CN217482013U - Plug valve and water air conditioner - Google Patents

Plug valve and water air conditioner Download PDF

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Publication number
CN217482013U
CN217482013U CN202123398143.7U CN202123398143U CN217482013U CN 217482013 U CN217482013 U CN 217482013U CN 202123398143 U CN202123398143 U CN 202123398143U CN 217482013 U CN217482013 U CN 217482013U
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valve
plug
groove
scrape
closed
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CN202123398143.7U
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何泽淼
张永涛
何永水
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Zhejiang Hengsen Industry Group Co ltd
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Zhejiang Hengsen Industry Group Co ltd
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Abstract

The utility model relates to a plug valve and water air conditioner. The plug valve includes: a valve body comprising a fluid inlet and a fluid outlet; a valve element disposed within the valve body and rotatable between an open valve position and a closed valve position, the valve element including a first valve flap and a second valve flap, the first valve flap closing the fluid inlet and the second valve flap closing the fluid outlet in the closed valve position; and a scraping structure provided on an opposite surface in sliding contact with the sealing surface of the second valve sheet and on a rotation path of the second valve sheet, and configured to scrape the sealing surface of the second valve sheet during rotation of the spool.

Description

Plug valve and water air conditioner
Technical Field
The utility model relates to a plug valve reaches water air conditioner including this kind of plug valve.
Background
The plug valve is a rotary valve in a closing member or plunger shape, and is opened or closed by rotating 90 degrees to enable a passage port on the plug to be communicated with or separated from a passage port on the valve body. The valve plug may be cylindrical or conical in shape. In a cylindrical valve plug, the passage opening is generally rectangular.
The valve body of a conventional plug valve is generally directly sleeved on the periphery of the valve core, and the valve core is directly contacted with the valve core, and the valve core is usually a metal body. Due to the reason of the processing technology, the inner sides of the passage openings on the two sides of the valve body are both edge structures, so that the edge structures on the inner sides of the passage openings can clamp the valve core in the rotating process of the valve core, the phenomenon of clamping is caused, and the valve core cannot rotate.
The plug valve generally comprises a valve plate positioned on an upstream side and a valve plate positioned on a downstream side, when the plug valve is closed, the pressure difference between an inlet and an outlet of a valve body is large, fluid can prop the valve plate on the upstream side open and enter the valve body, and the fluid pressure of the valve plate on the downstream side tightly abuts against the inner surface of the valve body to realize reliable sealing. The "upstream" side generally refers to the side from which the fluid originates, and the "downstream" side generally refers to the side to which the fluid flows.
During operation of such a plug valve, particularly when the downstream valve element is opened at a certain angle, the valve element may slightly swing due to the fluid pressure, causing a portion of the downstream valve element to deflect from the inner surface of the valve body, thereby causing leakage. In the case where the fluid medium is dirty, impurities are likely to accumulate in the gap between the outer surface of the downstream side valve sheet and the inner surface of the valve body and adhere to the outer surface of the downstream side valve sheet, which on the one hand causes wear to the downstream side valve sheet and on the other hand causes incomplete adhesion between the valve sheet and the inner surface of the valve body, resulting in leakage. In addition, the torque force when the plug valve rotates is very large.
SUMMERY OF THE UTILITY MODEL
The utility model relates to a plug valve, include: a valve body comprising a fluid inlet and a fluid outlet; a valve element disposed within the valve body and rotatable between an open valve position and a closed valve position, the valve element including a first valve flap and a second valve flap, the first valve flap closing the fluid inlet and the second valve flap closing the fluid outlet in the closed valve position; and a scraping structure provided on an opposite surface in sliding contact with the sealing surface of the second valve sheet and on a rotation path of the second valve sheet, and configured to scrape the sealing surface of the second valve sheet during rotation of the spool.
Advantageously, the opposing surface is formed on an inner surface of the valve body.
Advantageously, the valve further comprises a protective sleeve fixedly mounted to the valve body and disposed between the valve spool and the valve body, said opposing surfaces being formed on said protective sleeve, said protective sleeve comprising a first opening and a second opening communicating with said fluid inlet and fluid outlet, respectively, the valve spool being rotated within the protective sleeve such that said first and second valve flaps open or close said first and second openings, respectively.
Advantageously, the scraping structure has a first scraping member configured to scrape a part of the sealing surface of the second valve sheet when the spool rotates from the valve-closing position to the valve-opening position, and a second scraping member configured to scrape the remaining part of the sealing surface of the second valve sheet when the spool rotates from the valve-opening position to the valve-closing position.
Advantageously, the scraping structure comprises a groove, a first edge of which is configured as a first scraping member and a second edge of which is configured as a second scraping member.
Advantageously, the plug valve further comprises another scraping structure configured to scrape a part of the sealing surface of the second valve sheet when the valve spool rotates from the valve-closing position to the valve-opening position, the other scraping structure being configured to scrape the remaining part of the sealing surface of the second valve sheet when the valve spool rotates from the valve-closing position to the valve-opening position.
Advantageously, the scraping structure includes a first groove provided on the opposing surface, the first groove being provided on a downstream side of the fluid outlet in a rotational direction of the spool from the valve-closed position to the valve-open position, and the first groove includes a first edge configured to scrape the part of the sealing surface of the second valve plate when the spool is rotated from the valve-closed position to the valve-open position, and the other scraping structure includes a second groove provided on the opposing surface, the second groove being provided on an upstream side of the fluid outlet in the rotational direction, and including a first edge configured to scrape the remaining part of the sealing surface of the second valve plate when the spool is rotated from the valve-closed position to the valve-open position.
Advantageously, the plug valve further comprises another scraping structure configured to scrape a first portion of the sealing surface of the second valve sheet when the valve spool rotates from the valve-closing position to the valve-opening position, the scraping structure being configured to scrape a second portion of the sealing surface of the second valve sheet when the valve spool rotates from the valve-closing position to the valve-opening position, and scrape a third portion of the outer surface of the second valve sheet when the valve spool rotates from the valve-opening position to the valve-closing position, the first portion, the second portion, and the third portion in combination covering at least the entire area of the sealing surface of the second valve sheet.
Advantageously, the scraping structure includes a first groove provided on the opposing surface, the first groove being provided on a downstream side of the fluid outlet in a rotational direction of the spool from the valve-closed position to the valve-open position, and the first groove including a first edge and a second edge, the first edge is configured to scrape a second portion of the sealing surface of the second valve plate when the valve spool rotates from the valve-closed position to the valve-open position, the second edge is configured to scrape a third portion of the sealing surface of the second valve plate when the spool rotates from the valve-open position to the valve-closed position, the other scraping structure comprises a second groove provided on the opposite surface, the second groove being provided on an upstream side of the fluid outlet in the rotation direction, and includes a first edge configured to scrape a first portion of the sealing surface of the second valve plate when the spool rotates from the closed valve position to the open valve position.
Advantageously, the valve body comprises a valve body for housing the valve cartridge and a plug cap removably mounted to the valve body.
Advantageously, the valve body is provided with a stop configured to abut against the second valve flap to prevent movement of the outer surface of the second valve flap away from the inner surface of the protective sleeve under the influence of fluid pressure.
Advantageously, said stop comprises a first stop provided on the valve body and/or a second stop provided on the plug cap.
Advantageously, the second valve flap has a flap body and first and second fittings extending outwardly from both ends of the flap body, the first stop abutting the first fitting and the second stop abutting the second fitting.
Advantageously, the outer surface of the boot is provided with an annular mounting groove having a first portion extending along the outer surface above the first opening, a second portion extending along the outer surface below the second opening and an intermediate portion extending obliquely over the outer surface to connect the first and second portions respectively, the annular sealing ring being disposed in the annular mounting groove, the first portion of the annular sealing ring being disposed in the first portion of the annular mounting groove, the second portion of the annular sealing ring being disposed in the second portion of the annular mounting groove and the third portion of the annular sealing ring being disposed in the intermediate portion of the annular mounting groove.
Advantageously, the inner surface of the protective sleeve is provided with a first annular groove arranged in a first plane perpendicular to the longitudinal axis of the protective sleeve and in a first plane different from the plane of the first portion of the annular mounting groove, the first sealing ring being arranged in the first annular groove.
Advantageously, the inner surface of the protective sleeve is provided with a second annular groove arranged in a second plane perpendicular to the longitudinal axis of the protective sleeve and in a second plane different from the plane in which the second portion of the annular mounting groove is arranged, the second sealing ring being arranged in the second annular groove.
Advantageously, the valve cartridge further comprises a connecting rod, a first end of the connecting rod being connected to the first valve plate and a second end of the connecting rod being connected to the second valve plate.
Advantageously, the first valve plate has a first groove receiving the first end of the link, the second valve plate has a second groove receiving the second end of the link, there is a first gap between the first end of the link and the closed end of the first groove, and a second gap between the second end of the link and the closed end of the second groove, such that the link is movable relative to the first valve plate and the second valve plate.
Advantageously, the valve core further comprises a first return spring and a second return spring, the first return spring is connected between the inner surface of the first valve plate and the valve rod, and the second return spring is connected between the inner surface of the second valve plate and the valve rod.
Advantageously, the valve body is formed with a mounting hole through which the spool passes, the plug cap is partially inserted into the protective sleeve to close the mounting hole, and a plurality of seal rings are provided between the protective sleeve and the plug cap, between the plug cap and the valve body, and between a top of the protective sleeve and the valve body.
Advantageously, the protective sheath is a plastic protective sheath.
Advantageously, the plug valve further comprises a positioning pin inserted into the protective sleeve and the valve body to position the relative position of the protective sleeve and the valve body.
The utility model discloses still relate to a water air conditioner, it includes as above plug valve.
Drawings
The advantages and objects of the present invention will be better understood from the following detailed description of the preferred embodiments of the invention, taken in conjunction with the accompanying drawings. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the relationship of the various components.
Fig. 1 shows a perspective view of a plug valve according to the invention.
Figure 2 shows a side view of a plug valve according to the present invention.
Figure 3 shows a cross-sectional view of the plug valve according to the present invention along line a-a of figure 2.
Figure 4 shows a perspective view of a plug valve according to the present invention with the valve body removed.
Fig. 5 shows a front view of the structure of fig. 4.
Fig. 6a and 6b show left and right side views of the structure of fig. 4.
Fig. 7 shows a cross-sectional view taken along the line B-B of fig. 6 a.
FIG. 8 shows a cross-sectional view of FIG. 7 with the poppet and stem removed.
Fig. 9 shows a schematic view according to the positional relationship of the first seal ring, the second seal ring, and the annular seal ring.
FIGS. 10-13 show top views of a plug valve according to the present invention illustrating the rotation of the plug valve from a closed valve position to an open valve position.
FIGS. 14-15 show top views of a plug valve according to the present invention illustrating the rotation of the plug valve from an open valve position to a closed valve position.
Detailed Description
Various embodiments according to the present invention will be described in detail with reference to the accompanying drawings. Here, it is to be noted that, in the drawings, the same reference numerals are given to constituent parts having substantially the same or similar structures and functions, and repeated description thereof will be omitted. The term "sequentially comprising A, B, C, etc" merely indicates the order of the included elements A, B, C, etc. and does not exclude the possibility of including other elements between a and B and/or between B and C. In the following description, directional terms are used for convenience, wherein "longitudinal" refers to the direction of the length of the valve stem, the valve stem and the valve element are rotated about the longitudinal direction, whereby the direction of rotation of the valve stem or the valve element is referred to as the direction of rotation, "up" and "down" refer to the direction along the longitudinal direction, respectively, the direction in which the valve stem protrudes from the valve body is referred to as "up", the opposite direction is referred to as "down", "upstream" refers to the direction from which the fluid comes or the direction from which the fluid starts to rotate in the direction of rotation, and "downstream" refers to the direction to which the fluid is to flow or the direction to which the fluid is to rotate in the direction of rotation. It is noted, however, that the above-described orientations are merely for convenience of description, and the present disclosure is not so limited, as various features may have different orientations in different orientations.
The drawings in the present specification are schematic views to assist in explaining the concept of the present invention, and schematically show the shapes of the respective portions and the mutual relationships thereof.
Figures 1 to 3 show a plug valve 1 according to the invention in perspective, side and cross-sectional views respectively. The plug valve 1 includes a valve body 11, a valve element 12, and a stem 13, the valve element 12 being disposed in the valve body 11, the stem 13 being rotatably mounted to the valve body 11 and fixedly connected to the valve element 12, the stem 13 being driven by an external driving source (not shown), such as a motor, so that the stem 13 can rotate the valve element 12 in the valve body between an open valve position and a closed valve position. The valve-open position and the valve-closed position differ by, for example, 90 degrees.
The valve body 11 includes a valve body 111 defining a fluid inlet 113 and a fluid outlet 114, and a spin cover 112. The valve body 111 includes a mounting hole at a lower side through which the valve cartridge 12 is inserted into the valve body when mounted (see fig. 3), and a cap 112 for closing the mounting hole after the valve cartridge 12 is mounted into the valve body. A seal ring 115 is provided between the screw cap 112 and the valve body 111. A packing 117 is provided between the stem 13 and the valve body 111.
The valve core 12 comprises a first valve plate 121, a second valve plate 122 and a connecting rod 123 connected between the first valve plate and the second valve plate, and the connecting rod 123 is fixedly connected with the valve rod 13, so that the valve rod 13 can drive the valve core to rotate. In the closed position of the plug valve, the first vane 121 is arranged against the fluid inlet of the valve body, i.e. the first vane 121 is the upstream side vane, and the second vane 122 is arranged against the fluid outlet of the valve body, i.e. the second vane 122 is the downstream side vane.
As shown in fig. 7, the first end 1231 of the connecting rod 123 is connected to the first valve plate 121, and the second end 1232 is connected to the second valve plate 122. Specifically, the first end 1231 of the link is inserted into the first groove 1211 of the first valve sheet 121, and a first gap exists between the first end 1231 of the link and the closed end of the first groove 1211. The second end of the link is inserted into the second groove 1221 of the second valve plate 122, and a second gap exists between the second end 1232 of the link and the closed end of the second groove 1221. As such, when fluid entering via the fluid inlet pushes against the first valve plate 121, the first valve plate can move slightly away from the valve body relative to the connecting rod due to the presence of the first gap, thereby creating a small gap between the fluid inlet and the first valve plate 121 to allow fluid to enter the interior of the valve body, which presses against the upstream side of the second valve plate 122 and thereby pushes the second valve plate 122 against the interior surface of the valve body. To this end, a first return spring 124 is provided between the stem and the inner surface of the first valve plate 121 to bias the first valve plate 121 toward the inner surface of the valve body at a position adjacent to the first end of the link, and a second return spring 125 is provided between the stem and the inner surface of the second valve plate 122 to bias the second valve plate 122 toward the inner surface of the valve body at a position adjacent to the second end of the link. For example, the first and second return springs may be tower springs, the large ends of which are in contact with the first or second valve plate, and the lower ends of which are in contact with the valve stem 13.
As shown in fig. 3, in one embodiment, the stopcock 1 may further comprise a protective sleeve 14 fixedly mounted to the valve body 111 and disposed between the valve core 12 and the valve body 111, i.e., the protective sleeve surrounds the valve core, which causes the valve core to rotate within the protective sleeve. The protective sheath is formed by wear-resisting or self-lubricating material for example, and this material is plastics for example, and this has avoided the direct contact of case with the valve body, can not make the case receive wearing and tearing, has guaranteed that the case can normally rotate and can not block.
The protective sleeve also includes a locating pin 146 for locating the relative position of the protective sleeve 14 and the valve body 11. The positioning pin 146 is, for example, embedded in a corresponding groove formed in the protective sleeve 14 and the valve body 11, so that the protective sleeve 14 is fixed relative to the valve body 11.
As shown in fig. 4, 5 and 6a-6b, the protective sleeve 14 includes a first opening 141 and a second opening 142, the first opening 141 being aligned with the fluid inlet 113 of the valve body and the second opening 142 being aligned with the fluid outlet 114 of the valve body. In the circumferential direction of the rotation axis of the spool 12, the middle portions of the opening walls of the first opening and the second opening are gradually depressed toward both sides.
An annular mounting groove is provided on the outer surface of the casing, which is in the form of a closed ring encircling the casing, having a first portion extending over the first opening 141 around the outer circumferential surface of the casing to an extent exceeding the span of the first and second openings 141 and 142, a second portion extending below the second opening 142 around the outer circumferential surface of the casing to an extent exceeding the span of the first and second openings 141 and 142, and an intermediate portion extending obliquely around the outer surface of the casing to connect the first and second portions, as shown in fig. 6a and 6 b. Thus in the side view of fig. 5, the mounting slot forms a cross-fold transverse shape. The annular sealing ring 144 is disposed within the annular mounting groove and specifically the annular sealing ring 144 has a first section 1441 located within the first section of the annular mounting groove, a second section 1442 located within the intermediate section of the annular mounting groove and a third section 1443 located within the second section of the annular mounting groove.
As shown in fig. 8 and 9, in addition, a first annular groove is provided on the inner surface of the protective sheath, the first annular groove being provided in a first plane perpendicular to the longitudinal axis of the protective sheath and different from the plane of the first portion of the annular mounting groove, the first plane in which the first annular groove is provided is shown in the drawings to be located above, i.e., higher than, the plane of the first portion of the annular mounting groove, and a first seal ring 143 is provided in the first annular groove.
The inner surface of the protective sleeve is further provided with a second annular groove arranged in a second plane perpendicular to the longitudinal axis of the protective sleeve and which second plane is different from the plane of the second part of the annular mounting groove, which second plane is shown in the figures as being located below, i.e. lower than, the plane of the second part of the annular mounting groove, in which second annular groove the second sealing ring 145 is arranged.
The first plane staggers with the first part, and the second is opened the face and is stagger with the second part, can reduce the thickness of protective sheath effectively. Through the cooperation of first sealing washer, second sealing washer and ring packing, can realize sealed effect better.
The valve body 11 also includes a stop configured to abut the second valve plate 122 to prevent movement of the outer surface of the second valve plate away from the inner surface of the protective sleeve under the influence of fluid pressure. Specifically, during rotation of the spool, the pressure of the fluid entering via the fluid inlet to the second valve plate may be unbalanced, which results in a portion of the second valve plate possibly moving off the inner surface of the protective sleeve centered on the connecting rod 123, and for this reason, the stopper is configured to prevent such movement of the second valve plate.
As shown in fig. 3, in the present embodiment, the stoppers include a first stopper 115 provided on the valve body main body 111 and a second stopper 116 provided on the plug cover, and the second valve sheet 122 has a sheet main body 1221 and first and second fitting members 1222 and 1223 extending outward from both ends of the sheet main body in the longitudinal direction. As such, the first stop 115 is configured to slidingly abut the first mating member 1222 and the second stop 116 is configured to slidingly abut the second mating member 1223, thereby preventing any portion of the second valve flap from moving off the inner surface of the protective sleeve during rotation of the second valve flap. By means of the stop, the risk of leakage can be reduced, thereby reducing the possibility of impurities adhering to the outer surface of the second valve plate.
The plug valve further includes a scraping structure configured to scrape an outer surface or a sealing surface of a member for sealing (i.e., the second valve sheet) of the valve core during rotation of the valve core to scrape impurities off the outer surface. Under the condition that does not have the protective sheath, the scraping structure can set up in the valve body main part, and under the condition that has the protective sheath, the scraping structure sets up on the protective sheath, and the scraping structure setting is on the relative surface of valve block rotation in-process and the sealed sliding contact of valve block promptly. In the following description, the scraping structure is described as being arranged on the protective sleeve. Also, in the following description, the scraping structure is described in the form of a groove provided on the inner surface of the protective sheath, but it will be understood by those skilled in the art that the scraping structure may also be in other forms, such as utilizing variations in roughness of the inner surface of the protective sheath, etc., as long as the scraping function is achieved.
In the following description, the plug valve 1 includes the scraping structure 15 and the other scraping structure 16, and the scraping structure 15 and the other scraping structure 16 may be respectively provided in the jackets on the upstream side and the downstream side of the second outlet in the rotation direction of the second valve sheet in the plan view shown in fig. 10. The scraping structure 15 is for example in the form of a first groove with a first edge 151 configured as a first scraper and a second edge 152 configured as a second scraper, and the further scraping structure 16 may be in the form of a second groove with a first edge 161 configured as a scraper and a second edge 162 not acting as a scraper in this example.
Fig. 10 shows the plug valve in the closed position and fig. 11 shows the valve stem 13 rotating the valve element 12 counterclockwise, for example, by 20 degrees. As can be seen, during the rotation from the position of fig. 10 to the position of fig. 11, the first edges 161 of the second grooves scrape a first portion of the outer surface of the second valve sheet 122, which is denoted by S1 in fig. 10. At this time, the upper end of the outer surface of the second valve sheet 122 is rotated just to the first edge 151 of the first groove.
As the valve spool continues to rotate counterclockwise by 40 degrees to the position rotated by 60 degrees shown in fig. 12, the second portion S2 of the outer surface of the second valve plate 122 is scraped, and during the rotation of the valve spool to the valve-opening position shown in fig. 13, the first edge 151 of the first groove 15 scrapes the third portion S3 of the outer surface of the second valve plate 122, and the third portion S3 includes the second portion S2.
When the valve core rotates clockwise by 20 degrees to the position shown in fig. 14, the fourth portion S4 of the outer surface of the second valve plate 122 is scraped, and when the valve core rotates to the position shown in fig. 15, which rotates by 60 degrees, the second edge 152 of the first groove 15 scrapes the fifth portion S5 of the outer surface of the second valve plate 122, and the fifth portion contains the fourth portion. Then, the spool rotates to the valve-closing position shown in fig. 10, and further scrapes the outer surface of the second valve sheet. In fact, the first section S1, the third section S3, and the fifth section S5 in combination cover at least the entire area of the outer surface of the second valve sheet 122, thereby enabling scraping of the outer surface of the second valve sheet.
One form of scraping has been described above by way of example only, but it will be appreciated by those skilled in the art that the size and location of the first or second grooves and the size of the outer surface of the second valve sheet can be suitably designed to achieve multiple forms of scraping.
For example, another scraping structure, that is, the second groove may be omitted, and only the scraping structure formed by the first groove may be provided such that a part of the outer surface of the second valve sheet is scraped by the first edge of the first groove during rotation of the second valve sheet from the valve-closed position to the valve-open position, and the remaining part of the outer surface of the second valve sheet is scraped by the second edge of the first groove during rotation of the second valve sheet from the valve-open position to the valve-closed position.
For example, in the case where another scraping structure is present, when the spool rotates from the valve-closed position to the valve-open position, the first edge of the first groove is configured to scrape a part of the outer surface of the second valve sheet, and the first edge of the second groove is configured to scrape the remaining part of the outer surface of the second valve sheet.
Through the scraping structure who sets up the slot form, not only can scrape the impurity on the surface of second valve block, moreover, owing to set up the slot, reduced the second valve block in the protective sheath internal rotation with the frictional force of protective sheath to reduce the moment of torsion, reduced sealed area G simultaneously, as shown in fig. 10.
Although the scraping structure is described by taking a groove with a scraping edge as an example in the present embodiment, the present disclosure is not limited thereto. The scraping structure may also be realized by varying the roughness of a part of the opposite surface or by providing slightly protruding ridges, for example.
It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.
Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (23)

1. A plug valve, comprising:
a valve body comprising a fluid inlet and a fluid outlet;
a valve element disposed within the valve body and rotatable between an open valve position and a closed valve position, the valve element including a first valve flap and a second valve flap, the first valve flap closing the fluid inlet and the second valve flap closing the fluid outlet in the closed valve position; and
and a scraping structure provided on an opposite surface in sliding contact with the sealing surface of the second valve sheet on a rotation path of the second valve sheet and configured to scrape the sealing surface of the second valve sheet during rotation of the spool.
2. The plug valve of claim 1, wherein said opposing surfaces are formed on an inner surface of said valve body.
3. The plug valve of claim 1, further comprising a protective cover fixedly mounted to the valve body and disposed between the valve core and the valve body, the opposing surfaces being formed on the protective cover, the protective cover including a first opening and a second opening in communication with the fluid inlet and the fluid outlet, respectively, the valve core being rotated within the protective cover such that the first and second valve flaps open or close the first and second openings, respectively.
4. The plug valve according to claim 2 or 3, wherein the scraping structure has a first scraping member configured to scrape a part of the sealing surface of the second valve sheet when the valve body rotates from the valve-closing position to the valve-opening position, and a second scraping member configured to scrape the remaining part of the sealing surface of the second valve sheet when the valve body rotates from the valve-opening position to the valve-closing position.
5. The plug valve of claim 4, wherein the scraping structure comprises a groove, a first edge of the groove configured as a first scraping member and a second edge of the groove configured as a second scraping member.
6. A plug valve according to claim 2 or 3, further comprising a further scraping structure configured to scrape a portion of the sealing surface of the second valve plate as the valve spool rotates from the closed valve position to the open valve position, the further scraping structure being configured to scrape the remainder of the sealing surface of the second valve plate as the valve spool rotates from the closed valve position to the open valve position.
7. The plug valve of claim 6, wherein the scraping structure includes a first groove disposed on the opposing surface, the first groove being disposed on a downstream side of the fluid outlet in a rotational direction of the valve spool from the closed valve position to the open valve position, and the first groove includes a first edge configured to scrape the portion of the sealing surface of the second valve plate when the valve spool rotates from the closed valve position to the open valve position, and the other scraping structure includes a second groove disposed on the opposing surface, the second groove being disposed on an upstream side of the fluid outlet in the rotational direction and including a first edge configured to scrape the remaining portion of the sealing surface of the second valve plate when the valve spool rotates from the closed valve position to the open valve position.
8. A plug valve according to claim 2 or 3, further comprising a further scraping structure configured to scrape a first portion of the sealing surface of the second valve plate when the valve element is rotated from the closed position to the open position, the scraping structure being configured to scrape a second portion of the sealing surface of the second valve plate when the valve element is rotated from the closed position to the open position, and to scrape a third portion of the outer surface of the second valve plate when the valve element is rotated from the open position to the closed position, the first portion, the second portion and the third portion in combination covering at least the entire area of the sealing surface of the second valve plate.
9. The plug valve of claim 8, wherein the scraping structure includes a first groove disposed on the opposing surface, the first groove disposed on a downstream side of the fluid outlet in a rotational direction of the valve spool from a closed valve position to an open valve position, and the first groove including a first edge and a second edge, the first edge is configured to scrape a second portion of the sealing surface of the second valve plate when the valve spool rotates from the valve-closed position to the valve-open position, the second edge is configured to scrape a third portion of the sealing surface of the second valve sheet when the valve spool rotates from the valve-open position to the valve-closed position, the other scraping structure comprises a second groove provided on the opposite surface, the second groove being provided on an upstream side of the fluid outlet in the rotation direction, and includes a first edge configured to scrape a first portion of the sealing surface of the second valve plate when the spool rotates from the closed valve position to the open valve position.
10. The plug valve of claim 3, wherein the valve body includes a valve body for receiving the valve core and a plug cover removably mounted to the valve body.
11. A plug valve according to any one of claims 1 to 3, wherein the valve body is provided with a stop member configured to abut the second valve plate to prevent movement of the outer surface of the second valve plate away from the inner surface of the protective sleeve under the influence of fluid pressure.
12. A plug valve according to claim 11, wherein said stop means comprises a first stop means provided on the body of the valve body and/or a second stop means provided on the plug cap.
13. The plug valve of claim 12, wherein the second valve piece has a valve piece body and first and second mating members extending outwardly from both ends of the valve piece body, the first stop member abutting the first mating member and the second stop member abutting the second mating member.
14. The plug valve of claim 3, wherein the outer surface of the protective sleeve is provided with an annular mounting groove having a first portion extending along the outer surface above the first opening, a second portion extending along the outer surface below the second opening, and an intermediate portion extending obliquely across the outer surface to connect the first and second portions, respectively, the annular sealing ring being disposed within the annular mounting groove, the first portion of the annular sealing ring being disposed within the first portion of the annular mounting groove, the second portion of the annular sealing ring being disposed within the second portion of the annular mounting groove, and the third portion of the annular sealing ring being disposed within the intermediate portion of the annular mounting groove.
15. The plug valve of claim 14, wherein the inner surface of the boot has a first annular groove disposed in a first plane perpendicular to the longitudinal axis of the boot and in a different plane than a first portion of the annular mounting groove, the first sealing ring being disposed in the first annular groove.
16. The plug valve of claim 15, wherein the inner surface of the protective sleeve is provided with a second annular groove disposed in a second plane perpendicular to the longitudinal axis of the protective sleeve and in a second plane different from the plane of the second portion of the annular mounting groove, the second sealing ring being disposed within the second annular groove.
17. The plug valve of claim 1, wherein the valve core further comprises a connecting rod having a first end connected to the first valve plate and a second end connected to the second valve plate.
18. The plug valve of claim 17, wherein the first blade has a first groove receiving the first end of the link rod, the second blade has a second groove receiving the second end of the link rod, a first gap exists between the first end of the link rod and the closed end of the first groove, and a second gap exists between the second end of the link rod and the closed end of the second groove, such that the link rod is movable relative to the first blade and the second blade.
19. The plug valve of claim 18, wherein the spool further comprises a first return spring coupled between an inner surface of the first valve plate and the valve stem and a second return spring coupled between an inner surface of the second valve plate and the valve stem.
20. The plug valve of claim 10, wherein the valve body is formed with a mounting hole through which the valve element passes, the plug cover is partially inserted into the protective cover to close the mounting hole, and a plurality of sealing rings are disposed between the protective cover and the plug cover, between the plug cover and the valve body, and between a top of the protective cover and the valve body.
21. The plug valve of claim 3, wherein the protective sleeve is a plastic protective sleeve.
22. The plug valve of claim 3, further comprising a locating pin inserted into said protective sleeve and said valve body to locate the relative position of said protective sleeve and said valve body.
23. A water air conditioner characterised in that it includes a plug valve according to any one of claims 1 to 22.
CN202123398143.7U 2021-12-30 2021-12-30 Plug valve and water air conditioner Active CN217482013U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202123398143.7U CN217482013U (en) 2021-12-30 2021-12-30 Plug valve and water air conditioner

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202123398143.7U CN217482013U (en) 2021-12-30 2021-12-30 Plug valve and water air conditioner

Publications (1)

Publication Number Publication Date
CN217482013U true CN217482013U (en) 2022-09-23

Family

ID=83302900

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202123398143.7U Active CN217482013U (en) 2021-12-30 2021-12-30 Plug valve and water air conditioner

Country Status (1)

Country Link
CN (1) CN217482013U (en)

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