CN114688284A - Control valve - Google Patents

Abstract

The utility model provides a control valve, including case and valve port portion, valve port portion forms the valve port, control valve has first runner and second runner, first runner and second runner can realize the break-make through the valve port, when case and valve port portion butt, first runner and second runner do not communicate, for plastic material or through setting up the case and correspond and be plastic material with valve port butt portion through setting up the valve port portion, when case and valve port portion butt form sealedly like this, compare with the hard seal of case and the two metalwork butt formation of valve port, better sealed effect has, be favorable to improving the risk of interior hourglass when control valve closes the valve.

Description

Control valve

Technical Field

The application relates to an electric part, in particular to a control valve.

Background

In an air conditioning system or a thermal management system, a control valve is often used as a throttling element, and the control valve can perform forward or backward throttling on working fluid according to the requirements of different working modes of the system. The inventor knows that the valve element and the valve port part form a hard seal by abutting to close the control valve, which may cause the risk of internal leakage due to loose seal.

Disclosure of Invention

An object of the application is to provide a control valve, be favorable to improving the sealed effect when control valve closes the valve, be favorable to improving interior hourglass risk.

In order to achieve the purpose, the following technical scheme is adopted in the application:

a control valve comprising a valve member, the valve member comprising a valve element and a valve port portion, the valve port portion forming a valve port, the valve element being capable of adjusting an opening degree of the valve port close to or away from the valve port, the control valve having a first flow passage and a second flow passage, the first flow passage and the second flow passage being capable of being opened and closed by the valve port, the first flow passage not being communicated with the second flow passage when the valve element abuts against the valve port portion, characterized in that: the valve port part is made of plastic materials, or at least the valve core is made of plastic materials corresponding to the abutting part of the valve port part.

The application provides a control valve, including case and valve port portion, valve port portion forms the valve port, the control valve has first runner and second runner, first runner and second runner can realize the break-make through the valve port, when case and valve port portion butt, first runner and second runner do not communicate, be plastic material for plastic material or through setting up the case correspondence and valve port butt portion, when case and valve port portion butt form sealed like this, compare with the hard seal of two metalwork butt formation of case and valve port, better sealed effect has, be favorable to improving the risk of interior hourglass when the control valve closes the valve.

Drawings

FIG. 1 is a schematic cross-sectional view of a first embodiment of a control valve;

FIG. 2 is a schematic cross-sectional view of the valve member of FIG. 1;

FIG. 3 is an exploded view of the spool assembly of the first embodiment of the control valve;

FIG. 4 is a schematic cross-sectional view of the valve spool assembly of FIG. 1;

FIG. 5 is a cross-sectional structural view of the valve cartridge of FIG. 4;

FIG. 6 is a perspective view of the connecting section of the first embodiment of the control valve;

FIG. 7 is a cross-sectional view of the connector holder of FIG. 6;

FIG. 8 is a cross-sectional structural view of the cartridge seat assembly of FIG. 1;

FIG. 9 is a schematic perspective view of a first embodiment of a cartridge seat assembly of the control valve;

FIG. 10 is another cross-sectional structural schematic view of the first embodiment of the control valve;

FIG. 11 is an enlarged partial view of the portion A of FIG. 10;

FIG. 12 is a cross-sectional structural schematic view of a second embodiment of a control valve;

fig. 13 is a schematic cross-sectional view of a third embodiment of the control valve.

Detailed Description

The present application is further described with reference to the following figures and specific examples:

referring to fig. 1, the control valve 100 includes a driving member 1, a valve member 2, and a valve body member 3, a portion of the valve member 2 is located in a valve body cavity 30 formed by the valve body member 3, the valve member 2 is connected to the valve body member 3, the driving member 1 is located at an outer circumference of the valve member 2, the driving member 1 is connected to the valve member 2, and the control valve 100 is electrically and/or signal-connected to the outside through the driving member 1.

Referring to fig. 1, the driving component 1 includes an outer housing 11, a stator assembly 12 and a connecting interface 13, the stator assembly 12 includes a coil winding 121, and the connecting interface 13 includes a first pin 131, in this embodiment, the coil winding 121 and the first pin 131 are used as injection inserts and are integrally formed into the outer housing 11 by injection molding. The interface 13 and the outer shell 11 are integrally injection molded, one end of the first pin 131 is electrically connected to the coil winding 121, and the other end of the first pin 131 is located in a socket cavity formed by the interface 13 and is electrically connected to the outside. Of course, as another embodiment, the interface 13 and the outer shell 11 may be connected by being assembled and fixed. In the present embodiment, the driving member 1 further includes a fastening portion 14, the fastening portion 14 is fixedly connected to the outer housing 11, and the driving member 1 is connected to the valve member 2 through the fastening portion 14.

Referring to fig. 2, the valve member 2 includes a rotor assembly 21, a connecting seat 22, a screw 23, a valve core assembly 24, a valve core seat assembly 25, and a sleeve 26, the rotor assembly 21 is fixedly connected to one end of the screw 23, the other end of the screw 23 is threadedly connected to the valve core assembly 24, the connecting seat 22 is located at the peripheries of part of the screw 23 and part of the valve core assembly 24, the valve core seat assembly 25 is located at the periphery of part of the valve core assembly 24, the connecting seat 22 is fixedly connected to the valve core seat assembly 25, the sleeve 26 is located at the periphery of the rotor assembly 21, and the sleeve 26 is fixedly connected to the connecting seat 22. The valve core seat assembly 25 comprises a valve port portion which forms a valve port 251, the valve core assembly 24 comprises a valve core 241, the rotor assembly 21 can drive the valve core 241 to perform linear reciprocating motion along the axial direction of the valve component 2 through the screw rod 23, the valve core 241 can be close to or far away from the valve port 251 when moving, and then throttling or on-off can be formed at the valve port 251.

Referring to fig. 2 to 5, the rotor assembly 21 includes a rotor 211 and a connecting member 212, the rotor 211 is fixedly connected to the connecting member 212, and the connecting member 212 is fixedly connected to one end of the screw rod 23. In this embodiment, the connecting member 212 is used as an injection insert, the rotor 211 is formed by injection molding, and the rotor 211 and the connecting member 212 are fixed by injection molding. The connecting member 212 and the lead screw 23 can be fixed by interference fit, welding, or gluing. The valve core assembly 24 further includes a nut member 242, the nut member 242 is made of a plastic material, the nut member 242 can be formed by integral injection molding, the valve core 241 is located on an outer periphery of a portion of the nut member 242, the valve core 241 is fixedly connected with the nut member 242, and specifically, the nut member 242 and the valve core 241 can be fixed by interference fit or glue or injection molding or riveting. In the present embodiment, the spool 241 has a first passage 2411, the spool 241 includes a first mounting portion 2412, the first mounting portion 2412 forms a first mounting chamber 2413, and with respect to the spool 241, the first mounting chamber 2413 communicates with the first passage 2411. The nut member 242 comprises a limiting portion 244 and a threaded portion 245, the limiting portion 244 and the threaded portion 245 are integrally injection-molded, the nut member 242 is approximately T-shaped in appearance, the threaded portion 245 is located in the first installation cavity 2413, and the threaded portion 245 is in interference fit with the first installation portion 2412 to achieve fixed connection of the nut member 242 and the valve core 241; further, in order to reinforce the fixed connection between the valve core 241 and the nut member 242, the valve core 241 further includes first riveting portions 2414, the first riveting portions 2414 are higher than the first mounting portion 2412 in the axial direction of the valve core 241, the first riveting portions 2414 are located on two sides of the first mounting portion 2412 and can be symmetrically distributed in the radial direction of the valve core 241, a first step portion 2415 is formed between the first riveting portion 2414 and the first mounting portion 2412, riveting convex portions 2416 for riveting are arranged on the first riveting portion 2414, the riveting convex portions 2416 are arranged at intervals, riveting grooves 2417 are formed between two adjacent riveting convex portions 2416, and the purpose of arranging the riveting grooves 2417 is to realize the communication of later middle balance channels. The thread portion 245 is located in the first mounting cavity 2413, the thread portion 245 is in interference fit with the first mounting portion 2412, the limiting portion 244 abuts against the first stepped portion 2415, and the riveting convex portion 2416 is bent and pressed against the limiting portion 244, so that the limiting portion 244 is pressed between the riveting convex portion 2416 and the first stepped portion 2415, and the nut member 242 and the valve element 241 are fixedly connected. The nut member 242 further has a threaded hole 243, the threaded hole 243 is disposed through the nut member 242, an internal threaded section is disposed on the peripheral side wall forming the threaded hole 243, correspondingly, an external threaded section matched with the internal threaded section is disposed on the other end of the screw 23, and the screw 23 extends into the threaded hole 243, so that the external threaded section of the screw 23 is in threaded fit with the internal threaded section of the nut member 242, thereby realizing the threaded connection of the screw 23 and the valve core assembly 24. The screw 23 and the nut piece 242 are in threaded connection, and compared with the direct threaded connection between the screw 23 and the valve core 241, the threaded connection is beneficial to reducing thread abrasion.

Referring to fig. 2, 3, 6 and 7, the connecting seat 22 includes a first accommodating portion 221, the first accommodating portion 221 forms a first accommodating cavity 222, a part of the screw 23 and a part of the valve core assembly 24 are located in the first accommodating cavity 222, the first accommodating portion 221 includes a matching portion 223, the limiting portion 244 is located in the first accommodating cavity 222, the limiting portion 244 is a non-rotating body, the limiting portion 244 and the matching portion 223 can be matched with each other to limit circumferential rotation of the valve core assembly 24, and the structures of the limiting portion 244 and the matching portion 223 can be various as long as circumferential rotation of the valve core assembly 24 can be limited. In the present embodiment, the limiting portion 244 includes a limiting portion side surface 2441, accordingly, the engaging portion 223 includes an engaging portion side surface 2231, and the limiting portion 244 is located in the first accommodating cavity 222, so that the limiting portion side surface 2441 and the engaging portion side surface 2231 are attached to each other, and the circumferential rotation of the valve core assembly 24 is limited. It should be noted that, in order to enable the valve core assembly 24 to perform linear reciprocating motion along the axis of the valve member 2, the axial height H of the matching portion 223 needs to be larger than the axial height H of the limiting portion 244, and specifically, the proportional relationship between the axial height H of the matching portion 223 and the axial height H of the limiting portion 244 can be designed and determined according to the specific motion stroke of the valve core assembly 24. For example, in the present embodiment, the axial height H of the fitting portion 223 is 4.2 times the axial height H of the stopper portion 244.

Referring to fig. 2, the valve component 2 further includes a supporting member 27, specifically, the supporting member 27 includes a supporting frame 271, a bearing 272 and a sleeve 273, the supporting frame 271 has a placing cavity 274, the supporting frame 271 is fixedly connected with the connecting seat 22, and the placing cavity 274 is communicated with the first accommodating cavity 222. In this embodiment, the supporting frame 271 and the connecting seat 22 are fixed by welding, but of course, the supporting frame 271 and the connecting seat 22 can also be fixed by interference fit or other methods such as glue. In addition, the supporting frame 271 and the connecting seat 22 can also be integrally formed. Part of the screw 23 is located in the placing cavity 274, the bearing 272 is located on the outer periphery of the screw 23, the bearing 272 is located in the placing cavity 274, and the bearing 272 is fixedly connected with the support frame 271. Further, in order to prevent the second riveting portion 276 from damaging the bearing 272 during riveting, the supporting member 27 may further include a first retainer ring 277, the first retainer ring 277 is located on the outer periphery of the screw 23, the first retainer ring 277 is located in the placing cavity 274, along the axial direction of the supporting member 27, the bearing 272 is located between the first retainer ring 277 and the second step portion 275, the first retainer ring 277 is located closer to the second riveting portion 276 than the second step portion 275, during riveting, the second riveting portion 276 is bent and pressed against the first retainer ring 277, so that the bearing 272 is pressed between the second step portion 275 and the first retainer ring 277, and the fixing of the bearing 272 is realized. The sleeve 273 is located at the periphery of the screw 23, at least a part of the sleeve 273 is located in the placing cavity 274, the sleeve 273 is fixedly connected with the screw 23, and specifically, the sleeve 273 and the screw 23 can be fixed in an interference fit manner or a welding manner or an adhesive manner. The lead screw 23 includes a flange portion 231, the flange portion 231 is outwardly protruded in a radial direction of the lead screw 23, the bearing 272 is located between the sleeve 273 and the flange portion 231 in an axial direction of the lead screw 23, the flange portion 231 is disposed closer to the attachment seat 22 than the sleeve 273, the lead screw 23 is axially restrained by the flange portion 231 and the sleeve 273, specifically, when the lead screw 23 is supposed to move in a direction away from the attachment seat 22 in the axial direction, the lead screw 23 abuts against the bearing 272 by the flange portion 231 to restrain the movement of the lead screw 23; when the screw 23 is assumed to move in the direction approaching the connection base 22 in the axial direction, the screw 23 abuts on the bearing 272 through the sleeve 273, and the movement of the screw 23 is limited.

Referring to fig. 2, 7 and 8, the connection socket 22 further includes a second receiving portion 224, the second receiving portion 224 forming a second receiving cavity 225, and the second receiving cavity 225 communicates with the first receiving cavity 222 with respect to a single component of the connection socket 22. Part of the valve core seat assembly 25 is located in the second accommodating cavity 225, and the valve core seat assembly 25 and the connecting seat 22 can be fixedly connected in an interference fit manner, or in a welding manner, or in an adhesive manner. The valve core seat assembly 25 includes a valve core seat 252, a first sealing assembly 253 and a fixing seat 254, the first sealing assembly 253 includes a first sealing ring 2531 and a first sealing member 2532, the first sealing ring 2531 may be formed by integral injection molding of polyether ether ketone (PEEK) material, and of course, the first sealing ring 2531 may also be made of other plastic materials with hardness and elasticity. The valve core seat 252 has a valve core cavity 256, a portion of the fixing seat 254 is located in the valve core cavity 256, and the fixing seat 254 is fixedly connected with the valve core seat 252, specifically, the fixing connection can be achieved through interference fit, welding, or gluing. Referring to fig. 2, a part of the valve core seat 252 is located in the second accommodating cavity 225 of the connecting seat 22, and the valve core seat 252 is fixedly connected with the connecting seat 22, and the valve core seat 252 is located between the connecting seat 22 and the fixed seat 254 in the axial direction of the valve component 2. The fixed seat 254 is fixedly assembled with the valve core seat 252 to form a receiving groove, a part of the first sealing assembly 253 is located in the receiving groove, specifically, the first sealing ring 2532 and a part of the first sealing ring 2531 are located in the receiving groove, the first sealing ring 2531 includes a first concave portion, a part of the first sealing ring 2532 is located in a first concave cavity formed by the first concave portion, the first sealing member 2532 is compressed between the first concave portion and an inner side wall surface of the valve core seat 252 in a radial direction of the first sealing assembly 253, and the first sealing member 2532 is in a sealing state. Of course, as another embodiment, the first sealing ring 2531 may not include the first recess, i.e., the first sealing ring 2532 is directly compressed between the outer sidewall of the first sealing ring 2531 and the inner sidewall surface of the valve seat 252. It should be noted that the sealing manner of the first sealing member 2531 is not limited to the above manner, as long as the sealing manner can be formed to prevent the inner leakage between the valve core seat 252 and the fixed seat 254. Referring to fig. 8, the valve core seat 252 further includes a protrusion 255, the protrusion 255 protrudes inward in the radial direction of the valve core seat 252, and the first sealing assembly 253 is located between the protrusion 255 and the end surface of the fixed seat 254 in the axial direction of the valve core seat assembly 25, and the first sealing assembly 253 is axially limited by the protrusion 255 and the end surface of the fixed seat 254. It should be noted that defining an axial stop includes the first seal assembly 253 being clamped between the protrusion 255 and the anchor block 254.

Referring to fig. 2 and 8, a portion of the spool 241 is located in the spool chamber 256, and the first seal assembly 253 is located at an outer periphery of the spool 241, and specifically, the first seal ring 2531 is located at an outer periphery of the spool 241. The radial width D of the protrusion 255 is smaller than the radial width D of the cross section of the first sealing ring 2531, or in the radial direction of the valve core seat assembly 25, the first sealing ring 2531 is arranged closer to the valve core 241 than the protrusion 255, so that when the valve core 241 linearly reciprocates in the axial direction in the valve core cavity 256, the valve core 241 can abut against the first sealing ring 2531, and the valve core 241 forms a seal with the first sealing ring 2531, that is, in the present embodiment, the first sealing ring 2531 includes a valve port portion, which forms the valve port 251, and by providing the first sealing ring 2531 to form the valve port 251, compared with forming the valve port by a metal member, when the control valve 100 is closed, a better seal can be formed between the valve core 241 and the valve port portion, which is beneficial to improving internal leakage.

Referring to fig. 2 and 7, the valve component 2 further includes a second sealing assembly 28 and a second retainer ring 29, the second sealing assembly 28 is located at the periphery of the valve core 241, the second retainer ring 29 is located at the periphery of the valve core 241, the second sealing assembly 28 and the second retainer ring 29 are both located in the second accommodating cavity 225 of the connecting seat 22, and the second retainer ring 29 is fixedly connected with the connecting seat 22, specifically, the second retainer ring 29 and the connecting seat 22 may be fixedly connected by interference fit, welding, or gluing. The connecting seat 22 is formed with a boss portion 226 between the first accommodating portion 221 and the second accommodating portion 224, the second seal assembly 28 is located between the boss portion 226 and the second retainer ring 29 in the axial direction of the valve member 2, the second retainer ring 29 is disposed closer to the second seal assembly 28 than the valve core seat 252, and the second seal assembly 28 is axially restrained by the boss portion 226 and the second retainer ring 29. The second seal assembly 28 includes a second seal ring 281 and a second seal 282, the material of the second seal ring 281 may be the same as that of the first seal ring 2531, the second seal ring 281 is located at the outer periphery of the valve core 241, the second seal ring 281 is in interference fit with the valve core 241, so that the second seal ring 281 is in close contact with the outer surface of the valve core 24 to seal the valve core 24, the second seal ring 281 includes a second recess, a part of the second seal 282 is located in a second cavity formed by the second recess, the second seal 282 is compressed between the second recess and the sidewall of the second accommodating portion 224 in the radial direction of the second seal assembly 28, and the second seal 282 is in a sealing compressed state.

Referring to fig. 1 and 2, the valve body part 3 includes a main valve body 31, a first adapter 32 and a second adapter 34, the main valve body 31 forms a valve body cavity 30, a part of the valve part 2 is located in the valve body cavity 30, the valve part 2 is fixedly connected with the main valve body 31, and specifically, the valve part 2 and the valve body part 3 can be fixedly connected by interference fit or snap fit or welding or gluing. In the present embodiment, the valve member 2 and the main valve body 31 are fixed by welding, specifically, one end of the main valve body 31 is fixed by welding with the connecting seat 22, and the other end of the main valve body 31 is fixed by welding with the fixing seat 254. The first connecting pipe 32 is welded and fixed with the main valve body 31, the first connecting pipe 32 forms a first flow passage 33, and the first flow passage 33 is communicated with the valve body cavity 30; the second connection pipe 34 is welded and fixed to the fixed seat 254, the second connection pipe 34 forms a second flow passage 35, and the second flow passage 35 communicates with the first hole 2411 of the valve body 241. Along with the axial linear motion of the valve core 241, the first flow passage 32 and the second flow passage 33 can be opened, closed and throttled through the valve port 251, specifically, after the driving component 1 is electrified, the driving component 1 generates an excitation magnetic field through the stator assembly 12, the rotor assembly 21 is fixedly connected with the screw rod 23, the rotor assembly 21 drives the screw rod 23 to rotate together under the excitation of the magnetic field of the stator assembly 12, the screw rod 23 is in threaded connection with the valve core assembly 24, the screw rod 23 is axially limited through the bearing 272, the valve core assembly 24 is circumferentially limited through the connecting seat 22, the connecting seat 22 is fixedly arranged with the valve body component 3, thus, under the action of the threads, the valve core 241 can linearly reciprocate along the axial direction of the valve component 2, and when the valve core linearly reciprocates along the axial direction, the opening degree of the valve port 251 can be adjusted by approaching or departing from the valve port 251, thereby forming throttling or opening at the valve port 251, thus, the first flow passage 32 and the second flow passage 33 can be opened and closed and throttled by the valve port 251. In addition, in the present embodiment, the linear movement stroke of the spool 241 is limited by the flange portion 231 and the valve port portion of the screw 23, that is, when the spool 241 linearly moves upward in the axial direction of the valve member 2, the spool 241 is limited by abutment with the flange portion 231 by the limiting portion 244, and when the spool 241 linearly moves downward in the axial direction of the valve member 2, the spool 241 is limited by abutment with the valve port portion.

Referring to fig. 8 and 9, the valve core seat 252 further includes at least two through hole portions 257, the through hole portions 257 are distributed along an outer peripheral wall of the valve core seat 252 in an equal circumference manner, the through hole portions 257 penetrate through an outer peripheral wall of the valve core seat 252, a bore formed by the through hole portions 257 is communicated with the valve core cavity 256, a fluid area of the bore formed by the through hole portions 257 is larger than a fluid area formed by the valve port 251, the through hole portions 257 are arranged in a substantially flat hole shape, the through hole portions 257 include a first section 2571, a second section 2572, a third section 2573 and a fourth section 2574, the first section 2571 and the second section 2572 are distributed along an axial direction of the valve core seat 252, the first section 2571 is arranged farther away from an upper end face of the valve core seat 252 than the second section 2572, the third section 2573 and the fourth section 2574 are respectively located at two sides of the first section 2571 and the second section 2572, and the third section 2573 and the fourth section 2574 are symmetrically distributed. A plane is defined, which is parallel to the central axis of the valve core seat 252, along the axial direction of the valve core seat 252, the maximum axial distance of the projections of the first section 2571 and the second section 2572 on the plane is L1, and along the radial direction of the valve core seat 252, the minimum radial distance of the projections of the third section 2573 and the fourth section 2574 on the plane is L2, and L1 < L2.

In this embodiment, specifically, the first section 2571 is a first flat arc section, the second section 2572 is a second flat arc section, the third section 2573 is a first arc section, the fourth section 2574 is a second arc section, the surfaces of the first and second flat arc sections are both flat arc surfaces, the surfaces of the first and second arc sections are both arc surfaces, along the axial direction of the valve core seat 252, the first and second flat arc sections are arranged in parallel, the first and second arc sections are respectively located on both sides of the first and second flat arc sections and symmetrically distributed, one end of the first flat arc section is connected to one end of the first arc section, the other end of the first flat arc section is connected to one end of the second arc section, the other end of the first arc section is connected to one end of the second flat arc section, and the other end of the second flat arc section is connected to the other end of the second arc section. The through hole 257 is a flat hole, which is more advantageous to reduce the axial height of the valve core seat 252 and thus the axial height of the control valve 100, compared to a circular hole.

In addition, as the through hole parts 257 are distributed along the periphery of the valve core seat 252, in order to ensure the connection strength of the through hole parts 257, along the axial direction of the valve core seat 252, the minimum axial distance of the projection of the second section 2572 and the upper end surface of the valve core seat 252 on the plane is L3, the minimum axial distance of the projection of the first section 2571 and the lower end surface of the valve core seat 252 on the plane is L4, L4 is greater than L3, and L3 is greater than or equal to 1.5 mm; along the circumferential direction of the outer peripheral wall of the valve core seat 252, a spacing part is formed between two adjacent through hole parts, along the radial direction of the valve core seat 252, the minimum radial distance of the projection of the spacing part on the plane is L5, and L5 is more than or equal to 1.5 mm.

Referring to fig. 1, in the operation process of the control valve 100, when the first flow passage 33 is used as a working fluid inlet flow passage and the second flow passage 35 is used as a working fluid outlet flow passage, the flow direction of the fluid at this time is defined as a forward flow, the high-pressure working fluid flows into the valve body chamber 30 from the first flow passage 33, flows into the spool chamber 256 after flowing through the bore formed by the through hole portion 257, and is throttled by the valve port 251 to become low-pressure working fluid, and flows out of the second flow passage 35 to the subsequent system circuit. It should be noted that, by providing the through hole portion 257 to be distributed along the circumference of the outer peripheral wall of the valve core seat 252, radial impact on the valve core 241 when the high-pressure working fluid flows in from the first flow passage 33 is balanced, which is beneficial to the stable operation of the valve core 241.

Referring to fig. 1, when the second flow passage 35 is used as an inlet flow passage of the working fluid, and the first flow passage 33 is used as an outlet flow passage of the working fluid, the flow direction of the fluid is defined as a reverse flow at this time, when the high-pressure working fluid flows from the second flow passage 35, the fluid will act on the free end portion of the valve core 241, and will generate an axially upward acting force on the valve core 241, so that the valve core 241 and the valve port 251 are not tightly closed, or the output torque of the driving part 1 needs to be increased to drive the valve core 241 to move, in order to eliminate or alleviate the pressure action of the high-pressure working fluid on the valve core 241, so that the valve core assembly 24 operates stably, the control valve 100 further includes a balance passage, specifically, referring to fig. 3, in this embodiment, the nut 242 further includes a groove part 2421, the groove part 2421 is formed by recessing from the outer side wall surface of the nut 242 in the radial direction of the nut 242, and in the axial direction of the nut 242, one end of the groove part 2421 extends to the free end surface of the limiting part 244 and is arranged flush with the free end surface of the limiting part 244, the other end of the groove part 2421 extends to the first end surface 2451 of the thread part 245 and is arranged flush with the first end surface 2451, the thread part 245 further comprises a second end surface 2452, the second end surface 2452 is higher than the first end surface 2451 in the axial direction of the nut piece 242, the second end surface 2452 and the first end surface 2451 are alternately distributed along the circumference of the thread part 242, the number of the groove parts 2421 is at least one, in the embodiment, the number of the groove parts 2421 is two, and the groove parts are symmetrically arranged on the outer side wall of the nut piece 242. Referring to fig. 3, 5, 10, and 11, when the nut member 242 is fixedly assembled with the valve spool 241, at least a part of the threaded portion 245 is located in the first mounting cavity 2413 of the valve spool 241, the groove portion 2421 of the nut member 242 and the first mounting portion 2412 of the valve spool 241 are assembled to form a balance groove cavity 2423, the balance groove cavity 2423 communicates with the first duct 2411 and the first accommodation cavity 222, and specifically, the balance groove cavity 2423 communicates with the first accommodation cavity 222 through a gap formed by the rivet groove 2417; the balance groove cavity 2423 is communicated with the first duct 2411 through a gap formed between the first end face 2451 and the second end face 2452. It should be noted that, as another embodiment, threaded portion 245 may not include second end face 2452, and second end face 2452 may be configured to direct fluid flow through balance cavity 2423. In addition, the groove part 2421 is arranged on the outer side wall of the nut member 242, and the balance channel is realized in a mode of forming the balance groove cavity 2423 by being matched with the first mounting part 2412, so that the strength of the nut member 242 under the action of high-pressure fluid is favorably ensured.

Referring to fig. 1, 10 and 11, when high-pressure fluid flows in from the second flow passage 35, a part of the high-pressure fluid can flow through the first passage 2411 and then flow into the first accommodating chamber 222 through the balancing groove chamber 2423, so that the high-pressure working medium can be located on the back pressure side of the valve core assembly 24, the high-pressure fluid located in the first accommodating chamber 222 is sealed by the second sealing assembly 28, the high-pressure fluid is prevented from communicating with the throttled low-pressure fluid located in the valve core chamber 256, the high-pressure working medium located in the first accommodating chamber 222 will act on the valve core assembly 24, and an axially downward acting force will be generated on the valve core assembly 24, so that the valve core assembly 24 is subjected to two pressures in opposite directions in the axial direction, which is beneficial to balancing or tending to balancing the force applied to the valve core assembly 24, and is beneficial to stable operation of the valve core assembly 24. Part of the high-pressure fluid can be throttled by the valve port 251 and changed into low-pressure fluid to flow into the spool chamber 256, and flow to the first flow passage 33 through the bore formed by the through hole portion 257 and to the subsequent circuit. It should be noted that the provision of the balance groove 2423 is beneficial to quickly achieve pressure balance between the two ends of the valve core assembly 24, but as another embodiment, the nut member 242 may not include the groove part 2421, for example, the first passage 2411 and the first accommodating chamber 222 may only communicate with the screw rod 23 through the screw fit clearance of the nut member 242, or a through hole may be provided inside the nut member 242 to communicate the first passage 2411 and the first accommodating chamber 222, in the case that the strength of the nut member 242 is ensured. The form of the balance passage may be various as long as it can communicate the first passage 2411 and the first receiving chamber 222.

Referring to fig. 12, in order to implement the second embodiment of the control valve, in the second embodiment, the valve component 2 'includes a valve core 24' and a valve core seat 25 ', the valve core 24' is made of a non-metal material, in this embodiment, the valve core 24 'is made of a Polyetheretherketone (PEEK) material by integral injection molding, but the valve core 24' may also be made of other plastic materials with hardness and elasticity. The valve core 24 ' includes a limiting portion 244 ', the limiting portion 244 ' is located in the first accommodating cavity 222 of the connecting seat 22, the limiting portion 244 ' is matched with the matching portion of the connecting seat 22 to limit the circumferential rotation of the valve core 24 ', the structure of the limiting portion 244 ' may be the same as that of the limiting portion 244 in the first embodiment, and the limiting matching manner between the limiting portion 244 ' and the matching portion may be the same as that in the first embodiment, which is not described herein again. The valve core 24 'is provided with a first hole 2411 and a threaded hole 243', as for a single part of the valve core 24 ', the first hole 2411 is communicated with the threaded hole 243', an internal thread section is arranged on the peripheral side wall forming the threaded hole 243 ', an external thread section is arranged at one end of the screw rod 23, one end of the screw rod 23 provided with the external thread section extends into the threaded hole 243' and is in threaded fit with the internal thread section of the valve core 24 ', and threaded connection between the screw rod 23 and the valve core 24' is realized. The valve core 24' is made of plastic material (such as PEEK material), which is beneficial to reducing the thread abrasion between the valve core and the screw rod 23. The valve core seat 25 ' is a metal piece, the valve core seat 25 ' is integrally formed, the valve core seat 25 ' is located on the periphery of the valve core 24 ', and the valve core seat 25 ' is fixedly connected with the connecting seat 22, specifically, the fixed connection can be realized by welding, interference fit, glue or the like. The valve core seat 25 ' comprises a valve port part which forms a valve port 251 ', when the valve core 24 ' linearly reciprocates along the axial direction of the valve component 2 ', the valve core 24 ' can be close to or far away from the valve port 251 ', and then throttling or on-off is formed at the valve port 251 ', and the valve core 24 ' is made of non-metal materials (such as PEEK materials), so that when the control valve 100 ' closes, better sealing can be formed between the valve core 24 ' and the valve port part, internal leakage can be improved, and in addition, the structure of the valve core seat 25 ' can be simplified. In this embodiment, the valve core 24 'further has at least one balancing through hole 246, the balancing through hole 246 is communicated with the first passage 2411 and the first accommodation chamber 222, the second connection pipe 34 is welded and fixed to the valve core seat 25', the second connection pipe 34 forms the second flow passage 35, and the second flow passage 35 is communicated with the first passage 2411, so that when a high-pressure fluid flows in from the second flow passage 35, a part of the high-pressure fluid flows into the first accommodation chamber 222 through the balancing through hole 246 after flowing through the first passage 2411, so that the force of the valve core 24 'is balanced or tends to be balanced, which is beneficial to stable operation of the valve core 24'. The structure of the other parts of the control valve 100' is substantially the same as that of the first embodiment, and thus, the description thereof is omitted.

Referring to fig. 13, in a third embodiment of the control valve, in the third embodiment, the valve component 2 "includes a valve core assembly 24" and a valve core seat assembly 25 ", the valve core assembly 24" includes a valve core 241 "and a nut member 242", the valve core 241 "is used as an injection insert, the nut member 242" is formed by integral injection molding of a plastic material, and the valve core 241 "and the nut member 242" are fixed by injection molding. The nut member 242 "has a threaded hole 243", the valve core 241 "has a first passage 2411, for the valve core assembly 24", the threaded hole 243 "is communicated with the first passage 2411, an internal thread section is arranged on the peripheral side wall forming the threaded hole 243", an external thread section is arranged on one end of the screw rod 23, one end of the screw rod 23 provided with the external thread section extends into the threaded hole 243 ", and is in threaded fit with the internal thread section of the nut member 242", so that the threaded connection between the screw rod 23 and the valve core assembly 24 "is realized. The valve core seat assembly 25 "comprises a valve core seat 252" and a first sealing ring 253 ", wherein the valve core seat 252" is integrally formed by machining, and the valve core seat 252 "is taken as an injection molding insert and is integrally formed into the first sealing ring 253" by injection molding. In the present embodiment, the first sealing ring 253 "is injection molded from a Polyetheretherketone (PEEK) material, but the first sealing ring 253" may also be made of other plastic materials having hardness and elasticity. The valve core seat assembly 25 "is located at the periphery of the valve core 241", the valve core assembly 25 "is fixedly connected with the connecting seat 22, specifically, the valve core assembly 25" is fixedly connected with the connecting seat 22 through the valve core seat 252 ", and the valve core seat 252" and the connecting seat 22 can be fixedly connected through welding, interference fit, glue or other manners. The first sealing ring 253 "includes a valve port portion forming the valve port 251", and the valve body 241 "can approach or separate from the valve port 251" when linearly reciprocating in the axial direction of the valve member 2 ", thereby forming throttling or opening/closing at the valve port 251". In this embodiment, the balance channel is disposed on the screw rod 23, the balance channel includes a first channel section 232 and a second channel section 233, the first channel section 232 is disposed along an axial direction of the screw rod 23, the second channel section 233 is disposed along a radial direction of the screw rod 23, the first channel section 232 is communicated with the second channel section 233, the number of the second channel section 233 is at least one, the balance channel is communicated with the first passage 2411 and the first accommodating cavity 222 of the connecting seat 22, specifically, the first channel section 232 is communicated with the first passage 2411 and the second channel section 232, and the second channel section 232 is communicated with the first accommodating cavity 222. The second connecting pipe 34 is welded and fixed with the valve core seat 252 ″, the second connecting pipe 34 forms a second flow passage 35, and the second flow passage 35 is communicated with the first hole 2411, so that when high-pressure fluid flows in from the second flow passage 35, after a part of the high-pressure fluid flows through the first hole 2411, the high-pressure fluid flows into the first accommodating cavity 222 through the first channel section 232 and the second channel section 233, so that the stress of the valve core assembly 24 ″ is balanced or tends to be balanced, and the stable operation of the valve core assembly 24 ″ is facilitated. It should be noted that: with reference to the first embodiment and the third embodiment, it can be derived that in the first embodiment, the valve core can be used as an injection molding insert, the nut member is formed by injection molding, and the balance channel is formed by the screw rod; or in the first embodiment, the valve core seat and the fixed seat are integrally processed and formed, and the integrally formed valve core seat is used as an injection molding insert to form the first sealing ring with the valve port by injection molding, so that the structure and the assembly are simple. The structure of the other parts of the control valve 100 "is substantially the same as that of the first embodiment, and will not be described again.

It should be noted that: although the present application has been described in detail with reference to the foregoing embodiments, those skilled in the art will understand that modifications and equivalents may be made thereto, and all technical solutions and modifications that do not depart from the spirit and scope of the present application are intended to be covered by the claims of the present application.

Claims (9)

1. A control valve comprising a valve member including a valve element and a valve port portion, the valve port portion forming a valve port, the valve element being capable of adjusting an opening degree of the valve port close to or away from the valve port, the control valve having a first flow passage and a second flow passage, the first flow passage and the second flow passage being capable of being opened and closed by the valve port, the first flow passage and the second flow passage not being communicated when the valve element is abutted against the valve port portion, characterized in that: the valve port part is made of plastic materials, or at least the valve core is made of plastic materials corresponding to the abutting part of the valve port part.

2. The control valve of claim 1, wherein: the valve component further comprises a valve core seat, a fixed seat and a first sealing assembly, the valve core seat is fixedly connected with the fixed seat, the valve core seat and the fixed seat are assembled to form a containing groove, part of the first sealing assembly is located in the containing groove, the first sealing assembly is located on the periphery of the valve core, the first sealing assembly is axially limited through the valve core seat and the fixed seat, the first sealing assembly comprises a valve opening portion, and the valve opening portion is formed by injection molding of plastic materials.

3. The control valve of claim 2, wherein: the first sealing assembly comprises a first sealing ring and a first sealing piece, the first sealing ring comprises a first concave portion, the first sealing ring is located on the periphery of the valve core, part of the first sealing piece is located in a first cavity formed by the first concave portion, the first sealing piece is pressed between the first concave portion and the inner side wall of the valve core seat, the first sealing ring is integrally formed by injection molding of a plastic material, and the first sealing ring comprises the valve port portion.

4. The control valve according to claim 2 or 3, wherein: the valve core seat comprises a protruding portion, the protruding portion protrudes inwards along the radial direction of the valve core seat, the first sealing assembly is located between the protruding portion and the end face of the fixed seat along the axial direction of the valve component, the first sealing assembly performs axial limiting through the protruding portion and the end face of the fixed seat, and the first sealing assembly is arranged close to the valve core than the first protruding portion along the radial direction of the valve core seat.

5. The control valve of claim 1, wherein: the valve component further comprises a valve core seat and a first sealing ring, the valve core seat is used as an injection molding insert, the first sealing ring is integrally injection molded, the first sealing ring and the valve core seat are fixed in an injection molding mode, the first sealing ring is located on the periphery of the valve core, and the first sealing ring comprises the valve opening portion.

6. The control valve of claim 1, wherein: the valve component further comprises a valve core seat, the valve core seat is integrally processed and formed, the valve core seat is located on the periphery of the valve core, the valve core seat comprises the valve opening portion, and the valve core is integrally formed by injection molding of plastic materials.

7. The control valve according to any one of claims 2 to 5, wherein: the valve component further comprises a screw rod, a rotor component and a threaded component, the threaded component is formed by injection molding of a plastic material, the valve core is located on part of the periphery of the nut component, the valve core is fixedly connected with the nut component, the nut component is provided with a threaded hole to form an internal threaded section on the peripheral side wall of the threaded hole, one end of the screw rod is provided with an external threaded section, one end of the screw rod, provided with the external threaded section, extends into the threaded hole to be in threaded fit with the internal threaded section, the other end of the screw rod is fixedly connected with the rotor component, and the rotor component can drive the valve core to be abutted to the valve port through the screw rod.

8. The control valve of claim 6, wherein: the valve component further comprises a screw rod and a rotor component, the valve core is provided with a threaded hole, an internal thread section is arranged on the peripheral side wall forming the threaded hole, an external thread section is arranged at one end of the screw rod, provided with the external thread section, extends into the threaded hole to be in threaded fit with the internal thread section, the other end of the screw rod is fixedly connected with the rotor component, and the rotor component can drive the valve core to be abutted against the valve port through the screw rod.

9. The control valve according to claim 7 or 8, characterized in that: the valve core seat comprises through hole parts, the valve core seat is provided with valve core cavities, the number of the through hole parts is at least two, the through hole parts are in a flat hole shape, the through hole parts are distributed along the periphery wall of the valve core seat in an equal circumference mode, part of the valve core is located in the valve core cavities, the hole cavity formed by the through hole parts is communicated with the first flow channel and the valve core cavities, the valve core cavities and the second flow channels can be connected and disconnected through the valve port, and when the valve core is abutted to the valve port, the valve core cavities are not communicated with the second flow channels.

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