CN201818879U - Magnetic control multi-way valve - Google Patents

Abstract

The utility model discloses a magnetic control multi-way valve, which comprises a fixed unit, at least two control valves and a second magnet. The fixing unit has a water inlet and at least two attachment cavities, and the lower port of the attachment cavity forms a water outlet. The two control valves are installed in the two installation chambers respectively. The control valve includes a spool assembly, a first magnet, a gasket, a first spring and a second spring. The valve core assembly is fixed in the installation chamber and is provided with a pressure relief passage. The first magnet can be slidably connected up and down in the installation chamber and located on the valve core assembly. The gasket can be slid up and down and connected in the installation cavity and is located under the valve core assembly. A second magnet is attached horizontally to the outside of the fixed unit. It has the following advantages: the horizontal sliding of the second magnet controls the vertical sliding of the first magnet; The on-off between the water port and the water inlet chamber realizes the switching of the waterway.

Description

A magnetically controlled multi-way valve

technical field

The utility model relates to a multi-way valve, in particular to a magnetically controlled multi-way valve.

Background technique

The existing technology is solenoid valve technology, but its use is electric control, which needs to introduce an additional electric energy source, and has a large structure. The solenoid valve based on this technology not only has a large manufacturing cost, but also has a large use cost, requiring consumption electricity.

Utility model content

The utility model provides a magnetically controlled multi-way valve, which overcomes the disadvantages of high cost and power consumption in the electromagnetic valve technology in the background technology.

The technical solution adopted by the utility model to solve its technical problems is:

A magnetically controlled multi-way valve comprising:

A fixed unit, which has a water inlet and at least two independent attachment cavities, the lower ports of the attachment cavities form water outlets;

At least two control valves, which are respectively installed in each installation cavity; each control valve includes:

A spool assembly fixed in the mounting cavity, which is provided with a pressure relief channel;

A first magnet that can slide up and down relative to the installation cavity and control the unblocking of the pressure relief channel by sliding up and down, which can slide up and down and is connected in the installation cavity and is located on the valve core assembly;

A sealing gasket that can slide up and down relative to the installation chamber and control the connection between the water outlet and the water inlet chamber by sliding up and down under the control of the opening and blocking of the pressure relief channel. It can slide up and down and is connected in the installation chamber and is located in the valve core assembly under;

a first spring positioned between the gasket and the spool assembly; and

a second spring positioned between the first magnet and the spool assembly; and

A second magnet that can relatively slide horizontally and control the first magnet to slide up and down through the horizontal slide, which slides horizontally and is connected to the outside of the fixed unit.

In a preferred embodiment: a plug suitable for the pressure relief channel is fixed under the first magnet.

In a preferred embodiment:

The fixing unit includes a body and an upper cover, and the body and the upper cover are sealed and fixed together;

A first chamber is formed between the valve core assembly and the gasket, and a second chamber is formed between the valve core assembly and the upper cover;

A first water hole is provided on the sealing pad, and the first water hole is connected to the water inlet and the first cavity;

There is a pressure relief passage through the top and bottom of the valve core assembly and a second water hole through the top and bottom, the second water hole is connected to the first chamber and the second chamber, and the pressure relief passage is connected to the second chamber. Second cavity and water outlet.

In a preferred embodiment: the second magnet is horizontally slidably connected to the upper cover, and the corresponding magnetic pole of the lower end surface of the second magnet is opposite to the corresponding magnetic pole of the upper end surface of the first magnet.

In a preferred embodiment, a guide sleeve is arranged under the valve core assembly, the upper end of the guide sleeve is connected to a pressure relief channel, and the sealing pad is sealed and slidingly connected outside the guide sleeve.

In a preferred embodiment: a fixing groove adapted to the first spring is arranged on the sealing gasket, and the first spring is adapted to be connected to the fixing groove, and there is a fixing groove on the first spring an insertion end, and the insertion end is inserted into the first water hole.

In a preferred embodiment, a push button is horizontally slidably connected to the upper cover, and the push button is fixedly connected to the second magnet.

In a preferred embodiment: an upward stepped surface is provided in the installation cavity, and the sealing gasket corresponds to the stepped surface.

In a preferred embodiment: a convex figure is protruded on the stepped surface.

Compared with the background technology, this technical solution has the following advantages:

1. Control the first magnet to slide up and down through the horizontal sliding of the second magnet, control the unblocking of the pressure relief channel through the up and down sliding of the first magnet, control the up and down sliding of the gasket through the unblocking of the pressure relief channel, and control the water outlet and inlet through the up and down sliding of the gasket The on-off between the water chambers, so as to realize the switching of the waterway, it overcomes the shortcomings of the background technology, and can produce the following beneficial effects: a. Compared with the previous power control, the applicable occasions are more extensive, unlimited, and have high safety performance; 2. Saving solenoid valves can greatly save manufacturing, and saving electric energy can greatly reduce the cost of use. This effect is especially prominent in the existing environmental protection society that advocates energy saving and carbon reduction; c. Switching is light and accurate; d. It has the effect of magnetizing water, magnetizing Water has various miraculous effects and is widely used in fields such as industry, agriculture and medicine;

2. There is a fixed groove on the sealing pad that is suitable for the first spring, and the first spring is adapted to connect to the fixed groove. There is an insertion end on the first spring, and the insertion end is inserted into the first water hole, which can accurately Locating the first spring for easy assembly;

3. There is a convex pattern on the stepped surface, and the sealing is realized through the cooperation of the gasket and the convex pattern, and the sealing performance is good.

Description of drawings

Below in conjunction with accompanying drawing and embodiment the utility model is further described.

FIG. 1 is a three-dimensional schematic diagram of a magnetically controlled two-way valve in a preferred embodiment of the present invention.

Fig. 2 is a three-dimensional exploded view of the magnetically controlled two-way valve in a preferred embodiment of the present invention.

Fig. 3 is a three-dimensional exploded view of the valve core assembly in the magnetically controlled two-way valve in a preferred embodiment of the present invention.

Fig. 4a is a three-dimensional schematic diagram of a valve core body in a magnetically controlled two-way valve in a preferred embodiment of the present invention.

Fig. 4b is a schematic cross-sectional view of the valve core body in the magnetically controlled two-way valve in a preferred embodiment of the present invention.

Fig. 4c is a three-dimensional schematic diagram of the gasket in the magnetically controlled two-way valve in a preferred embodiment of the present invention.

Fig. 4d is a schematic cross-sectional view of the gasket in the magnetically controlled two-way valve in a preferred embodiment of the present invention.

Fig. 5a is a middle cross-sectional view of the magnetically controlled two-way valve when the push button is directly above the water outlet B in a preferred embodiment of the present invention.

Fig. 5b is a schematic cross-sectional view along line A-A of Fig. 5a.

Fig. 6a is a cross-sectional view of the magnetically controlled two-way valve when the push button is in the middle position in a preferred embodiment of the present invention.

Fig. 6b is a schematic cross-sectional view of B-B in Fig. 6a.

Fig. 7a is a cross-sectional view of the magnetically controlled two-way valve when the push button is directly above the water outlet A in a preferred embodiment of the present invention.

Fig. 7b is a schematic cross-sectional view of C-C in Fig. 7a.

Detailed ways

Please refer to FIG. 1 to FIG. 7 , a magnetically controlled multi-way valve, which includes a fixed unit, two control valves 100 , and a second magnet 200 .

The fixing unit includes a body 300 and an upper cover 400 . The body 300 and the upper cover 400 are hermetically fixed together, and the fixed unit has a water inlet 310 capable of connecting to an external water source and two mutually independent mounting cavities 320 horizontally arranged at intervals. The mounting cavities 320 The lower port forms a water outlet 330, and the fitting cavity 320 and the water outlet 330 are preferably coaxial. In this embodiment, an upward stepped surface is provided inside the installation cavity 320 , and a convex figure 340 protrudes from the stepped surface. In this embodiment, the two installation chambers 320 are respectively defined as an installation chamber 320A and an installation chamber 320B, and the two water outlets 330 are respectively defined as a water outlet 330A and a water outlet 330B.

The two control valves 100 are installed in the two installation chambers 320 respectively. The control valve 100 includes a spool assembly 110 , a first magnet 120 , a gasket 130 , a first spring 140 and a second spring 150 . The valve core assembly 110 is fixed in the mounting cavity 320, the first magnet 120 can slide up and down in the mounting cavity 320 and is located on the valve core assembly 110, and the sealing gasket 130 can slide up and down in the connection Inside the installation cavity 320 and under the valve core assembly 110, the first spring 140 is arranged between the gasket 130 and the valve core assembly 110; the second spring 150 is arranged between the first magnet 120 and the valve core assembly 110 between. The gasket 130 is located on the stepped surface of the mounting cavity 320 , corresponding to the convex figure 340 of the mounting cavity 320 . A first cavity 160 is formed between the valve core assembly 110 and the gasket 130 , and a second cavity 170 is formed between the valve core assembly 110 and the upper cover 400 .

The spool assembly 110 is provided with a pressure relief channel 111 that runs through the top and bottom and a second water hole 112 that runs through the top and bottom. The second water hole 112 connects the first chamber 160 and the second chamber 170, so The pressure relief channel 111 is connected to the second chamber 170 and the water outlet 330 . Preferably, a water screw 180 is provided to be screwed into the lower port of the pressure relief channel 111 of the spool assembly 110, and then the water screw 180 can connect the pressure relief channel 111 to the water outlet 330, and it can be sealed. The pad 130 plays a guiding role (the central hole 132 of the sealing pad 130 is sealed and slidably sleeved outside the water screw 180 ). A first water hole 131 is defined above the sealing pad 130 , and the first water hole 131 is used to connect the water inlet 310 and the first cavity 160 .

In order to ensure the sealing performance, preferably, a plug 121 suitable for the pressure relief channel is fixed under the first magnet 120 .

In order to ensure the accurate positioning of the first spring 140, in order to facilitate assembly, it is preferable that a fixing groove adapted to the first spring 140 is arranged on the gasket 130, and the first spring 140 is adapted to be connected to the fixing groove. Moreover, the first spring 140 has an insertion end 141 on it, and the insertion end 141 is inserted into the first water hole 131 . In order to ensure accurate positioning of the second spring 150 and to facilitate assembly, it is preferable that the upper end surface of the valve core assembly 110 is recessed with a positioning groove, and the second spring 150 is adapted to be connected to the positioning groove.

For ease of understanding, the above-mentioned two control valves 100 are respectively defined as a control valve 100A and a control valve 100B, and the corresponding components of the two control valves 100 are also defined separately, for example, the two spool assemblies 110 are respectively defined as a spool assembly 110A and a spool assembly 110A. In the assembly 110B, the two first cavities 160 are respectively defined as a first cavity 160A and a first cavity 160B and so on. In order for the examiner to clearly understand the following action principles, in Figure 1, Figure 2, Figure 5, Figure 6 and Figure 7, A and B are respectively used to distinguish the two control valves and their corresponding structures, and their structures are essentially the same , so when introducing a single control valve in Figure 3 and Figure 4, there is no distinction between A and B.

The second magnet 200 can be horizontally slidably connected to the upper cover 400 , in order to ensure smooth horizontal sliding of the second magnet 200 , it is better to cooperate with a push button 210 , two third springs 220 and two positioning beads 230 . The second magnet is fixed under the push button 210, the left and right sides of the upper cover 400 are respectively provided with slide grooves, the left and right sides of the push button 210 respectively extend downwards to form sliders, and the two slides The blocks are respectively slidably connected in the chute to realize the connection relationship to guide. The positioning ball and the third spring cooperate to convert sliding friction into rolling friction, so as to reduce the coefficient of friction. In order to prevent the push button from sliding out of the upper cover, it is better to provide a limit mechanism 240 .

In this embodiment, the shape of the second magnet 200 is the same as that of the first magnet 120 , and the magnetic poles corresponding to the lower end surface of the second magnet are opposite to those corresponding to the upper end surface of the first magnet.

As shown in FIG. 5 , the push button 210 is right above the water outlet 330B at this time, and after the water flow fills the water inlet chamber through the water inlet 310, it enters the first chamber 160A, 160B through the left and right first water holes 131A, 131B, and After filling the space, enter the second cavity 170A, 170B along the second water hole 112A, 112B;

Because there is a magnetic pole facing each other above the first magnet 120B (that is, the second magnet 200 with N pole to N pole) and repulsion occurs, the first magnet 120B drives the plug 121B to move downward to block the pressure relief port of the pressure relief channel 111B, so that The water pressure in the first chamber 160B and the second chamber 170B is the same as the water pressure in the water inlet chamber because the pressure relief port cannot discharge water; the sealing gasket 130B will reach the water outlet in the initial state due to the action of the first spring 140B The lower part of 330B is connected to the water outlet 330B, and the pressure of the water outlet 330B is the same as the atmosphere, so that the sealing gasket 130B has a downward pressure difference, blocking the water outlet 330B, so that the water outlet 330B is watertight;

Since there is no second magnet above the first magnet 120A, without repulsive force, it moves upwards under the action of the second spring 150B, and the pressure relief channel 111A is connected, so that the pressure of the first chamber 160A and the second chamber 170A are in line with the water outlet. The pressure of 330A (that is, the pressure of the atmosphere) is the same, so that the pressure at the upper end of the sealing gasket 130A is lower than the pressure at the lower end, so that the sealing gasket 130A moves upward to open to the water outlet 330A, so that the water outlet 330A starts to discharge water. Wherein: the force of the sealing gasket 130A is: F1'-F2=(P1 (the active force of the water pressure acting on the sealing gasket 130A-P2 (the active force of the atmospheric pressure acting on the sealing gasket 130A))*S-F2 (the force of the first spring Elasticity)>0.

As shown in Figure 6, push the push button to the left to the middle position, then the second magnet 200 leaves the first magnet 120B and does not reach the first magnet 120A, at this time the pressure relief ports of the pressure relief channels 111A and 111B are both opened, the same reason It can be obtained that at this time the water outlets 330A and 330B both discharge water outwards.

As shown in FIG. 7 , continue to push the push button to the left to the far left. At this time, the first magnet 120A is subjected to repulsive force, but the first magnet 120B is not affected. Similarly, the water outlet 330B is discharged, and the water outlet 330A is not discharged.

Push the knob, the above process can be cycled.

In this embodiment, a two-way valve is taken as an example, but it is not limited thereto. Others such as three-way valves are also applicable. For example, three control valves are provided, and the first magnets of the three control valves slide up and down through the second magnet to realize the on-off of the water outlet.

The above is only a preferred embodiment of the utility model, so the scope of implementation of the utility model cannot be limited accordingly, that is, the equivalent changes and modifications made according to the patent scope of the utility model and the contents of the specification should still belong to this utility model. within the scope of utility models.

Claims (9)

1. A magnetic control multi-way valve is characterized in that: it comprises: A fixed unit, which has a water inlet and at least two independent attachment cavities, the lower ports of the attachment cavities form water outlets; At least two control valves, which are respectively installed in each installation cavity; each control valve includes: A spool assembly fixed in the mounting cavity, which is provided with a pressure relief channel; A first magnet that can slide up and down relative to the installation cavity and control the unblocking of the pressure relief channel by sliding up and down, which can slide up and down and is connected in the installation cavity and is located on the valve core assembly; A sealing gasket that can slide up and down relative to the installation chamber and control the connection between the water outlet and the water inlet chamber by sliding up and down under the control of the opening and blocking of the pressure relief channel. It can slide up and down and is connected in the installation chamber and is located in the valve core assembly under; a first spring positioned between the gasket and the spool assembly; and a second spring positioned between the first magnet and the spool assembly; and A second magnet that can relatively slide horizontally and control the first magnet to slide up and down through the horizontal slide, which slides horizontally and is connected to the outside of the fixed unit. 2 . The magnetically controlled multi-way valve according to claim 1 , wherein a plug adapted to the pressure relief channel is fixed under the first magnet. 3 . 3. A magnetically controlled multi-way valve according to claim 2, characterized in that: The fixing unit includes a body and an upper cover, and the body and the upper cover are sealed and fixed together; A first chamber is formed between the valve core assembly and the gasket, and a second chamber is formed between the valve core assembly and the upper cover; A first water hole is provided on the sealing pad, and the first water hole is connected to the water inlet and the first cavity; There is a pressure relief passage through the top and bottom of the valve core assembly and a second water hole through the top and bottom, the second water hole is connected to the first chamber and the second chamber, and the pressure relief passage is connected to the second chamber. Second cavity and water outlet. 4. A magnetically controlled multi-way valve according to claim 3, wherein the second magnet is horizontally slidably connected to the upper cover, and the lower end of the second magnet corresponds to the magnetic pole and the upper end of the first magnet The faces correspond to the opposite magnetic poles. 5. A magnetic control multi-way valve according to claim 4, characterized in that: a guide sleeve is arranged under the valve core assembly, the upper end of the guide sleeve is connected to a pressure relief channel, and the sealing pad seals and slides Socketed outside the guide sleeve. 6. A magnetically controlled multi-way valve according to claim 3, characterized in that: a fixing groove adapted to the first spring is arranged on the sealing pad, and the first spring is adapted to be connected to the fixing groove Moreover, there is an insertion end on the first spring, and the insertion end is inserted into the first water hole. 7 . The magnetically controlled multi-way valve according to claim 3 , wherein a push button is horizontally slidably connected to the upper cover, and the push button is fixedly connected to the second magnet. 8 . 8. A magnetically controlled multi-way valve according to claim 3 or 4 or 5 or 6 or 7, characterized in that: there is an upward stepped surface inside the mounting cavity, and the gasket corresponds to the stepped surface . 9 . The magnetically controlled multi-way valve according to claim 8 , wherein a protruding ring is provided on the stepped surface. 10 .

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