Fluid switching valve
1. A fluid switching valve, characterized by: the valve body assembly comprises a valve seat and a shell assembly, the coil stator is fixed on the outer wall of the shell assembly, the rotor assembly is arranged in the shell assembly, and the lower part of the rotor assembly is connected with the commutator; the shell assembly is fixed on the valve seat, and the static valve disc is fixed on the valve seat; the limiting device penetrates through the static valve disc and is fixed on the valve seat;
when the commutator is electrified, the rotating magnetic field generated by the coil stator and the magnetic field generated by the rotor component interact with each other, so that the rotor component rotates, and the commutator moves angularly.
2. A fluid switching valve as claimed in claim 1 wherein: the valve seat comprises a seat body, an input pipeline, a first output pipeline and a second output pipeline are arranged on the outer wall of the seat body, and the first output pipeline and the second output pipeline are symmetrical in position; the seat body is provided with a hole C connected with the input pipeline, the seat body is provided with a hole A connected with the first output pipeline, the seat body is provided with a hole B connected with the second output pipeline, the hole A and the hole B are symmetrical in position, and the hole A, the hole B and the hole C are on the same reference circle and have the same size; a limiting blind hole matched with the limiting device is arranged on the same plane where the hole A, the hole B and the hole C are located, and the limiting blind hole and the hole C are located on the same central line; and the seat body is provided with a valve cavity matched with the static valve disc and the shell assembly.
3. A fluid switching valve according to claim 1 or 2, wherein: be equipped with respectively on the quiet valve disc with A hole, B hole, C hole, spacing blind hole position correspond and big or small the same first through-hole, second through-hole, third through-hole, fourth through-hole, the up end of quiet valve disc is equipped with first sealed face, the lower terminal surface of quiet valve disc be equipped with first through-hole two sealed annular that the second through-hole corresponds.
4. A fluid switching valve as claimed in claim 1 wherein: the rotor assembly comprises a first bearing, a second bearing, a magnetic ring and a rotating shaft, wherein the second bearing, the magnetic ring and the first bearing are sequentially fixed on the rotating shaft; the first bearing and the second bearing are secured in the housing assembly.
5. The fluid switching valve according to claim 4, wherein: a balance hole which penetrates through the center of the rotating shaft up and down is formed in the center of the rotating shaft, a first spring hole matched with the pressure spring is formed below the balance hole, and a connecting groove matched with the commutator is formed below the first spring hole; and a first step column matched with the first bearing is formed outside the balance hole, a second step column matched with the magnetic ring is formed below the first step column, and a third step column matched with the second bearing is formed below the second step column.
6. The fluid switching valve according to claim 1 or 5, wherein: the commutator is provided with a connecting part matched with the connecting groove; a second spring hole matched with the pressure spring is formed in the right center of the connecting part; a flow guide hole is formed below the second spring hole; a flow channel groove communicated with the flow guide hole is arranged below the connecting part, a limiting groove is arranged at the opposite position of the flow channel groove, and the limiting groove is separated from the flow channel groove; and a second sealing surface matched with the first sealing surface is arranged below the limiting groove and the runner groove.
7. The fluid switching valve of claim 6, wherein: the limiting groove is provided with a first limiting point and a second limiting point which are matched with the limiting device, and the first limiting point and the second limiting point are symmetrical in position and identical in size.
Background
The fluid switching valve is a valve which is widely applied in modern industry, and is a valve for realizing communication, cutting off, reversing, pressure unloading and sequential action control of fluid. Currently, a fluid switching valve commonly used in industry is a low-pressure low-frequency operation valve. When a special valve, such as a textile fluid switching valve, is involved, the valve is a high-pressure high-frequency switching valve. The valve has very high requirement on the service life, the switching frequency is as high as more than 600 times per minute, and the valve is a very special valve.
However, the current textile fluid switching valve has the following defects: first, spare part is easy wearing and tearing, does not have the automatic compensation function, like the axial sealing washer of sealed effect, radially sealed ceramic case and ceramic cover are in the condition of high pressure high frequency switching action for a long time, easily take place spare part wearing and tearing, reduce life. Such a drawback leads to increased maintenance costs; secondly, the ceramic valve core and the ceramic sleeve are in clearance fit, and the valve always has leakage problems due to the clearance fit. The two defects can cause poor sealing effect and large fluid pressure drop at the same time. If the pressure is kept the same, power is wasted.
Disclosure of Invention
The present invention aims to overcome the above-mentioned deficiencies of the prior art and to provide a fluid switching valve.
In order to achieve the purpose, the invention adopts the following technical scheme: a fluid switching valve, characterized by: the valve body assembly comprises a valve seat and a shell assembly, the coil stator is fixed on the outer wall of the shell assembly, the rotor assembly is arranged in the shell assembly, and the lower part of the rotor assembly is connected with the commutator; the shell assembly is fixed on the valve seat, and the static valve disc is fixed on the valve seat; the limiting device penetrates through the static valve disc and is fixed on the valve seat;
when the commutator is electrified, the rotating magnetic field generated by the coil stator and the magnetic field generated by the rotor component interact with each other, so that the rotor component rotates, and the commutator moves angularly.
In the above fluid switching valve, the valve seat includes a seat body, an input pipeline, a first output pipeline and a second output pipeline are arranged on an outer wall of the seat body, and the first output pipeline and the second output pipeline are symmetrical in position; the seat body is provided with a hole C connected with the input pipeline, the seat body is provided with a hole A connected with the first output pipeline, the seat body is provided with a hole B connected with the second output pipeline, the hole A and the hole B are symmetrical in position, and the hole A, the hole B and the hole C are on the same reference circle and have the same size; a limiting blind hole matched with the limiting device is arranged on the same plane where the hole A, the hole B and the hole C are located, and the limiting blind hole and the hole C are located on the same central line; and the seat body is provided with a valve cavity matched with the static valve disc and the shell assembly.
In above-mentioned fluid switching valve, be equipped with respectively on the static valve disc and correspond and the same first through-hole of size, second through-hole, third through-hole, fourth through-hole with A hole, B hole, C hole, spacing blind hole position, the up end of static valve disc is equipped with first sealed face, the lower terminal surface of static valve disc be equipped with first through-hole two sealed annular grooves that the second through-hole corresponds, sealed annular groove is used for settling the sealing washer, and the purpose prevents that A hole and B hole from streaming.
In the above fluid switching valve, the rotor assembly includes a first bearing, a second bearing, a magnetic ring, and a rotating shaft, and the second bearing, the magnetic ring, and the first bearing are sequentially fixed to the rotating shaft; the first bearing and the second bearing are fixed in the housing assembly, and the main purpose of using the bearings is to reduce frictional resistance and to perform a supporting function.
In the above fluid switching valve, a balance hole penetrating up and down is formed in the center of the rotating shaft, a first spring hole matched with the pressure spring is formed below the balance hole, and a connecting groove matched with the commutator is formed below the first spring hole; and a first step column matched with the first bearing is formed outside the balance hole, a second step column matched with the magnetic ring is formed below the first step column, and a third step column matched with the second bearing is formed below the second step column.
In the above fluid switching valve, the commutator is provided with a connecting portion which fits the connecting groove; a second spring hole matched with the pressure spring is formed in the right center of the connecting part; a flow guide hole is formed below the second spring hole; a flow channel groove communicated with the flow guide hole is arranged below the connecting part, a limiting groove is arranged at the opposite position of the flow channel groove, and the limiting groove is separated from the flow channel groove; and a second sealing surface matched with the first sealing surface is arranged below the limiting groove and the runner groove.
In the above fluid switching valve, the limiting groove is provided with a first limiting point and a second limiting point which are matched with the limiting device, and the first limiting point and the second limiting point are symmetrical in position and have the same size.
Compared with the prior art, the invention has the following beneficial effects:
the sealing mode adopted by the invention is axial sealing, the sealing mode is realized by the second sealing surface of the commutator and the first sealing surface of the static valve disc, and the first sealing surface and the second sealing surface are both obtained by mirror finishing. The invention realizes the automatic compensation function after the parts are worn, and when the first sealing surface and the second sealing surface are worn, the second sealing surface of the commutator is tightly matched with the first sealing surface of the static valve disc under the elastic action of the pressure spring and the axial pressure of the fluid on the commutator. By the mode, the invention realizes that parts do not need to be replaced and electric power does not need to be wasted for maintaining pressure.
Drawings
The invention is further described with reference to the accompanying drawings:
FIG. 1 is a schematic structural view of the present invention;
FIG. 2 is a schematic view of the construction of a valve seat according to the present invention;
FIG. 3 is a first schematic structural diagram of a static valve disc according to the present invention;
FIG. 4 is a second schematic structural view of a static valve disc according to the present invention;
FIG. 5 is a schematic view A of the rotating shaft according to the present invention;
FIG. 6 is a schematic sectional view A-A of a rotary shaft according to the present invention;
FIG. 7 is a first schematic structural diagram of the commutator of the present invention;
FIG. 8 is a second schematic structural view of the commutator of the present invention;
in the figure, 1-valve seat, 101-input pipeline, 102-first output pipeline, 103-second output pipeline, 104-C hole, 105-A hole, 106-B hole, 107-limiting blind hole, 108-valve cavity, 109-seat body; 2-a coil stator; 3-a limiting device; 4-a housing assembly; 5-static valve disc, 501-first through hole, 502-second through hole, 503-third through hole, 504-fourth through hole, 505-first sealing surface, 506-sealing ring groove; 6-commutator, 601-connecting part, 602-second spring hole, 603-diversion hole, 604-runner groove, 605-limiting groove, 6051-first limiting point, 6052-second limiting point, 606-second sealing surface; 7-a pressure spring; 8-a second bearing; 9-a magnetic ring; 10-a first bearing; 11-rotation axis, 1101-balance hole, 1102-first spring hole, 1103-connection groove, 1104-first step column, 1105-second step column, 1106-third step column.
Detailed Description
The technical scheme of the invention is further specifically described by the following embodiments.
Referring to fig. 1, a fluid switching valve comprises a valve body assembly, a driving mechanism, a commutator 6, a static valve disc 5 and a limiting device 3,
wherein, the driving mechanism comprises a coil stator 2 and a rotor component,
the valve body assembly comprises a valve seat 1 and a shell assembly 4, a coil stator 2 is fixed on the outer wall of the shell assembly 4, a rotor assembly is arranged in the shell assembly 4, and the lower part of the rotor assembly is connected with a commutator 6; the shell component 4 is fixed on the valve seat 1, and the static valve disc 5 is fixed on the valve seat 1; the limiting device 3 is fixed on the valve seat 1 through the static valve disc 5;
when energized, the rotating magnetic field produced by the coil stator 2, when interacting with the magnetic field produced by the rotor assembly, causes the rotor/assembly to move in rotation, thereby causing the commutator 6 to move angularly.
Referring to fig. 2, the valve seat 1 of the present invention will be further specifically described as follows:
the valve seat comprises a seat body 109, an input pipeline 101, a first output pipeline 102 and a second output pipeline 103 are arranged on the outer wall of the seat body 109, and the first output pipeline 102 and the second output pipeline 103 are symmetrical in position;
wherein, the seat body 109 is provided with a C hole 104 connected with the input pipeline 101;
wherein, the seat body 109 is provided with an A hole 105 connected with the first output pipeline 102;
wherein, the seat body 109 is provided with a B hole 106 connected with the second output pipeline 103;
the holes A105 and B106 are symmetrical in position, and the holes A105, B106 and C104 are on the same reference circle and have the same size;
the same plane where the hole A105, the hole B106 and the hole C104 are located is provided with a limiting blind hole 107 matched with the limiting device 3, and the limiting blind hole 107 and the hole C104 are on the same central line;
wherein, the seat body 109 is provided with a valve cavity 108 matched with the static valve disc 5 and the shell component 4.
Referring to fig. 3 and 4, the static valve disk 5 of the present invention will be further specifically described as follows:
the static valve disc 5 is provided with a first through hole 501, a second through hole 502, a third through hole 503 and a fourth through hole 504 which correspond to the hole A105, the hole B106, the hole C104 and the limiting blind hole 107 in position and have the same size;
the upper end surface of the static valve disk 5 is provided with a first sealing surface 505, and the first sealing surface 505 is obtained by grinding to form a mirror surface, so that the friction resistance is reduced, and the sealing effect is improved;
two sealing ring grooves 506 corresponding to the first through hole 501 and the second through hole 502 are formed in the lower end face of the static valve disc 5, and the two sealing ring grooves are used for accommodating sealing rings.
The rotor assembly of the present invention is further described in detail with reference to fig. 1, 5 and 6, as follows:
the rotor assembly comprises a first bearing 10, a second bearing 8, a magnetic ring 9 and a rotating shaft 11, wherein the second bearing 8, the magnetic ring 9 and the first bearing 10 are sequentially fixed on the rotating shaft 11; the first bearing 10 and the second bearing 8 are fixed in the housing assembly 4; the rotor assembly is so arranged as to reduce frictional resistance generated during rotation of the rotation shaft 11 using the first bearing 10 and the second bearing 8, and the first bearing 10 and the second bearing 8 support the rotation shaft 11.
Referring to fig. 5 and 6, the rotating shaft 11 of the present invention will be described in detail as follows:
wherein, the center of the rotating shaft 11 is provided with a balance hole 1101 which penetrates up and down, and the purpose is to make the fluid reach balance rapidly and accelerate the switching speed;
a first spring hole 1102 matched with the pressure spring 7 is arranged below the balance hole 1101;
wherein, a connecting groove 1103 matched with the commutator 6 is arranged below the first spring hole 1102;
wherein, a first step column 1104 matched with the first bearing 10 is formed outside the balance hole 1101, a second step column 1105 matched with the magnetic ring 9 is formed below the first step column 1104, and a third step column 1106 matched with the second bearing 8 is formed below the second step column 1105.
The commutator 6 of the present invention will be further specifically described with reference to fig. 7 and 8, as follows:
wherein, the commutator 6 is provided with a connecting part 601 matched with the connecting groove;
wherein, the right center of the connecting part 601 forms a second spring hole 602 matched with the pressure spring 7;
a flow guide hole 603 is formed below the second spring hole 602;
wherein, a runner groove 604 communicated with the diversion hole 603 is arranged below the connecting part 601;
wherein, the relative position of the runner groove 604 is provided with a limit groove 605, and the limit groove 605 and the runner groove 604 are separated;
a second sealing surface 606 matched with the first sealing surface 505 is arranged below the limiting groove 605 and the runner groove 604, and the second sealing surface 606 is obtained by grinding to form a mirror surface, so that the frictional resistance is reduced, and the sealing effect is improved;
the limiting groove 605 is provided with a first limiting point 6051 and a second limiting point 6052 which are matched with the limiting device 3, and the first limiting point 6051 and the second limiting point 6052 are symmetrical in position and identical in size.
The second spring hole 602 in the commutator 6 and the first spring hole 1102 in the rotating shaft 11 are provided with a pressure spring 7 with proper elasticity, so that the commutator 6 is always in contact with the static valve disc 5 under the action of the spring pressure of the pressure spring 7, and the purposes are as follows: the second sealing surface 606 in the commutator 6 and the first sealing surface 505 in the static valve disk 5 can obtain the function of automatic compensation under the condition of abrasion, and parts do not need to be replaced.
The commutator 6 and the static valve disc 5 are made of materials with low wear-resistant friction coefficient, and the most preferable material in the invention is ceramic, so that the switching speed is accelerated, and the working efficiency is improved.
The sealing mode adopted by the invention is axial sealing, the sealing mode is realized by the second sealing surface 606 of the commutator 6 and the first sealing surface 505 of the static valve disc 5, and the first sealing surface 505 and the second sealing surface 606 are both mirror-finished, so that the automatic compensation can be realized under the abrasion condition, the sealing effect is consistent with the original sealing effect, and the pressure maintaining is not needed.
The working principle of the invention is further explained:
when one line of a coil stator of the fluid switching valve is connected with the positive pole and the other line is connected with the negative pole, the magnetic ring 9 rotates under the action of electromagnetic induction; meanwhile, a rotating shaft 11 connected with the commutator 6 is also driven to synchronously move; when the stop device 3 contacts the first stop point 6051, the commutator 6 stops moving; at this point, hole B106 is closed and hole C104 communicates with hole a 105, so that input conduit 101 communicates with first output conduit 102;
when the coil stator wiring phase sequence of the fluid switching valve is opposite to the wiring mode, the magnetic ring 9 rotates under the action of electromagnetic induction; meanwhile, a rotating shaft 11 connected with the commutator 6 is also driven to synchronously move; when the stopper 3 comes into contact with the first stopper point 6052, the commutator 6 stops moving; at this time, the a hole 105 is closed and the C hole 104 communicates with the B hole 106, so that the input pipe 101 communicates with the first output pipe 103.
The above embodiments are only for illustrating the technical idea and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the content of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made in accordance with the spirit of the present disclosure are intended to be covered by the scope of the present disclosure.