is a cross-sectional view showing the configuration of a solenoid valve according to one embodiment of the present invention, and shows a state in which a flow path is opened. FIG.

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

1 and 2 are cross-sectional views illustrating a configuration of a solenoid valve according to one embodiment of the present invention. FIG. 1 shows a state in which the flow path is blocked, and FIG. 2 shows a state in which the flow path is opened.

As shown in these drawings, the solenoid valve according to the present invention includes a main body 100, a plunger cap 200, a diaphragm 300, a diaphragm holder 310, a plunger 210, a return spring 220 and an additional spring 320. Particularly, the additional spring 320 is configured to press the diaphragm 300 which closes the flow path for locking the valve, do.

This will be described in more detail below for each configuration.

First, a main body 100 in which a flow path is formed is provided. A fluid inflow path 112 and an outflow path 114 are formed in the main body 100 and a valve flow path 116 communicating with the inflow path 112 and the outflow path 114 is formed between the inflow path 112 and the outflow path 114 do.

Here, the valve passage 116 is located at the center of the main body 100, and the upper surface thereof is opened. That is, the main body 100 has an open top surface.

A valve seat 118 protrudes upward from the bottom surface of the valve passage 116. The valve seat 118 protrudes in a cylindrical shape, and the diaphragm 300, which will be described later, is closely attached to the upper surface of the valve seat 118, thereby blocking the flow passage.

A plunger cap 200 is provided on the upper portion of the main body 100. The plunger cap 200 is formed in an empty pipe-like structure and the lower end of the plunger cap 200 is expanded to seal the upper surface of the main body 100.

A coil 230 is wound around the outer circumferential surface of the plunger cap 200 and a plunger 210 is installed inside the plunger cap 200 to move up and down by an electromagnetic force flowing along the coil 230.

A coil 230 may be wound around the outer circumferential surface of the plunger cap 200. A separate bobbin 232 may be coupled to the outer circumference of the plunger cap 200, It is more preferable that the windings 230 are wound.

Next, a diaphragm 300 for opening and closing the valve passage 116 is provided in the main body 100. The diaphragm 300 is installed in the valve passage 116 above the valve seat 118 and has flexibility due to its own shape.

A pressure chamber 120 is provided above the diaphragm 300. That is, the space above the valve passage 116 in the main body 100 is closed by the diaphragm 300. More specifically, the plunger cap 200 and the diaphragm 300 The pressure chamber 120 is provided as a closed space.

The pressure chamber 120 pressurizes or releases the diaphragm 300 while increasing or decreasing the pressure by the fluid flow. At this time, the diaphragm 300 is contacted with or separated from the valve seat 118 in accordance with the pressure or relief of the diaphragm 300 of the pressure chamber 120, so that the flow passage is blocked or opened.

The diaphragm 300 is coupled to a diaphragm holder 310 that supports the diaphragm 300 and guides the operation of the diaphragm 300. The diaphragm holder 310 guides fluid in and out of the pressure chamber 120 and guides the lifting operation of the diaphragm 300 in accordance with a pressure change in the pressure chamber 120.

The diaphragm holder 310 is formed with an inlet hole 312 and an outlet hole 314 communicating the pressure chamber 120 and the valve flow passage 116. More specifically, the inlet hole 312 communicates with the pressure chamber 120 on the side of the inlet passage 112, and the outlet passage 114 communicates with the outlet passage 114 side and the pressure chamber 120 Communicate.

Here, it is a matter of course that the diaphragm 300 has a through hole corresponding to the inlet hole 312 and the outlet hole 314 of the diaphragm holder 310. That is, the inlet hole 312 and the outlet hole 314 are formed through the diaphragm holder 310 and the diaphragm 300.

The inlet hole 312 is disposed on the outer side of the valve seat 118 to guide the fluid introduced through the inlet passage 112 into the pressure chamber 120 when the flow passage is shut off.

Next, the outflow hole 314 is disposed inside the valve seat 118 to guide the fluid introduced into the pressure chamber 120 to the outflow path 114.

As described above, the plunger 210 is provided inside the plunger cap 200 to open and close the outflow hole 314 by the electromagnetic force flowing along the coil 230. The plunger 210 is a cylindrical movable iron core that moves up and down along the inner shape of the plunger cap 200 having a cylindrical structure.

When the power is supplied to the coil 230, the plunger 210 is raised by the electromagnetic force flowing along the coil 230. At this time, the bottom surface of the plunger 210 is separated from the outflow hole 314 to open the outflow hole 314.

A return spring 220 is provided on the plunger 210 to press the plunger 210 downward. The return spring 220 is formed on the plunger 210 in the plunger cap 200 and comprises a compression coil spring for pushing the plunger 210 from the ceiling of the plunger cap 200.

The return spring 220 returns the plunger 210 to the original position when power supply to the coil 230 is interrupted. At this time, the bottom surface of the plunger 210 contacts the upper surface of the outflow hole 314 to close the outflow hole 314.

The plunger 210 and the diaphragm holder 310 are respectively provided with a plunger packing 212 and a seating guide end 316 so that the plunger 210 can close the water outlet hole 314 with correct operation. Respectively.

The plunger packing 212 closes the outflow hole 314 when the plunger 210 is lowered and seals the cylinder of the plunger cap 200 when the plunger 210 is lifted .

The plunger packing 212 is coupled to the bottom surface of the plunger 210 and has an outer diameter that is in close contact with the inner diameter of the plunger cap 200.

The seating guide 316 is configured to accommodate the plunger packing 212 so that the plunger 210 can be accurately seated in the outlet hole 314 when the plunger 210 is lowered .

The seating guide 316 protrudes upward from the upper surface of the diaphragm holder 310 and is disposed concentrically along the circumference of the outlet hole 314. [

An additional spring 320 is provided in the pressure chamber 120 to press the diaphragm 300 in close contact with the valve seat 118 of the valve passage 116.

The additional spring 320 is formed of a compression coil spring and prevents the diaphragm 300 from being separated from the valve seat 118 at a predetermined pressure or less set by the design of the additional spring 320.

Hereinafter, the operation of the solenoid valve according to the embodiment of the present invention having the above-described configuration will be described with reference to the accompanying drawings.

1, the plunger 210 is biased to the lower side of the plunger cap 200 by its own weight and the restoring force of the return spring 220. In this state, And the plunger packing 212 provided on the bottom surface of the plunger 210 is kept in close contact with the water outlet hole 314 of the diaphragm holder 310.

The fluid introduced through the inflow path 112 flows into the pressure chamber 120 along the inflow hole 312 of the diaphragm holder 310 while the outflow hole 314 is blocked, The inner space of the pressure chamber 120 is expanded by the fluid flowing into the pressure chamber 120 because the hole 314 is blocked.

As the internal volume of the pressure chamber 120 is expanded, the flexible diaphragm 300 is lowered and brought into close contact with the valve seat 118, thereby blocking the flow passage. At this time, the fluid introduced into the pressure chamber 120 through the inflow channel 112 is lower than the pressure that presses the bottom face of the diaphragm 300 upward from the upper face of the diaphragm 300 The force for pressing downward is weaker.

However, there is a case where the pressure of the fluid flowing through the inflow path 112 is weak and the inflow hole 112 may not pass through the inflow hole 112. That is, the fluid is less than the pressure through which the fine holes 312 can pass.

In this case, a slight clearance is generated between the diaphragm 300 and the valve seat 118 due to the force of the fluid flowing through the inflow passage 112 to press the bottom surface of the diaphragm 300 upward , Leakage may occur despite the locked state of the valve.

However, since the additional spring 320 presses the diaphragm 300 with a certain force in the pressure chamber 120, the gap between the diaphragm 300 and the valve seat 118 is prevented.

Here, the additional spring 320 is designed so that when the valve is locked, the diaphragm 300 can apply a minimum pressure that is not separated from the valve seat 118.

1, when a power is supplied to the coil 230, a magnetic field is generated due to the current flowing along the coil 230. By the electromagnetic force of the current and the magnetic field, the plunger 210 is moved to the plunger cap 200).

When the lifting action of the plunger 210 is performed, the return spring 220 is compressed and the plunger packing 212 coupled to the bottom surface of the plunger 210 is lifted from the outlet hole 314 of the diaphragm holder 310 So that the outflow hole 314 is opened.

When the outflow hole 314 is opened as described above, the fluid in the pressure chamber 120 is discharged toward the outflow path 114 along the outflow hole 314, and the internal volume of the pressure chamber 120 is reduced.

As the internal volume of the pressure chamber 120 is reduced, the flexible diaphragm 300 rises and is separated from the valve seat 118, thereby opening the flow path.

The fluid introduced through the inflow path 112 is discharged through the outflow path 114 along the opened valve flow path 116, thereby externally supplying the fluid.

As a result, the solenoid valve of the present invention can prevent the diaphragm 300 from being excessively biased by the additional spring 320 even when the pressure in the pressure chamber 120, which presses the diaphragm 300, So that it is possible to prevent the occurrence of water leakage when the flow path is cut off.

The scope of the present invention is not limited to the above-described embodiments, and many other modifications will be possible to those skilled in the art based on the present invention.

100: main body 112: inflow path
114: Outflow path 116: Valve flow path
118: valve seat 120: pressure chamber
200: plunger cap 210: plunger
212: plunger packing 220: return spring
230: coil 232: bobbin
300: diaphragm 310: diaphragm holder
312: Access hole 314: Access hole
316: Seat guide stage 320: Additional spring

Claims (3)

A main body 100 communicating with the inflow passage 112 and the outflow passage 114 of the fluid and the valve passage 116 communicating with the inflow passage 112 and the outflow passage 114 and opened on the upper surface;
A plunger cap (200) which hermetically closes the upper surface of the main body (100) and has an internal hollow pipe structure and coils (230) wound around the outer periphery;
A diaphragm 300 installed in the main body 100 for opening and closing the valve passage 116;
A pressure chamber (120) formed in the upper space of the diaphragm (300) in the main body (100) and pressing and releasing the diaphragm (300) by the flow of fluid;
An inlet hole 312 for communicating the pressure chamber 120 and the inlet passage 112 and an outlet hole 314 for communicating the pressure chamber 120 and the outlet passage 114 are formed, A diaphragm holder 310 supporting the diaphragm 310;
A plunger 210 which is located inside the plunger cap 200 and moves up and down by an electromagnetic force flowing along the coil and opens and closes the outflow hole 314;
A return spring 220 installed on the plunger 210 in the plunger cap 200 to press the plunger 210 downward; And
And an additional spring 320 installed on the top surface of the diaphragm holder 310 and pressing the diaphragm 300 to closely contact the valve seat 118 of the valve passage 116. [ The solenoid valve. The method according to claim 1,
The plunger 210 is provided at its lower surface with a plunger 210 for closing the outlet hole 314 when the plunger 210 is lowered and a plunger packing 200 for sealing the cylinder of the plunger cap 200 when the plunger 210 is lifted. 212 are coupled,
The upper surface of the diaphragm holder 310 is provided with a seating guide stage (not shown) for receiving the plunger packing 212 so that the plunger seal 212 can be seated accurately in the outlet hole 314 when the plunger 210 is lowered 316) protrudes upward. 3. The apparatus of claim 2, wherein the return spring (220)
When the pressure formed inside the pressure chamber 120 is weakened in the lowered state of the plunger 210, a restoring force enough to prevent the diaphragm 300 from being separated from the valve seat 118 Wherein the solenoid valve is configured to have a solenoid valve.

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