CN117231751A

CN117231751A - Liquid leakage prevention electromagnetic valve

Info

Publication number: CN117231751A
Application number: CN202311489319.0A
Authority: CN
Inventors: 牟海雯; 王昕�; 赵建松; 谢加超; 于佳琳
Original assignee: Shandong Provincial Laboratory Of Weifang Modern Agriculture
Current assignee: Shandong Provincial Laboratory Of Weifang Modern Agriculture
Priority date: 2023-11-10
Filing date: 2023-11-10
Publication date: 2023-12-15
Anticipated expiration: 2043-11-10
Also published as: CN117231751B

Abstract

The application belongs to the technical field of electromagnetic valves, and particularly relates to a liquid leakage preventing electromagnetic valve which comprises a vertical core pipe and two horizontal core pipes symmetrically arranged at the lower end of the vertical core pipe. The two horizontal core tubes and the vertical core tube form an inverted T-shaped core tube, and an inverted T-shaped cavity is formed inside the T-shaped core tube. The coil assembly is fixedly sleeved outside the vertical core tube, the valve core which can move up and down and is arranged vertically is arranged in the vertical core tube, and the valve core can move downwards to the bottom end of the valve core to be abutted to the bottom wall of the T-shaped cavity. A long strip mounting plate penetrating through the diameter of the horizontal core tube along the front-back direction is arranged at the position, close to the outer end, inside the horizontal core tube, and two valve plates are respectively rotatably mounted on the upper side wall and the lower side wall of the mounting plate. The valve core moves downwards to the lowest position under the action of gravity and the elastic force of the first compression spring, the bottom end of the valve core is abutted with the bottom plate of the vertical core pipe to seal the left side and the right side of the vertical core pipe, at the moment, the outer end of the horizontal core pipe is sealed through the valve plate, liquid flowing to the valve core can be effectively limited, the flow of liquid in a runner at the lower end part of the vertical core pipe is prevented, and a good sealing effect is achieved.

Description

Liquid leakage prevention electromagnetic valve

Technical Field

The application belongs to the technical field of electromagnetic valves, and particularly relates to a liquid leakage prevention electromagnetic valve.

Background

The electromagnetic valve is a technology for opening or closing the valve core by taking the electromagnetic as a power source, so that a user can conveniently control the opening of the electromagnetic valve at the far end.

In the chinese patent with publication number CN106704615B, a novel plug board type electromagnetic valve is mentioned, which comprises a valve body, a movable iron core plug board assembly and an electromagnetic coil, the movable iron core plug board assembly comprises an iron core and a plug board, and further comprises a valve port, a left sealing element and a spring, the valve body comprises a water inlet, a water outlet and an anti-blocking cavity, the plug board is positioned in the anti-blocking cavity, the valve port is tubular, one end of the valve port is connected with the water outlet, the other end of the valve port is connected with the plug board, the left sealing element compresses the plug board and enables the plug board to be tightly attached to the valve port under the action of the spring, a plug board hole is formed in the plug board, and the plug board hole can be respectively communicated with and staggered with the valve port through the movement of the plug board. The novel inserting plate type electromagnetic valve is novel in structure, ingenious in design, particularly suitable for fluid media with fixed impurities, capable of overcoming the defect that a traditional electromagnetic valve is not suitable for liquid with granular impurities, good in sealing performance and long in service life.

The inventor finds that in the process of developing products, the electromagnetic valve seal in the application is mainly realized by dislocation of the plug board port and the valve port in the middle of the plug board, the plug board needs the internal pressure of the straight-face valve body at the moment, the plug board can wear in the process of sliding up and down for a long time, the plug board can shake at the moment, the valve body is not sealed practically to generate liquid leakage, and the long-term use is not facilitated.

Disclosure of Invention

The application aims to provide the liquid leakage preventing electromagnetic valve with better sealing effect.

In order to achieve the purpose, the application discloses a liquid leakage prevention electromagnetic valve which comprises a vertical core pipe and two horizontal core pipes symmetrically arranged at the left side and the right side of the lower end of the vertical core pipe. The two horizontal core tubes and the vertical core tube form an inverted T-shaped core tube, and the insides of the two horizontal core tubes and the vertical core tube are communicated with each other so that an inverted T-shaped cavity is formed in the T-shaped core tube. The coil assembly is fixedly sleeved outside the vertical core pipe, and an iron valve core which can move up and down and is vertically arranged is arranged in the vertical core pipe. The valve core can move downwards to the lower end of the valve core is abutted to the bottom wall of the T-shaped cavity to block the two horizontal core tubes, the valve core moves downwards to the lowest part, the bottom end of the valve core is abutted to the bottom wall of the T-shaped cavity to seal the left side and the right side of the vertical core tube, and then the two horizontal core tubes are blocked, so that the valve core is simple in structure.

Preferably, one or two long mounting plates penetrating through the diameters of the two long mounting plates along the front-back direction are arranged in the parts, close to the outer ends, of the two long core tubes, and two valve plates are respectively rotatably arranged on the upper side wall and the lower side wall of each mounting plate. When the valve core descends to close the left side and the right side of the vertical core pipe, the outer end part of the horizontal core pipe is closed through the valve plate, so that liquid flowing to the valve core can be effectively limited, the flow of liquid in a flow channel at the lower end part of the vertical core pipe can be effectively prevented, and the leakage-proof electromagnetic valve is further guaranteed to have a good sealing effect.

Preferably, the front end and the rear end of the mounting plate are tightly attached to the inner side wall of the horizontal core pipe, and the valve plate is provided with a rubber strip for sealing, so that the sealing effect of the valve plate can be further improved. The inner sides of the hinging edges of the upper valve plate and the lower valve plate are respectively hinged with the inner sides of the upper side wall and the lower side wall of the mounting plate, so that when the valve core moves downwards to the lowest position, the valve plates can rotate outwards to be in a stable vertical state.

Preferably, the horizontal core pipe is internally provided with a supporting tight component connected with the middle position of the inner side wall of the mounting plate, the supporting tight component comprises a connecting component and an elastic component which can stretch along the left and right directions, the outer end of the elastic component is connected with the mounting plate, the inner end of the elastic component is connected with the connecting component, the upper side and the lower side of the connecting component are respectively connected with two supporting plates which extend out from the outer end, one or more groups of stretching components are further arranged on the mounting plate, the stretching components comprise two stretching components which are vertically symmetrical and are arranged along the left and right directions, the inner ends of the upper stretching component and the lower stretching component are hinged on the mounting plate, and the outer ends of the upper stretching component and the lower stretching component are respectively hinged on the inner sides of the upper valve plate and the lower valve plate. The abutting component and the stretching component are simple in structure, and the end part of the transverse core tube can be effectively sealed along with the descending of the valve plate.

Preferably, when the valve core moves downwards to the lowest position, the connecting part drives the retaining plate to move outwards to the outermost end, the outer end of the retaining plate is abutted with the inner side wall of the valve plate, at the moment, the inner end of the connecting part is abutted with the lower end of the valve core, the elastic part is in a compressed state, the valve plate rotates outwards to be in a vertical state, and the stretching part is in a stretched state; when the valve core moves upwards to the uppermost part, the elastic part stretches, the connecting part drives the retaining plate to move inwards to the innermost end under the action of the elastic part, and the stretching part retracts to enable the valve plate to rotate inwards to be in an inclined state.

Preferably, the abutting assembly further comprises a mounting rod arranged along the left-right direction, the connecting component is a first sleeve with an outward opening, the inner end of the mounting rod can be arranged in the first sleeve in a left-right moving mode, the outer end of the mounting rod is fixedly connected with the mounting plate, the elastic component is a second compression spring positioned in the first sleeve, the inner end of the second compression spring is connected with the inner wall of the first sleeve, and the outer end of the second compression spring is connected with the inner end of the mounting rod.

Preferably, the stretching component comprises a stretching spring capable of stretching along the length direction of the stretching component, a second sleeve with an opening at the outer end and a sliding rod with the inner end capable of moving along the length direction of the second sleeve, the stretching spring is arranged in the second sleeve, the inner end of the stretching spring is fixedly connected with the inner wall of the second sleeve, the outer end of the stretching spring is connected with the inner end of the sliding rod, and the outer end of the sliding rod is hinged to the inner side of the valve plate.

Preferably, the stretching assembly further comprises a side plate positioned between the upper stretching component and the lower stretching component, the outer end of the side plate is fixedly connected with the inner side wall of the mounting plate, the upper side and the lower side of the inner end of the side plate are respectively hinged with the inner ends of the upper sleeve and the lower sleeve, namely the second sleeve is hinged with the mounting plate through the side plate, and the stretching component is horizontally arranged or the outer end of the stretching component is obliquely arranged in the direction away from the central axis of the transverse core pipe. The obliquely arranged stretching components enable the structural arrangement to be more reasonable.

Preferably, the cross section of the vertical core pipe and the cross section of the horizontal core pipe are both circular structures, the bottom of the vertical core pipe is provided with an arc-shaped bottom plate which is integrally formed with the vertical core pipe, the bottom plate and the horizontal core pipe are coaxially arranged, through holes which are coaxially arranged with the horizontal core pipe are formed in the left side wall and the right side wall of the lower end of the vertical core pipe, the diameter of each through hole is equal to the inner diameter of the horizontal core pipe, a semicircular notch which is coaxial with the vertical core pipe and is matched with the side wall of the vertical core pipe is formed in the inner end of the horizontal core pipe, and the cross section of the valve core is circular and matched with the vertical core pipe, and the lower end of the valve core is hemispherical and matched with the bottom plate of the vertical core pipe. The valve core can move downwards until the lower end of the valve core is abutted against the inner side of the bottom plate of the vertical core pipe, so that the lower end of the vertical core pipe is closed. The structural design of the connecting part of the vertical core pipe and the horizontal core pipe further improves the tightness of the liquid leakage prevention electromagnetic valve.

Preferably, the coil assembly comprises a coil housing sleeved on the outer wall of the vertical tube, a plurality of groups of coils are wound inside the coil housing, a sealing cover is arranged at the upper end of the vertical tube, and the upper end of the valve core is connected with the sealing cover through a first compression spring. The arrangement of the outer sleeve and the sealing cover can effectively protect the internal structure of the electromagnetic valve, and the effective use of the liquid leakage preventing electromagnetic valve is guaranteed.

In summary, the beneficial effects of the application are as follows: in the application, the valve core moves downwards to the lowest position under the action of gravity and the elastic force of the first compression spring, and the bottom end of the valve core is abutted with the bottom plate of the vertical core pipe to seal the left side and the right side of the vertical core pipe, so that the structure is simple. The valve plate can effectively prevent the flow of liquid in the flow channel at the lower end part of the vertical core pipe when the valve core descends to close the left side and the right side of the vertical core pipe, so that the good sealing and leakage preventing effect of the leakage preventing electromagnetic valve is ensured. The propping assembly and the stretching assembly are simple in structure, and the end part of the transverse core tube can be sealed along with the descending of the valve core by the valve plate easily and effectively.

Drawings

FIG. 1 is a front view of a leak resistant solenoid valve of the present application;

FIG. 2 is a right side view of FIG. 1;

FIG. 3 is a cross-sectional view of section A-A of FIG. 2 (with the valve cartridge lowermost);

FIG. 4 is a cross-sectional view of the valve cartridge when it is uppermost;

FIG. 5 is a perspective view of a vertical core tube;

FIG. 6 is a front view of the vertical core tube;

FIG. 7 is a top view of the right side cross core tube;

1. outer sleeve, 11, standpipe, 12, horizontal tube, 2, coil assembly, 21, coil housing, 22, coil, 3, seal cap, 4, T-shaped core tube, 41, T-shaped cavity, 42, vertical core tube, 421, bottom plate, 422, through hole, 43, horizontal core tube, 431, notch, 5, spool, 6, first compression spring, 71, mounting plate, 72, valve plate, 721, hinge edge, 722, circular arc edge, 8, abutment assembly, 81, abutment plate, 82, mounting rod, 83, first sleeve, 84, second compression spring, 9, tension member, 91, second sleeve, 92, slide bar, 93, side plate.

Detailed Description

The following describes in further detail the embodiments of the present application with reference to the drawings and examples. The following examples are illustrative of the application and are not intended to limit the scope of the application.

In the description of the present application, it should be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. refer to the directions or positional relationships based on the directions or positional relationships shown in the drawings, and in addition, the inner and outer ends of the left-side horizontal core tube correspond to the right and left ends thereof, respectively, except that the inner and outer portions of the tubular structure are defined by the structure itself, the inner and outer ends of the right-side horizontal core tube correspond to the left and right ends thereof, respectively, and the inner and outer directions of the respective members located in the horizontal core tube are identical to the directions of the inner and outer ends of the horizontal core tube. The above terminology is for the purpose of describing and simplifying the description only, and is not intended to indicate or imply that the devices or elements being referred to must have a particular orientation, be constructed and operate in a particular orientation, and therefore should not be construed as limiting the application.

The terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first", "a second", or a third "may explicitly or implicitly include one or more such feature. In the description of the present application, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements.

The specific meaning of the above terms in the present application will be understood in specific cases by those of ordinary skill in the art.

The following is a description of a preferred embodiment of the application, taken in conjunction with the accompanying drawings.

First embodiment:

as shown in fig. 1-4, the application discloses a liquid leakage preventing electromagnetic valve, which comprises a circular vertical core pipe 42 and two circular horizontal core pipes 43 symmetrically arranged at the left and right sides of the lower end of the vertical core pipe 42, of course, the cross sections of the vertical core pipe 42 and the horizontal core pipe 43 can also be respectively rectangular or other shaped structures, and for convenience of description, the cross sections of the vertical core pipe 42 and the horizontal core pipe 43 are circular. The two horizontal core tubes 43 and the vertical core tube 42 form an inverted T-shaped core tube 4, and the two horizontal core tubes 43 and the vertical core tube 42 are mutually communicated so that an inverted T-shaped cavity 41 is formed inside the T-shaped core tube 4. The novel T-shaped steel tube structure is characterized by further comprising an outer sleeve 1 sleeved outside the T-shaped core tube 4, wherein the outer sleeve 1 is of an inverted T-shaped structure and comprises a vertical tube 11 and a horizontal tube 12, the lower end of the vertical tube 11 is communicated with the middle position of the horizontal tube 12, the upper part of the vertical core tube 42 is positioned in the vertical tube 11, and the left and right horizontal core tubes 43 are respectively positioned at the left part and the right part of the horizontal tube 12. The vertical core tube 42 is internally provided with an iron valve core 5 which can move up and down and is vertically arranged, and the valve core 5 can move downwards until the lower end of the valve core 5 is abutted to the bottom wall of the T-shaped cavity 41 so as to block the two horizontal core tubes 43.

As shown in fig. 5 and 6, the bottom of the vertical core tube 42 is provided with a circular arc-shaped bottom plate 421 integrally formed with the vertical core tube, the bottom plate 421 is coaxially arranged with the horizontal core tube 43, and the front side edge and the rear side edge of the bottom plate 421 are integrally formed and connected with the lower ends of the front side wall and the rear side wall of the vertical core tube 42. The left and right side walls of the lower end of the vertical core tube 42 are provided with through holes 422 which are coaxial with the horizontal core tube 43, and the diameter of the through holes 422 is equal to the inner diameter of the horizontal core tube 43. As shown in fig. 7, a semicircular notch 431 coaxial with the vertical core tube 42 and fitting with the side wall thereof is formed at the inner end of the horizontal core tube 43. The cross section of the valve core 5 is round and the lower end of the valve core 5 is hemispherical and matched with the bottom plate 421 of the vertical core pipe 42, specifically, the valve core 5 is in clearance fit with the inner side wall of the vertical core pipe 42, and the specific fit clearance is in terms that the valve core 5 can move up and down in the vertical core pipe 42 in actual situations and can seal the vertical core pipe 42, so that the valve core is not limited specifically. As shown in fig. 3, the valve core 5 can move downward until the lower end of the valve core 5 abuts against the inner side of the bottom plate 421 of the vertical core tube 42 to close the lower end of the vertical core tube 42, and further, when the lower end of the valve core 5 abuts against the inner side of the bottom plate 421 of the vertical core tube 42, the hemispherical spherical center of the lower end of the valve core 5 is located on the central axis of the bottom plate 421 of the vertical core tube 42, and at this time, the lower end of the valve core 5 is in transition fit with the bottom plate 421 of the vertical core tube 42, so that the lower end of the vertical core tube 42 is more effectively sealed by the valve core 5.

As shown in fig. 1-4, the coil assembly 2 is fixedly sleeved outside the vertical core pipe 42, the coil assembly 2 comprises a coil shell 21 sleeved on the outer wall of the vertical pipe 11, and a plurality of groups of coils 22 are wound inside the coil shell 21. The upper end of the vertical core pipe 42 is provided with a sealing cover 3, the sealing cover 3 is fixedly connected to the upper end of the vertical pipe 11 through a bolt, and the upper end of the valve core 5 is connected with the sealing cover 3 through a first compression spring 6.

As shown in fig. 2 to 4, a long mounting plate 71 penetrating the left side cross core tube 43 in the front-rear direction is provided near the outer end, and two valve plates 72 are rotatably mounted on the upper and lower side walls of the mounting plate 71. Specifically, the hinge edge 721 of the valve plate 72 is a straight edge, the opposite side to the hinge edge 721 is an arc edge 722, and two ends of the arc edge 722 respectively intersect with two ends of the hinge edge 721, that is, the two valve plates 72 and the mounting plate 71 form a circular structure adapted to the inner side wall of the transverse core tube 43. As shown in fig. 3, when the valve spool 5 moves downward to the lowermost position, the valve plates 72 are rotated outward (i.e., rotated leftward) to be in a vertical state, and both the valve plates 72 and the mounting plate 71 close the cross core pipe 43. As shown in fig. 4, when the valve spool 5 moves upward to the uppermost side, the valve plate 72 rotates inward (i.e., rotates rightward) in an inclined state, and the inside of the lateral core pipe 43 communicates with the outside through the clearance between the circular arc edge 722 and the inner wall of the lateral core pipe 43. Of course, the mounting plate 71 may be provided inside the right side horizontal core tube 43, and the present embodiment will be specifically described taking the mounting plate 71 provided inside the left side horizontal core tube 43 as an example.

Specifically, as shown in fig. 2, the front and rear ends of the mounting plate 71 have an arc structure with a center on the central axis of the horizontal core tube 43, and the front and rear ends of the mounting plate 71 are tightly attached to the inner side walls of the horizontal core tube 43. Further, the circular arc edge 722 of the valve plate 72 is provided with a rubber strip (not shown in the figure) for sealing, so that the sealing effect of the valve plate 72 can be further improved. In order to move the valve body 5 downward to the lowermost position, the valve plates 72 are rotated outward to be in a stable vertical state, as shown in fig. 3 and 4, the inner sides of the hinge sides 721 of the upper and lower valve plates 72 are hinged to the inner sides of the upper and lower side walls of the mounting plate 71, respectively.

In this embodiment, the transverse core tube 43 is provided with a tightening component 8 connected to the middle position of the inner side wall of the mounting plate 71, and one or more groups of stretching components are further provided on the mounting plate 71, and in this embodiment, the mounting plate 71 is provided with two groups of stretching components symmetrically disposed on two sides of the tightening component 8.

The abutting assembly 8 comprises a connecting part and an elastic part which can stretch along the left-right direction, wherein the outer end of the elastic part is connected with the mounting plate 71, the inner end of the elastic part is connected with the connecting part, and the upper side and the lower side of the connecting part are respectively connected with two abutting plates 81 which extend towards the outer end. The stretching assembly comprises two stretching components 9 which are vertically symmetrical and are arranged along the left-right direction, the inner ends of the upper stretching component 9 and the lower stretching component 9 are hinged on the mounting plate 71, and the outer ends of the upper stretching component 9 and the lower stretching component 9 are respectively hinged on the inner sides of the upper valve plate 72 and the lower valve plate 72.

As shown in fig. 3, when the valve core 5 moves downward to the lowest position, the valve core 5 pushes the connecting component outwards, the connecting component drives the retaining plate 81 to move outwards (i.e. move leftwards) to the outermost end, the outer end of the retaining plate 81 abuts against the inner side wall of the valve plate 72, at this time, the inner end of the connecting component abuts against the lower end of the valve core 5, the elastic component is in a compressed state, the valve plate 72 rotates outwards to be in a vertical state to seal the transverse core tube 43, and the stretching component 9 is in a stretched state. As shown in fig. 4, when the valve core 5 moves upward to the uppermost position, the elastic member stretches, the connecting member drives the retaining plate 81 to move inward (i.e., to the right) to the innermost position under the action of the elastic member, and the stretching member 9 retracts to rotate the valve plate 72 inward to an inclined state to open the horizontal core tube 43.

Specifically, the stretching member 9 includes a stretching spring that can expand and contract along the length direction thereof, a second sleeve 91 with an opening at the outer end, and a slide rod 92 with an inner end that can move along the length direction thereof in the second sleeve 91, the stretching spring is disposed in the second sleeve 91, the inner end of the stretching spring is fixedly connected with the inner wall of the second sleeve 91, the outer end of the stretching spring is connected with the inner end of the slide rod 92, and the outer end of the slide rod 92 is hinged to the inner side of the valve plate 72. The stretching assembly further comprises a side plate 93 positioned between the upper stretching component 9 and the lower stretching component 9, the outer end of the side plate 93 is fixedly connected with the inner side wall (namely the right side wall) of the mounting plate (71), the upper side and the lower side of the inner end of the side plate 93 are respectively hinged with the inner ends of the upper second sleeve 91 and the lower second sleeve 91, namely the second sleeve 91 is hinged with the mounting plate 71 through the side plate 93, and the stretching component 9 is horizontally arranged or the outer end of the stretching component 9 is obliquely arranged in the direction far away from the central axis of the transverse core tube 43.

The abutting assembly 8 further comprises a mounting rod 82 arranged along the left-right direction, the connecting component is a first sleeve 83 which is open outwards (namely open leftwards), the inner end of the mounting rod 82 can be arranged in the first sleeve 83 in a left-right moving mode, the outer end of the mounting rod 82 is fixedly connected with the mounting plate 71, the elastic component is a second compression spring 84 positioned in the first sleeve 83, the inner end of the second compression spring 84 is connected with the inner wall of the first sleeve 83, and the outer end of the second compression spring 84 is connected with the inner end of the mounting rod 82. In order to facilitate the valve core 5 to push the first sleeve 83 outwards when descending, the outer side wall of the inner end of the first sleeve 83 is arranged in a hemispherical shape.

In fig. 2 to 4, the mounting plate 71, the valve plate 72, the abutting assembly 8 and the stretching assembly are disposed in the inner portion of the horizontal core tube 43 on both sides, and this embodiment is described specifically only by taking the mounting plate 71, the valve plate 72, the abutting assembly 8 and the stretching assembly disposed in the horizontal core tube 43 on the left side as examples, and the drawings are only for clarity of description of this embodiment and are not meant to be limiting.

As is clear from the above description, when the valve element 5 is located at the lowermost position, the tension member 9 is in a stretched state, that is, the tension spring is in a stretched state; the resilient member is in a compressed state, i.e. the second compression spring 84 is in a compressed state. As shown in fig. 4, when the coil 22 is energized to move the valve spool 5 upward to the uppermost, the bottom of the vertical core pipe 42 is opened; the second compression spring 84 stretches, and the first sleeve 83 drives the retaining plate 81 to move inwards to the innermost end under the action of the second compression spring 84; the extension spring is retracted, and the valve plate 72 is rotated inward by the tension of the extension spring, thereby opening the end of the cross core tube 43. The liquid outside the left horizontal core tube 43 can pass through the left horizontal core tube 43, the vertical core tube 42 and the right horizontal core tube 43 in turn and then pass through the liquid leakage prevention electromagnetic valve.

As shown in fig. 3, when the coil 22 is powered off, the valve core 5 moves downward under the action of gravity and the elastic force of the first compression spring 6, contacts with the inner end of the first sleeve 83 and pushes the first sleeve 83 outwards, the second compression spring 84 compresses, the retaining plate 81 moves outwards along with the first sleeve 83, the retaining plate 81 moving outwards pushes the valve plate 72 to rotate outwards until the valve core 5 moves downwards to the lowest position to make the bottom end of the valve core 5 contact with the bottom plate 421 of the vertical core tube 42 to seal the bottom of the vertical core tube 42, at this time, the retaining plate 81 moves outwards to the outermost end along with the first sleeve 83, and the outer end of the retaining plate 81 completely contacts with the inner side wall of the valve plate 72, the valve plate 72 is in a vertical state, and the outer end of the left horizontal core tube 43 is sealed, so that the liquid flowing to the valve core 5 can be effectively limited, at this time, the hydraulic difference at two sides of the valve core 5 is small, and the flow of the liquid in the flow channel at the lower end of the vertical core tube 42 can be effectively prevented, so that the valve has good sealing performance.

Second embodiment:

in the present embodiment, as shown in fig. 3 and 4, the mounting plate 71, the valve plate 72, the abutting assembly 8 and the stretching assembly, which are bilaterally symmetrical to the inside of the left lateral core tube 43, are also provided inside the right lateral core tube 43 on the basis of the first embodiment. When the valve body 5 is lifted or lowered, the components in the left and right lateral core tubes 43 are also symmetrically moved in opposite directions. When the valve core 5 descends to close the left side and the right side of the vertical core pipe, the transverse core pipe 43 on the left side and the right side can close the outer end parts of the left side and the right side, so that the flow of liquid in the flow channel on the lower end part of the vertical core pipe 42 can be more effectively prevented, and the sealing performance of the application is further improved.

The foregoing is merely a preferred embodiment of the present application, and it should be noted that modifications and substitutions can be made by those skilled in the art without departing from the technical principles of the present application, and these modifications and substitutions should also be considered as being within the scope of the present application.

Claims

1. The utility model provides a leak protection liquid solenoid valve, its characterized in that includes perpendicular core pipe (42) and symmetry set up in two horizontal core pipe (43) of perpendicular core pipe (42) lower extreme left and right sides, two horizontal core pipe (43) and perpendicular core pipe (42) constitute the T shape core pipe (4) of inversion, two inside all mutual intercommunication of horizontal core pipe (43) and perpendicular core pipe (42) makes the inside T shape chamber (41) that form of T shape core pipe (4), perpendicular core pipe (42) external fixation cover is equipped with coil assembly (2), be equipped with in perpendicular core pipe (42) iron case (5) that can reciprocate and vertical setting.

2. The leakage prevention electromagnetic valve according to claim 1, wherein one or two of the horizontal core tubes (43) are provided with a long mounting plate (71) penetrating the diameter thereof in the front-rear direction at the position near the outer end, and the upper and lower side walls of the mounting plate (71) are respectively rotatably provided with two valve plates (72).

3. The leakage-proof electromagnetic valve according to claim 2, wherein the front end and the rear end of the mounting plate (71) are tightly attached to the inner side wall of the horizontal core tube (43), rubber strips for sealing are arranged on the valve plates (72), and the inner sides of the hinging edges (721) of the upper valve plate (72) and the lower valve plate (72) are respectively hinged with the inner sides of the upper side wall and the lower side wall of the mounting plate (71).

4. The leakage-proof electromagnetic valve according to claim 2, wherein a tight supporting component (8) connected with the middle position of the inner side wall of the mounting plate (71) is arranged in the horizontal core tube (43), the tight supporting component (8) comprises a connecting component and an elastic component which can stretch along the left-right direction, the outer end of the elastic component is connected with the mounting plate (71) and the inner end of the elastic component is connected with the connecting component, the upper side and the lower side of the connecting component are respectively connected with two supporting plates (81) which extend towards the outer end, one group or a plurality of groups of stretching components are further arranged on the mounting plate (71), the stretching components comprise two stretching components (9) which are symmetrical up and down and are arranged along the left-right direction, the inner ends of the upper stretching component and the lower stretching component (9) are hinged on the mounting plate (71), and the outer ends of the upper stretching component and the lower stretching component (9) are respectively hinged with the inner sides of the upper valve plate and the lower valve plate (72).

5. The leakage prevention electromagnetic valve according to claim 4, wherein when the valve core (5) moves downwards to the lowest position, the connecting part drives the retaining plate (81) to move outwards to the lowest position, the outer end of the retaining plate (81) is abutted with the inner side wall of the valve plate (72), at the moment, the inner end of the connecting part is abutted with the lower end of the valve core (5), the elastic part is in a compressed state, the valve plate (72) rotates outwards to be in a vertical state, and the stretching part (9) is in a stretched state; when the valve core (5) moves upwards to the uppermost part, the elastic part stretches, the connecting part drives the retaining plate (81) to move inwards to the innermost end under the action of the elastic part, and the stretching part (9) retracts to enable the valve plate (72) to rotate inwards to be in an inclined state.

6. The leakage prevention electromagnetic valve according to claim 4, wherein the abutting assembly (8) further comprises a mounting rod (82) arranged along the left-right direction, the connecting component is a first sleeve (83) which is opened outwards, the inner end of the mounting rod (82) is arranged in the first sleeve (83) in a left-right movable mode, the outer end of the mounting rod (82) is fixedly connected with the mounting plate (71), the elastic component is a second compression spring (84) positioned in the first sleeve (83), the inner end of the second compression spring (84) is connected with the inner wall of the first sleeve (83), and the outer end of the second compression spring (84) is connected with the inner end of the mounting rod (82).

7. The leakage preventing electromagnetic valve according to claim 4, wherein the tension member (9) comprises a tension spring capable of expanding and contracting along the length direction thereof, a second sleeve (91) with an open outer end and a sliding rod (92) with an inner end capable of moving along the length direction thereof in the second sleeve (91), the tension spring is arranged in the second sleeve (91), the inner end of the tension spring is fixedly connected with the inner wall of the second sleeve (91), the outer end of the tension spring is connected with the inner end of the sliding rod (92), and the outer end of the sliding rod (92) is hinged with the inner side of the valve plate (72).

8. The leakage-proof electromagnetic valve according to claim 7, wherein the stretching assembly further comprises a side plate (93) arranged between the upper stretching component (9) and the lower stretching component (9), the outer end of the side plate (93) is fixedly connected with the inner side wall of the mounting plate (71), the upper side and the lower side of the inner end of the side plate (93) are respectively hinged with the inner ends of the upper second sleeve (91) and the lower second sleeve (91), namely the second sleeve (91) is hinged with the mounting plate (71) through the side plate (93), and the stretching component (9) is horizontally arranged or the outer end of the stretching component is obliquely arranged in the direction away from the central axis of the transverse core tube (43).

9. The leakage-proof electromagnetic valve according to claim 1, wherein the cross sections of the vertical core tube (42) and the horizontal core tube (43) are of circular structures, a circular arc-shaped bottom plate (421) which is integrally formed with the vertical core tube (42) is arranged at the bottom of the vertical core tube (42), the bottom plate (421) and the horizontal core tube (43) are coaxially arranged, through holes (422) which are coaxially arranged with the horizontal core tube (43) are formed in the left side wall and the right side wall of the lower end of the vertical core tube (42), the diameter of each through hole (422) is equal to the inner diameter of the horizontal core tube (43), a semicircular notch (431) which is coaxial with the vertical core tube (42) and is matched with the side wall of the vertical core tube (42) is formed in the inner end of the horizontal core tube (43), and the cross section of the valve core (5) is of a circular shape which is matched with the bottom plate (421) of the vertical core tube (42).

10. The anti-leakage electromagnetic valve according to claim 1, further comprising an outer sleeve (1) sleeved outside the T-shaped core tube (4), wherein the outer sleeve (1) is of an inverted T-shaped structure and comprises a vertical tube (11) and a transverse tube (12), the coil assembly (2) comprises a coil housing (21) sleeved on the outer wall of the vertical tube (11), a plurality of groups of coils (22) are wound inside the coil housing (21), a sealing cover (3) is arranged at the upper end of the vertical tube (11), and the upper end of the valve core (5) is connected with the sealing cover (3) through a first compression spring (6).