KR200256002Y1 - Electromagnetic valve for fluid control - Google Patents

Abstract

The present invention absorbs the frictional force generated when the plunger strikes the fixing member to open the flow path to reduce shock and noise, and can control the plurality of flow paths by forming a plurality of flow paths opened and closed by the magnetic force of the electromagnet. The electromagnet valve for controlling the fluid, the electromagnet valve has a plurality of flow paths are formed inside the body to guide the fluid in and out, and the body for guiding the fluid in and out, and fixed to correspond to the main body flow path When the magnetic force is applied to the coil is applied to the electromagnet, and the fixing member of the metal body having a magnetic body when the magnetic force is generated in each of the respective electromagnets, and movable between the main body flow path and the fixing member Is attached to the fixing member when the magnetic force is generated in the coil, and the magnetic force is not generated in the coil. An elastic member which is separated from the government material and opens and closes the flow path, and an elastic member interposed between the fixing member and the plunger to provide a restoring force so that the plunger can seal the flow path when no magnetic force is generated in the coil. And, it is characterized in that it comprises a buffer member is fixed to any one side of the plunger and the holding member contact surface to reduce the noise generated when the plunger is in close contact with the holding member.

Description

Electromagnetic valve for fluid control

The present invention relates to an electromagnetic valve for controlling the flow of fluids such as a fluid in a liquid state, that is, a water supply control or other heat medium, and more particularly, a flow control of a refrigerant for driving a cooling cycle. The present invention relates to an electromagnet valve for fluid control, which has two independent flow paths, so that each flow path is individually controlled and at the same time, driving noise caused by mechanical shocks can be reduced.

The electromagnet valve is a control mechanism installed on the flow path of all the mechanical devices using the fluid to selectively open and close the flow path and control the flow of the fluid according to the surrounding set conditions. The electromagnet valve is driven according to a signal given from the control means of the device, and the flow path is opened and closed to achieve the desired fluid control. For example, in the case of the cooling and freezing cycle of the refrigerator, an electromagnetic valve is installed on the flow path of the refrigerant, and the flow of the refrigerant is controlled by controlling the flow of the refrigerant while driving an electromagnetic valve driven according to a signal sensed by a temperature sensor or a microcomputer. Air conditioning is achieved at the proper temperature.

1 and 2 show an example of a conventional electromagnet valve. The electromagnet valve 1 is typically provided with an electromagnet means 3 on an upper portion of the main body 2 formed of one flow path 2a, that is, the inlet port 2b and the outlet port 2c are formed at right angles or in the same straight line. In the means 3, the magnetic core 4 is provided so that when the power source is applied to the electromagnet means 3, the movable element 5 moves by the magnetic force generated through the magnetic core 4, and thus, the flow path (2a) is opened and closed to achieve fluid control. By the way, in such an electromagnet valve, one flow path is controlled, and each electromagnet valve is necessarily provided according to the number of flow paths when controlling a plurality of flow paths independent of the apparatus. Therefore, the increase in the number of parts, as well as the installation space is required is a major factor to increase the volume of the device. Furthermore, when the solenoid valve is driven, the impact noise caused by the collision is generated between the mover 5 and the magnetic core 4 which open and close the flow path directly in the electromagnet, and the mechanical drive is not stabilized due to such an impact. The reliability of the product is falling.

The present invention has been made in consideration of the above circumstances, and an object thereof is to provide an electromagnet valve for fluid control to reduce the number of parts by unifying parts and to make the volume of the product as small as possible.

Another object of the present invention is to absorb and reduce the driving noise of the valve, that is, the shock generated between the magnetic core and the mover when the valve is driven by interposing a buffer member between the magnetic core and the mover. The present invention provides an electromagnet valve for fluid control to achieve stable driving.

The object of the present invention is achieved by providing an electromagnetic valve for controlling the fluid passing through all the pipelines, such as the water supply path or the refrigerant flow path of the air conditioner, the electromagnetic valve has a pair of inlet and outlet side flow path A main body having a chamber between these inlet and outlet side flow paths; An electromagnet having a mover driven by an iron core magnetized by a power source applied by being coupled to both chambers of the main body using separate coupling members; A restoring spring installed in the receiving groove formed in the mover to return the mover to its original position when the iron core loses magnetic force; Including an iron core of the electromagnet or a buffer member provided on one side of the movable side of the electromagnet, the two cores are provided on each side of the main body by two electromagnets to be opened and closed to unify parts, and at the same time, the iron core A buffer member is interposed between the actuator and the mover to reduce driving shock and noise of the device.

1 and 2 are cross-sectional views showing the internal configuration of a conventional electromagnet valve,

3 and 4 are cross-sectional views showing the internal configuration of the electromagnet valve of the present invention,

3 is an explanatory diagram giving a state in which a flow path is closed;

4 is an explanatory diagram giving a state in which the flow path is opened;

Figure 5a, 5b, 5c is an enlarged cross-sectional view showing the main portion to extract the portion A of Figure 4, a cross-sectional view showing an embodiment of the present invention,

Explanation of symbols on the main parts of the drawings

11: body 12: electromagnet

13 iron core 14 mover

15: restoring spring 16: shock absorbing member

Next, embodiments of the present invention will be described in detail with reference to the drawings. Figure 3 shows a cross-sectional view showing the internal configuration of the electromagnet valve for fluid control according to the present invention. In the figure, 10 is an electromagnet valve. The electromagnet valve 10 has a main body 11 formed in a substantially rod shape and having two sets of inlet flow passages 17a and 17b on one side and outlet flow passages 17c and 17d on the other side. Both sides of the main body 11 are provided with electromagnets 12a and 12b which are installed to be driven in a direction parallel to the length of the main body 11 using respective coupling members 23a and 23b.

Each of the electromagnets 12a and 12b has iron cores 13a and 13b which are magnetically energized when an electric power is applied to the electromagnets, and movers 14a and 14b which are driven by the magnetization forces of the iron cores 13a and 13b. It includes. At this time, when the movable elements 14a and 14b are driven, that is, the iron cores 13a and 13b are magnetized, the movable elements 14a and 14b are stuck to the iron core side, and when the magnetic core is lost to the iron core, the restoring spring 15 is used. The flow paths 17a and 17b were closed while falling from the iron core.

In addition, these electromagnets 12a, 12b and iron cores 13a, 13b may collide with each other between the iron cores 13a, 13b and the movers 14a, 14b of the respective electromagnets 12a, 12b. When the shock absorbing member 16a, 16b to absorb the shock is interposed.

In addition, the main body 11 has chambers 18a and 18b between the inlet and outlet side flow paths 13a, 13b, 13c, and 13d, and electromagnets in the chambers 18a and 18b. The movable elements 14a and 14b will be driven by a magnetization force generated by the application of power to the coil 20 wound around the hollow-cylindrical bobbin 19 of (12a) and (12b).

In addition, each of the movable members 14a and 14b includes a receiving groove 22 in its body so that the restoring spring 15 is incorporated.

On the other hand, the shock absorbing member 16 may use an elastic material capable of absorbing shock, that is, preferably a rubber material or synthetic resins having excellent absorbing power, and the shock absorbing member 16 is generated when the mover strikes the iron core. It will absorb shocks and thus reduce drive noise.

5A, 5B, and 5C show an embodiment of the inventive shock absorbing member 16. FIG. 5A shows a detailed view of the shock absorbing member 16. In this embodiment, the shock absorbing member 16 is an iron core 13a, 13b. It shows the state that it is installed partly on the side. At this time, the buffer member 16 is made of a ring-shaped body.

Figure 5b is another embodiment of the present invention, which is also installed on the iron core (13a) (13b) side partly embedded, in which the body shows a buffer member (16a) consisting of a disc shape.

Figure 5c is another embodiment of the present invention, showing an example in which the buffer member 16b having a tubular shape integrally with the flange is inserted into the receiving groove 22 of the movers 14a and 14b. have.

As such, the present invention may use various types of shock absorbing members 16, 16a and 16b, and the shock absorbing members may be selectively installed on the iron core or the mover side.

Then, the effect of the present invention electromagnet valve will be described in detail. The electromagnet valve of the present invention forms two sets of inlet and outlet side flow paths on both sides of one main body, and opens and closes each of these inlet and outlet flow paths by a mover that drives each electromagnet to control multiple flow paths of a mechanical device simultaneously. In this way, there is an effect of unifying the two kinds of parts and thus reducing the number of parts of the device and further miniaturizing the product volume.

In addition, by absorbing the shock of the actuator of the electromagnet valve to obtain a stabilization in the mechanical operation, while also reducing the noise generated during the impact to increase the product. As described above, the embodiment of the present invention has been described, the present invention Changes may be made without departing from the scope of the claims.

Claims (4)

A main body having a pair of inlet and outlet side flow paths and a chamber between each of the inlet and outlet flow paths; An electromagnet having a mover configured by an iron core magnetized by a power source applied by being coupled to both chambers of the main body using separate coupling members; A spring installed in the receiving groove formed in the mover to return the mover to its original position when the iron core loses magnetic force; And It includes a buffer member which is installed on either the iron core of the electromagnet or the movable side of the electromagnet, Here, two sets of flow paths are opened and closed by respective electromagnets on both sides of the main body to unify the parts and at the same time intervene a shock absorbing member between the iron core and the mover to reduce driving shock and noise of the device. Electromagnet valve for fluid control, characterized in that. The method of claim 1, The electromagnet valve for fluid control comprising the buffer member is formed in a ring shape to be installed to the iron core in part embedded. The method of claim 1, Electromagnet valve for fluid control comprising the buffer member is made in the shape of a disc to be installed in part embedded in the iron core. The method of claim 1, The electromagnet valve for fluid control comprising the buffer member is formed in a tubular shape having a flange integrally at the upper end to be inserted into the receiving groove of the mover.