CN210566332U - Axial flow type electromagnetic valve - Google Patents

Abstract

The application relates to the technical field of electromagnetic valves, in particular to an axial-flow electromagnetic valve. The axial flow type electromagnetic valve comprises a flow pipe, a valve seat assembly, an electromagnetic driving assembly and a valve main body; the circulating pipe, the valve seat assembly and the electromagnetic driving assembly are all positioned in the valve main body; the electromagnetic driving assembly is arranged around the circulating pipe in a surrounding mode, the valve seat assembly is located at one end of the circulating pipe and connected with the valve main body and corresponds to a flow channel opening in the valve main body; the electromagnetic driving assembly is used for driving the circulating pipe to move in the valve main body along the medium circulating direction so as to abut against or be far away from the valve seat assembly; when the circulation pipe is abutted against the valve seat assembly, the circulation pipe and the runner port are closed; when the circulation pipe is far away from the valve seat assembly, the circulation pipe is communicated with the flow port. The axial-flow type electromagnetic valve reduces the size in the height direction, and reduces the space required for installing the axial-flow type electromagnetic valve when the axial-flow type electromagnetic valve is connected into a pipeline. The axial flow type electromagnetic valve is simple in structure, can realize bidirectional conduction of media, and expands application scenes of the axial flow type electromagnetic valve.

Description

Axial flow type electromagnetic valve

Technical Field

The application relates to the technical field of electromagnetic valves, in particular to an axial-flow electromagnetic valve.

Background

The electromagnetic operating mechanism of the electromagnetic valve is used for controlling the connection or disconnection of the valve. In the existing solenoid valve, the electromagnetic operating mechanism is generally arranged perpendicular to the medium flow pipeline of the solenoid valve, so that the size of the solenoid valve in the direction perpendicular to the medium flow pipeline is larger, and the solenoid valve occupies a larger space when being installed in the pipeline.

SUMMERY OF THE UTILITY MODEL

An object of the application is to provide an axial flow solenoid valve for reduce the occupation to the space when the solenoid valve is installed in the pipeline.

The application provides an axial-flow electromagnetic valve, which comprises a flow pipe, a valve seat assembly, an electromagnetic driving assembly and a valve main body;

the flow tube, the valve seat assembly and the electromagnetic drive assembly are all located within the valve body;

the electromagnetic driving assembly is arranged around the circulating pipe in a surrounding mode, the valve seat assembly is located at one end of the circulating pipe and connected with the valve main body and corresponds to a flow passage opening in the valve main body; the electromagnetic driving assembly is used for driving the circulation pipe to move in the medium circulation direction in the valve main body so as to abut against or be far away from the valve seat assembly;

when the circulation pipe abuts against the valve seat assembly, the circulation pipe and the flow port are closed; when the flow pipe is far away from the valve seat assembly, the flow pipe is communicated with the flow port.

In the above technical solution, further, the valve seat assembly includes a mounting seat and a sealing gasket;

the mounting seat is connected with the valve main body, the sealing gasket is mounted on the mounting seat, and the end part of the circulating pipe can abut against the sealing gasket;

the mounting seat is provided with a circulation gap, the circulation gap is arranged outside the range covered by the end part of the circulation pipe, and the circulation gap is used for communicating the runner port and the circulation pipe.

In the above technical solution, further, the valve seat assembly further includes a connecting member and a crimping member;

the middle part of the mounting seat is provided with a mounting groove, and the sealing gasket is arranged in the mounting groove;

the crimping piece with the sealed pad has seted up the through-hole, the blind hole has been seted up to the mount pad, the connecting piece passes in proper order the crimping piece reaches behind the sealing pad with the mount pad is connected, be used for right the sealed pad fastening.

In the above technical solution, further, the electromagnetic driving assembly includes a stationary core, a movable core, a coil assembly and an installation shell;

the static iron core is arranged around the circulating pipe in a surrounding mode, and a first accommodating cavity is formed between the static iron core and the circulating pipe;

the movable iron core is connected with the circulating pipe and can move in the first accommodating cavity along the medium circulating direction;

the holding tank has been seted up to quiet iron core, the installation shell is detained and is established the notch department of holding tank forms the second and holds the chamber, coil pack is located the second holds the intracavity.

In the above technical solution, further, the stationary core includes a first magnetic conductive portion and a second magnetic conductive portion;

the first magnetic conduction part is connected with the second magnetic conduction part and surrounds to form the accommodating groove.

In the above technical solution, further, the electromagnetic driving assembly further includes a return elastic member;

the reset elastic piece is positioned at one end of the circulating pipe far away from the valve seat assembly, one end of the reset elastic piece is connected with the circulating pipe, the other end of the reset elastic piece is connected with the valve main body, and the reset elastic piece has a driving force for driving the circulating pipe to move towards the valve seat assembly.

In the above technical solution, further, the lead wire assembly is further included;

the lead assembly is installed outside the electromagnetic driving assembly and is electrically connected with the coil assembly.

In the above technical solution, further, the sealing device further includes a sealing assembly;

the sealing assemblies are arranged at two ends of the electromagnetic driving assembly and are connected with the valve main body;

the seal assembly is formed with a through-hole through which the flow tube passes and is movable relative to the seal assembly.

In the above technical solution, further, the sealing assembly includes a sealing seat, a sealing baffle, and a sealing ring;

the sealing seat and the sealing baffle are provided with the through holes, the through holes formed in the sealing seat are stepped holes, and the sealing ring is located on the stepped surface of the stepped holes and surrounds the circulating pipe;

the sealing baffle is located the valve main part with between the seal receptacle, just the sealing baffle lock is in the sealing washer is kept away from one side of ladder face.

In the above technical solution, further, the valve main body includes a first connecting flange and a second connecting flange;

the first connecting flange is positioned on one side of the circulating pipe and connected with one end of the electromagnetic driving assembly, and the second connecting flange is positioned on the other side of the circulating pipe and connected with the other end of the electromagnetic driving assembly;

and a third accommodating cavity is formed in the second connecting flange, and the valve seat assembly is positioned in the third accommodating cavity.

Compared with the prior art, the beneficial effect of this application is:

the application provides an axial-flow type electromagnetic valve, which comprises a flow pipe, a valve seat assembly, an electromagnetic driving assembly and a valve main body; the circulating pipe, the valve seat assembly and the electromagnetic driving assembly are all positioned in the valve main body; the electromagnetic driving assembly is arranged around the circulating pipe in a surrounding mode, the valve seat assembly is located at one end of the circulating pipe and connected with the valve main body and corresponds to a flow channel opening in the valve main body; the electromagnetic driving assembly is used for driving the circulating pipe to move in the valve main body along the medium circulating direction so as to abut against or be far away from the valve seat assembly; when the circulation pipe is abutted against the valve seat assembly, the circulation pipe and the runner port are closed; when the circulation pipe is far away from the valve seat assembly, the circulation pipe is communicated with the flow port.

Specifically, the axial flow solenoid valve includes a flow tube, a valve seat assembly, an electromagnetic drive assembly, and a valve body; the both ends of runner pipe communicate with the runner mouth of valve main part respectively, and the length of runner pipe extends along medium circulation direction, and the electromagnetic drive subassembly encloses to be established around the runner pipe to be connected with the runner pipe and drive the runner pipe motion, the length direction of electromagnetic drive subassembly is unanimous with the length direction of runner pipe, compares with traditional solenoid valve, and axial-flow solenoid valve reduces the size of direction of height to a certain extent. When the circulation pipe moves to abut against or be far away from the valve seat assembly, when the circulation pipe abuts against the valve seat assembly, the circulation pipe is blocked, so that a medium cannot flow from the flow passage opening on one side to the flow passage opening on the other side, and the valve is turned off; when the circulation pipe is far away from the valve seat assembly, the circulation pipe is communicated with the flow passage ports on two sides, so that a medium can flow through the axial flow type electromagnetic valve, and the valve is communicated.

The application provides an axial-flow solenoid valve has reduced direction of height's size, and during in the access pipeline, actually reduced the required space of installation axial-flow solenoid valve. The axial flow type electromagnetic valve is simple in structure, and can realize bidirectional conduction of media and expand application scenes of the axial flow type electromagnetic valve.

Drawings

In order to more clearly illustrate the detailed description of the present application or the technical solutions in the prior art, the drawings needed to be used in the detailed description of the present application or the prior art description will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present application, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a first structural schematic diagram of an axial-flow electromagnetic valve according to an embodiment of the present disclosure;

fig. 2 is a second structural schematic diagram of an axial-flow electromagnetic valve according to an embodiment of the present disclosure;

FIG. 3 is an enlarged schematic view at A in FIG. 2;

FIG. 4 is a schematic structural diagram of a seat assembly according to an embodiment of the present disclosure;

fig. 5 is a schematic structural diagram of an axial-flow electromagnetic valve according to a second embodiment of the present application;

FIG. 6 is an enlarged schematic view at B in FIG. 5;

fig. 7 is a schematic structural diagram of an axial-flow electromagnetic valve according to a third embodiment of the present application.

In the figure: 101-a flow-through tube; 102-a valve seat assembly; 103-an electromagnetic drive assembly; 104-a valve body; 105-a runner port; 106-a mount; 107-a gasket; 108-a flow-through gap; 109-a connector; 110-a crimp; 111-mounting grooves; 112-stationary core; 113-a movable iron core; 114-a coil assembly; 115-a mounting housing; 116-a first receiving cavity; 117-second receiving chamber; 118-a first magnetically permeable portion; 119-a second magnetic conductive part; 120-a return spring; 121-a lead assembly; 122-a seal assembly; 123-sealing seat; 124-sealing baffle plate; 125-sealing ring; 126-a first connecting flange; 127-a second connecting flange; 128-third receiving chamber.

Detailed Description

The technical solutions of the present application will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In the description of the present application, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present application. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood in a specific case by those of ordinary skill in the art.

Example one

Referring to fig. 1 to 4, the present application provides an axial-flow solenoid valve, which includes a flow pipe 101, a valve seat assembly 102, an electromagnetic driving assembly 103, and a valve main body 104; flow tube 101, valve seat assembly 102, and electromagnetic drive assembly 103 are all located within valve body 104; wherein, the electromagnetic driving component 103 is arranged around the circulation pipe 101, the valve seat component 102 is arranged at one end of the circulation pipe 101, and the valve seat component 102 is connected with the valve main body 104 and corresponds to the flow passage opening 105 on the valve main body 104; the electromagnetic driving assembly 103 is used for driving the flow pipe 101 to move in the medium flow direction in the valve main body 104 so as to abut against or be away from the valve seat assembly 102; when the flow pipe 101 abuts against the valve seat assembly 102, the flow pipe 101 and the flow port 105 are closed; when the flow tube 101 is away from the valve seat assembly 102, the flow tube 101 communicates with the orifice 105.

Specifically, the axial flow solenoid valve includes a flow tube 101, a valve seat assembly 102, an electromagnetic drive assembly 103, and a valve body 104; both ends of the flow pipe 101 communicate with the flow port 105 of the valve main body 104, respectively, and the length of the flow pipe 101 extends in the medium flow direction, where the direction F in the drawing is the medium flow direction. The electromagnetic driving assembly 103 is arranged around the circulation pipe 101 and connected with the circulation pipe 101 to drive the circulation pipe 101 to move, the length direction of the electromagnetic driving assembly 103 is consistent with the length direction of the circulation pipe 101, and compared with a traditional electromagnetic valve, the axial flow electromagnetic valve has the advantage that the size in the height direction is reduced to a certain extent. When the circulation pipe 101 moves to abut against or be away from the valve seat assembly 102, when the circulation pipe 101 abuts against the valve seat assembly 102, the circulation pipe 101 is blocked, so that a medium cannot flow from the flow passage opening 105 on one side to the flow passage opening 105 on the other side, and the valve is closed; when the flow pipe 101 is far away from the valve seat assembly 102, the flow pipe 101 communicates with the flow port 105 on both sides, so that the medium can flow through the axial flow type electromagnetic valve, and the conduction of the valve is realized.

The application provides an axial-flow solenoid valve through enclosing electromagnetic drive subassembly 103 and establishing around runner pipe 101, has reduced the size of whole direction of height, when in the access pipeline, has actually reduced the required space of installation axial-flow solenoid valve. The axial flow type electromagnetic valve is simple in structure, and can realize bidirectional conduction of media and expand application scenes of the axial flow type electromagnetic valve.

In an alternative to this embodiment, the valve seat assembly 102 includes a mounting seat 106 and a gasket 107; the mounting seat 106 is connected to the valve body 104, the gasket 107 is mounted on the mounting seat 106, and the end of the flow tube 101 can abut against the gasket 107; the mounting seat 106 is provided with a flow gap 108, the flow gap 108 is provided outside the range covered by the end of the flow pipe 101, and the flow gap 108 is used for communicating the flow passage port 105 and the flow pipe 101.

In this embodiment, the valve seat assembly 102 comprises a mounting seat 106 and a gasket 107, the mounting seat 106 being mounted in the valve body 104 for mounting the gasket 107 on the one hand, the gasket 107 blocking the flow-through pipe 101 when one side end of the flow-through pipe 101 abuts against the gasket 107. The sealing gasket 107 is made of soft material, so that the blocking effect on the circulation pipe 101 is good; on the other hand, a flow gap 108 is formed in the circumferential direction of the mounting seat 106, the flow gap 108 is formed in a region other than the region covered by the end portion of the flow pipe 101, and when the mounting seat 106 is mounted in the valve body 104, the flow gap 108 forms a flow passage for the medium, and when the flow pipe 101 is away from the gasket 107, the medium can flow through the flow gap 108, and the medium flows from the flow port 105 on one side to the flow port 105 on the other side.

In an alternative embodiment, the valve seat assembly 102 further comprises a connecting member 109 and a crimping member 110; the middle part of the mounting seat 106 is provided with a mounting groove 111, and the sealing gasket 107 is arranged in the mounting groove 111; the press-connection member 110 and the sealing gasket 107 are provided with through holes, the mounting seat 106 is provided with blind holes, and the connecting member 109 sequentially penetrates through the press-connection member 110 and the sealing gasket 107 and then is connected with the mounting seat 106 so as to fasten the sealing gasket 107.

In this embodiment, in order to achieve reliable mounting of the gasket 107, the gasket 107 is further fixed by the connecting member 109 and the crimping member 110. Wherein the crimping member 110 is crimped on the surface of the gasket 107 for increasing the connection area with the gasket 107 and preventing the gasket 107 from tilting. Specifically, the connecting member 109 may be a screw, and the crimping member 110 may be a washer.

The mounting seat 106 is opened with a mounting groove 111, the sealing gasket 107 is disposed in the mounting groove 111, preferably, the thickness of the sealing gasket 107 is smaller than the depth of the mounting groove 111, and the size of the opening of the mounting groove 111 is larger than the size of the end nozzle of the flow pipe 101, so that the end of the flow pipe 101 can be placed in the mounting groove 111 and press-fitted on the sealing gasket 107. Mounting groove 111 has been seted up at the middle part of mount pad 106, and circulation clearance 108 can set up a plurality ofly and evenly lay in the circumference of mount pad 106 for the circulation of medium is more even smooth and easy.

Example two

The axial flow electromagnetic valve in the second embodiment is an improvement on the above embodiment, and the technical contents disclosed in the above embodiment are not repeated, and the contents disclosed in the above embodiment also belong to the contents disclosed in the second embodiment.

Referring to fig. 5, in an alternative of this embodiment, the electromagnetic driving assembly 103 includes a stationary core 112, a movable core 113, a coil assembly 114, and a mounting shell 115; the static iron core 112 is arranged around the circulating pipe 101, and a first accommodating cavity 116 is formed between the static iron core 112 and the circulating pipe 101; the plunger 113 is connected to the flow tube 101, and the plunger 113 can move in the first receiving chamber 116 in the medium flow direction; static iron core 112 has seted up the holding tank, and the notch department that the installation shell 115 was buckled and is established at the holding tank forms the second and holds chamber 117, and coil pack 114 is located the second and holds chamber 117.

In this embodiment, the electromagnetic drive assembly 103 includes a stationary core 112, a movable core 113, a coil assembly 114, and a mounting case 115. When the coil assembly 114 is energized, an electromagnetic force is formed between the stationary core 112 and the movable core 113, and the movable core 113 is connected to the flow tube 101 to drive the flow tube 101 to move. Specifically, the stationary core 112 is disposed around the flow tube 101, a longitudinal direction of the stationary core 112 is aligned with a longitudinal direction of the flow tube 101, a first accommodating chamber 116 is formed between the stationary core 112 and the flow tube 101, the longitudinal direction of the first accommodating chamber 116 is aligned with the longitudinal direction of the flow tube 101, and the movable core 113 moves in the first accommodating chamber 116 under the driving of the electromagnetic force. Coil assembly 114 is embedded in the holding groove formed in the stationary core, and mounting shell 115 surrounds the notch of the holding groove, so that coil assembly 114 is enclosed in second holding cavity 117.

In an alternative solution of this embodiment, the stationary core 112 includes a first magnetic conductive part 118 and a second magnetic conductive part 119; the first magnetic conduction part 118 is connected with the second magnetic conduction part 119, and encloses to form an accommodating groove.

In this embodiment, since the coil assembly 114 is sleeved on the stationary core, the mounting case 115 is sleeved outside the coil assembly 114, and the first magnetic conductive portion 118 and the second magnetic conductive portion 119 are surrounded to form an accommodating groove, in order to facilitate mounting, when mounting, the coil assembly 114 may be firstly sleeved on the first magnetic conductive portion 118, then the mounting case 115 is sleeved outside the coil assembly 114, then the second magnetic conductive portion 119 is mounted, and the mounting case 115 is connected to the first magnetic conductive portion 118 and the second magnetic conductive portion 119.

In an alternative of this embodiment, the electromagnetic driving assembly 103 further includes a return elastic member 120; the elastic restoring member 120 is located at one end of the flow pipe 101 away from the valve seat assembly 102, one end of the elastic restoring member 120 is connected to the flow pipe 101, the other end of the elastic restoring member 120 is connected to the valve body 104, and the elastic restoring member 120 has a driving force for driving the flow pipe 101 to move toward the valve seat assembly 102.

In this embodiment, when the electromagnetic driving component 103 is powered on, the flow pipe 101 is away from the valve seat component 102, so as to realize the flow of the medium, and by providing the reset elastic component 120, when the electromagnetic driving component 103 is powered off, the flow pipe 101 can rapidly move under the action of the elastic force to abut against the valve seat component 102, so as to realize the rapid switching between the on and off states of the axial-flow type electromagnetic valve.

In an alternative version of this embodiment, the axial flow solenoid valve further includes a lead assembly 121; the lead assembly 121 is installed outside the electromagnetic driving assembly 103, and the lead assembly 121 is electrically connected with the coil assembly 114. Specifically, the lead assembly 121 may be mounted outside the mounting case 115 to energize the coil assembly 114.

EXAMPLE III

The axial flow electromagnetic valve in the third embodiment is an improvement on any one of the above embodiments, and the technical contents disclosed in the above embodiments are not repeated, and the contents disclosed in the above embodiments also belong to the contents disclosed in the third embodiment.

Referring to fig. 6, in an alternative embodiment, the axial-flow solenoid valve further includes a seal assembly 122; the sealing components 122 are arranged at two ends of the electromagnetic driving component 103, and the sealing components 122 are connected with the valve main body 104; the sealing assembly 122 is formed with a penetration hole through which the flow tube 101 passes and is movable relative to the sealing assembly 122.

In this embodiment, in order to achieve a sealed connection between the flow pipe 101 and the valve body 104 such that the medium can only flow from the inside of the flow pipe 101, a sealing assembly 122 is provided between the electromagnetic driving assembly 103, the valve body 104, and the communication pipe. The flow pipe 101 can move in the through hole of the sealing assembly 122 to realize the connection and disconnection of the medium.

In an alternative to this embodiment, the sealing assembly 122 includes a sealing seat 123, a sealing baffle 124 and a sealing ring 125; the sealing seat 123 and the sealing baffle 124 are provided with through holes, the through holes provided by the sealing seat 123 are stepped holes, and the sealing ring 125 is positioned on the stepped surface of the stepped holes and surrounds the circulating pipe 101; the sealing baffle 124 is located between the valve body 104 and the sealing seat 123, and the sealing baffle 124 is fastened to the side of the sealing ring 125 away from the stepped surface.

In this embodiment, the sealing assembly 122 includes a sealing seat 123, a sealing baffle 124 and a sealing ring 125, the sealing baffle 124 is located on the side of the valve body 104, the sealing seat 123 is located on the side of the electromagnetic driving assembly 103, one end of the return elastic member 120 is connected to the flow pipe 101, and the other end can abut against the sealing seat 123. The sealing ring 125 surrounds the flow pipe 101 and is disposed in the area formed between the sealing seat 123, the sealing baffle 124 and the flow pipe 101, so that the sealing effect is good. In particular, the sealing ring 125 may be an O-ring 125 or a Y-ring 125, and preferably, the sealing ring 125 is a Y-ring 125 having an elastic force pressing against the flow pipe 101 to ensure a better sealing effect.

Referring to fig. 7, in an alternative embodiment, the valve body 104 includes a first attachment flange 126 and a second attachment flange 127; the first connecting flange 126 is positioned at one side of the flow pipe 101 and connected with one end of the electromagnetic driving assembly 103, and the second connecting flange 127 is positioned at the other side of the flow pipe 101 and connected with the other end of the electromagnetic driving assembly 103; a third receiving cavity 128 is formed in the second attachment flange 127, and the valve seat assembly 102 is positioned within the third receiving cavity 128.

In this embodiment, the valve body 104 includes a first connecting flange 126 and a second connecting flange 127, and when the axial-flow solenoid valve is installed in a pipeline, the first connecting flange 126 and the second connecting flange 127 are respectively connected to two pipes to be connected. To achieve a secure mounting of the valve seat assembly 102, a third receiving chamber 128 is provided in the second connecting flange 127 for receiving the valve seat assembly 102. Preferably, the sealing member 122 on one side of the valve seat member 102 is also disposed in the third receiving chamber 128, and the first connecting flange 126 may be opened with a fourth receiving chamber such that the sealing member 122 on the opposite side of the valve seat member 102 is disposed in the fourth receiving chamber.

Finally, it should be noted that: the above embodiments are only used for illustrating the technical solutions of the present application, and not for limiting the same; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present application. Moreover, those skilled in the art will appreciate that while some embodiments herein include some features included in other embodiments, rather than other features, combinations of features of different embodiments are meant to be within the scope of the application and form different embodiments.

Claims (10)

1. An axial-flow solenoid valve is characterized by comprising a flow pipe, a valve seat assembly, an electromagnetic driving assembly and a valve main body;

the flow tube, the valve seat assembly and the electromagnetic drive assembly are all located within the valve body;

the electromagnetic driving assembly is arranged around the circulating pipe in a surrounding mode, the valve seat assembly is located at one end of the circulating pipe and connected with the valve main body and corresponds to a flow passage opening in the valve main body; the electromagnetic driving assembly is used for driving the circulation pipe to move in the medium circulation direction in the valve main body so as to abut against or be far away from the valve seat assembly;

when the circulation pipe abuts against the valve seat assembly, the circulation pipe and the flow port are closed; when the flow pipe is far away from the valve seat assembly, the flow pipe is communicated with the flow port.

2. The axial flow solenoid valve of claim 1, wherein the valve seat assembly comprises a mounting seat and a sealing gasket;

the mounting seat is connected with the valve main body, the sealing gasket is mounted on the mounting seat, and the end part of the circulating pipe can abut against the sealing gasket;

the mounting seat is provided with a circulation gap, the circulation gap is arranged outside the range covered by the end part of the circulation pipe, and the circulation gap is used for communicating the runner port and the circulation pipe.

3. The axial flow solenoid valve of claim 2, wherein the valve seat assembly further comprises a connector and a crimp;

the middle part of the mounting seat is provided with a mounting groove, and the sealing gasket is arranged in the mounting groove;

the crimping piece with the sealed pad has seted up the through-hole, the blind hole has been seted up to the mount pad, the connecting piece passes in proper order the crimping piece reaches behind the sealing pad with the mount pad is connected, be used for right the sealed pad fastening.

4. The axial flow solenoid valve of claim 1, wherein the electromagnetic drive assembly comprises a stationary core, a movable core, a coil assembly, and a mounting housing;

the static iron core is arranged around the circulating pipe in a surrounding mode, and a first accommodating cavity is formed between the static iron core and the circulating pipe;

the movable iron core is connected with the circulating pipe and can move in the first accommodating cavity along the medium circulating direction;

the holding tank has been seted up to quiet iron core, the installation shell is detained and is established the notch department of holding tank forms the second and holds the chamber, coil pack is located the second holds the intracavity.

5. The axial flow solenoid valve of claim 4, wherein the stationary core comprises a first magnetically permeable portion and a second magnetically permeable portion;

the first magnetic conduction part is connected with the second magnetic conduction part and surrounds to form the accommodating groove.

6. The axial flow solenoid valve of claim 4, wherein the electromagnetic drive assembly further comprises a return spring;

the reset elastic piece is positioned at one end of the circulating pipe far away from the valve seat assembly, one end of the reset elastic piece is connected with the circulating pipe, the other end of the reset elastic piece is connected with the valve main body, and the reset elastic piece has a driving force for driving the circulating pipe to move towards the valve seat assembly.

7. The axial flow solenoid valve of claim 4, further comprising a lead wire assembly;

the lead assembly is installed outside the electromagnetic driving assembly and is electrically connected with the coil assembly.

8. The axial flow solenoid valve of claim 1, further comprising a seal assembly;

the sealing assemblies are arranged at two ends of the electromagnetic driving assembly and are connected with the valve main body;

the seal assembly is formed with a through-hole through which the flow tube passes and is movable relative to the seal assembly.

9. The axial flow solenoid valve of claim 8, wherein the seal assembly comprises a seal seat, a seal retainer, and a seal ring;

the sealing seat and the sealing baffle are provided with the through holes, the through holes formed in the sealing seat are stepped holes, and the sealing ring is located on the stepped surface of the stepped holes and surrounds the circulating pipe;

the sealing baffle is located the valve main part with between the seal receptacle, just the sealing baffle lock is in the sealing washer is kept away from one side of ladder face.

10. The axial flow solenoid valve of claim 1, wherein the valve body comprises a first connecting flange and a second connecting flange;

the first connecting flange is positioned on one side of the circulating pipe and connected with one end of the electromagnetic driving assembly, and the second connecting flange is positioned on the other side of the circulating pipe and connected with the other end of the electromagnetic driving assembly;

and a third accommodating cavity is formed in the second connecting flange, and the valve seat assembly is positioned in the third accommodating cavity.

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