CN215962885U - Drying device and post insulator - Google Patents

Abstract

The utility model discloses a drying device which comprises a drying agent box and a drying agent, wherein the drying agent box is in a cage shape, through holes are formed in the periphery of the drying agent box, the drying agent is wrapped in a cloth bag, and the cloth bag is placed in the drying agent box after being bundled. The drying device has the advantages of simple structure, simple and convenient manufacturing process and low manufacturing cost.

Description

Drying device and post insulator

Technical Field

The utility model relates to the technical field of power transmission and transformation and offshore wind power new energy insulation equipment, in particular to a drying device and a post insulator.

Background

At present, most of post insulators in the industry are solid or filled with solid, pressure gas and the like, when the post insulators are solid or filled with solid, whether water vapor exists in the post insulators or not does not need to be considered, and only the end parts of the post insulators need to be sealed; when the post insulator is filled with pressure gas, the interior of the post insulator is hollow, and a drying device is required to be arranged to remove internal water vapor, so that the drying device for the insulator in the power industry is required to be provided.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects of the prior art, the utility model aims to provide a drying device which is simpler in structure, simpler and more convenient in manufacturing process and lower in manufacturing cost.

In order to achieve the purpose of the utility model, the technical means adopted by the utility model are as follows: a drying device comprises a drying agent box and a drying agent, wherein the drying agent box is in a cage shape, through holes are formed in the periphery of the drying agent box, the drying agent is wrapped in a cloth bag, and the cloth bag is placed in the drying agent box after being bundled

Among the above-mentioned drying device, the periphery of desicator box is equipped with the through-hole, is convenient for absorb moisture, wraps up the drier in the sack simultaneously, can prevent that the drier from scattering.

Preferably, quilting lines are quilted on the cloth bag to enable the cloth bag to form a plurality of small lattices, and the molecular sieve drying agent is filled in the small lattices, so that the drying agent is uniformly filled, the contact area with the outside is uniform and stable, and the drying effect is better exerted.

Preferably, the area that the sack tiled is equal with the cross-sectional area of desiccants box, makes the desiccants can be tiled in the sack in order to realize the contact of maximum area with the external world, effectively absorbs moisture, and drying effect is better.

Preferably, the opening of the drying agent box extends with a connecting lug perpendicular to the drying agent box for connecting other components to fix the drying agent box.

Preferably, the drying agent box is made of an electrically conductive material.

In order to achieve the above object of the present invention, another technical means adopted by the present invention is as follows: the utility model provides a post insulator, includes the flange, is fixed with foretell drying device on the flange to get rid of the inside steam of post insulator.

Preferably, the drying device comprises a desiccant box and a desiccant, wherein the desiccant box is in a cage shape, and the desiccant is placed in the desiccant box.

Preferably, the opening part of drying agent box extends and has the engaging lug perpendicular with drying agent box, is equipped with the connecting hole on the engaging lug, is equipped with the screw hole on the flange, wears to establish the fastener after connecting hole and screw hole match and makes drying agent box and flange fixed connection, just also makes drying agent box fix on the flange.

Preferably, the flange comprises a flange cylinder and a flange disc, the flange cylinder is of a hollow structure along the axial direction, the flange disc covers one end of the flange cylinder, and the drying device is located on the disc surface of the flange disc facing the flange cylinder, so that the drying device is located inside the post insulator.

Preferably, the height of the drying device is smaller than the height of the flange cylinder in the axial direction of the post insulator.

The beneficial effect of this application is: be different from prior art's condition, among the drying device of this application, the periphery of desiccant box is equipped with the through-hole, is convenient for absorb moisture, wraps up the drier in the sack simultaneously, can prevent that the drier from scattering. And, this drying device is used for post insulator, is located post insulator's inside for absorb its inside moisture, prevent that post insulator from appearing the internal insulation flashover scheduling problem.

Drawings

Fig. 1 is a schematic cross-sectional view of a post insulator 10 according to an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of a flange 130 according to an embodiment of the present invention;

FIG. 3 is a schematic cross-sectional view of a flange 130 according to another embodiment of the present invention;

FIG. 4 is an enlarged schematic view of portion A of FIG. 1 in one implementation scenario;

fig. 5 is an enlarged schematic view of a portion a of fig. 1 in another implementation scenario.

Detailed Description

As required, detailed embodiments of the present invention are disclosed herein. However, it is to be understood that the disclosed embodiments are merely exemplary of the utility model, which may be embodied in various forms. Therefore, specific details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present invention in virtually any appropriately detailed manner, including employing various features disclosed herein in combination with features that may not be explicitly disclosed herein.

The term "connected", as used herein, unless otherwise expressly specified or limited, is to be construed broadly, as meaning either directly or through an intermediate connection. In the description of the present invention, it is to be understood that the directions or positional relationships indicated by "upper", "lower", "end", "one end", etc. are based on the directions or positional relationships shown in the drawings, and are only for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a specific direction, be constructed in a specific direction and operate, and thus, should not be construed as limiting the present invention.

As shown in fig. 1, the post insulator 10 includes a hollow insulating tube 110, a shed 120 and two flanges 130, the shed 120 covers the periphery of the hollow insulating tube 110, and the two flanges 130 respectively seal and cover two ends of the hollow insulating tube 110. The hollow insulating tube 110 is a hollow insulating tube formed by pultrusion and winding glass fiber or aramid fiber impregnated epoxy resin, a glass steel tube formed by pultrusion and curing glass fiber impregnated epoxy resin, or an aramid fiber tube formed by pultrusion and curing aramid fiber impregnated epoxy resin, and is not limited herein.

The umbrella skirt 120 is made of a silicon rubber material and is wrapped around the hollow insulating tube 110 in an integral vacuum injection manner, so that the external insulating performance and the service life of the post insulator 10 are integrally improved. Of course, the umbrella skirt may also be made of other rubber materials or insulating materials, and the umbrella skirt may also be fixed on the outer circumferential surface of the hollow insulating tube in other forms such as die pressing, and the like, which is not limited herein.

In an application scenario, the flange 130 includes a flange barrel 131 and a flange 132, the flange barrel 131 is hollow along an axial direction, and the flange 132 covers one end of the flange barrel 131, so that the flange 130 is a structure with one side open and the other side closed. The open sides of the two flange cylinders 131 are respectively sleeved at two ends of the hollow insulating tube 110, and the flanges 130 are sealed and cover the two ends of the hollow insulating tube 110, that is, the post insulator 10 is in a fully closed state, so as to prevent external water vapor and other impurities from entering the interior of the post insulator 10. The flange plate 132 is closed, does not need to be punched, is convenient to process and has good sealing property. At this time, the insulating medium in the hollow insulating tube 110 is ambient air, and the air pressure value in the hollow insulating tube 110 is consistent with the production ambient air pressure value in the process of preparing the post insulator 10. Therefore, the post insulator 10 can be directly packaged in a production environment, the production is convenient, other treatments on insulating media are not needed, the insulating property meets the requirement, the production efficiency is high, and the processing cost is low.

In an application scene, compared with the traditional solid post insulator and the traditional hollow inflatable post insulator, the post insulator 10 with the ambient air as the internal insulation medium is adopted, so that on one hand, the problems of crack defects and interfaces of the post insulator caused by solid filling are avoided, and the electrical performance of the post insulator is influenced; on the other hand, because the ambient air is not filled through the inflation device, the inflation step is omitted, an inflation valve structure, the inflation device, gas and the like are omitted, the structure is simplified, the cost is reduced, the overall cost is reduced by at least 30%, the risk points of gas leakage and process defects are reduced, the post insulator cannot generate a negative pressure state in the operation process, a monitoring device is not needed, special treatment (such as drying treatment and the like) is not needed for the ambient air, and the overall performance is improved.

In an application scenario, the relative value of the air pressure inside the hollow insulating tube 110 is set to 0 MPa.

It should be noted that, in this embodiment, the flanges 130 at both ends of the hollow insulating tube 110 are completely the same, and in other embodiments, the flanges at both ends of the hollow insulating tube may be provided as two different flanges, for example, in order to adapt to different connection strengths, the heights of the two flanges are not set to be the same, or in order to adapt to different connection modes, the positions and the number of the connection holes provided on the flange are not the same, and the like, which is not limited herein.

And, in this embodiment, the flange 130 is made of an aluminum alloy material, and the flange cylinder 131 and the flange 132 are integrally formed, that is, formed by integral casting, and thus the structure is relatively simple and easy to manufacture. Of course, in other embodiments, the flange may be made of steel or other metal materials, and the flange cylinder and the flange may also be formed separately and then fixedly connected by welding, which is not limited herein.

In an application scenario, as shown in fig. 1 and 2, the hollow insulating tube 110 and the two flanges 130 are fixed by glue. Specifically, the outer diameter of the hollow insulating tube 110 is slightly smaller than the inner diameter of the flange cylinder 131. A plurality of inner annular grooves 1311 are axially arranged on the inner wall of the flange barrel 131 at intervals along the flange barrel 131, a plurality of outer annular grooves (not shown) are axially arranged on the outer wall of the hollow insulating tube 110 at intervals along the hollow insulating tube 110, the size and the number of the inner annular grooves 1311 and the outer annular grooves are consistent, the hollow insulating tube 110 is sleeved in the flange barrel 131, and when one end of the hollow insulating tube 110 is abutted to the disc surface of the flange 132 facing the hollow insulating tube 110, the inner annular grooves 1311 and the outer annular grooves are matched in position and correspond to each other. Furthermore, a glue injection hole (not shown) is formed in the flange 130, and an adhesive is filled between the outer wall of the hollow insulating tube 110 and the flange 130, specifically, after the glue injection hole is formed in the outer wall of the flange cylinder 131, the adhesive is injected into the glue injection hole, so that the adhesive is filled in a cavity formed by the inner annular groove 1311 and the outer annular groove, and the hollow insulating tube 110 and the flange 130 are connected and fixed through the adhesive. The above-mentioned gluing method can adopt horizontal gluing or vertical gluing, as long as the flange 130 and the hollow insulating tube 110 can be fixed by gluing. In another application scenario, the outer wall of the hollow insulating tube 110 and/or the inner wall of the flange cylinder 131 may be coated with an adhesive and then glued.

Continuing to refer to fig. 2, a circulation groove 1312 communicated with the inner annular grooves 1311 is further formed in the inner wall of the flange cylinder 131, the circulation groove 1312 is filled after the adhesive is injected into the flange cylinder 131, the inner annular grooves 1311 and the circulation groove 1312 are solidified to form a cross structure, the flange cylinder 131 and the hollow insulating pipe 110 can be further fixedly connected, the adhesive injected between the flange cylinder 131 and the hollow insulating pipe 110 can circulate between the adjacent inner annular grooves 1311, the adhesive injection rate can be increased, the risk of air bubble retention is reduced, the flange 130 and the hollow insulating pipe 110 are combined more firmly, and the torsion resistance of the post insulator 10 is improved on the premise that the adhesive with better bonding property is not replaced.

Here, the number of the flow grooves 1312 may be one, or may be plural (for example, two, four, six, or even more), and when the number of the flow grooves 1312 is plural, the plural flow grooves 1312 are provided at intervals in the circumferential direction of the flange cylinder 131. One flow groove 1312 may communicate with only two adjacent inner annular grooves 1311, or may communicate with three, four or even all adjacent inner annular grooves 1311, which is not limited herein.

The bottom surface of the flow channel 1312 is a flat surface or a curved surface. Specifically, when the radial depth and width of the flow channel 1312 relative to the flange 130 are fixed, the flow channel 1312 with the flat bottom surface has more complicated and expensive processing, but higher torsional strength than the flow channel 1312 with the curved bottom surface, because the contact area between the adhesive in the flat channel and the inner wall of the flange cylinder 131 is larger, that is, the flow channel 1312 with the curved bottom surface has more convenient processing and lower processing cost than the flow channel 1312 with the flat bottom surface, but the torsional strength is slightly lower.

Further, in the axial direction of the post insulator 10, the ratio (i.e., the cementing ratio) of the length of the portion of the inner wall of the flange cylinder 131 contacting the hollow insulating tube 110 to the outer diameter of the hollow insulating tube 110 is in the range of 0.2 to 1.0, for example, 0.2, 0.5, 0.8, or 1.0. Specifically, as the binding ratio decreases, the strength of the post insulator 10 decreases significantly, for example, when the binding ratio is decreased to 0.15, the strength of the post insulator 10 decreases by 20% compared to 0.2, and when the binding ratio is increased to 1.2, the strength of the post insulator 10 increases slightly but the cost increases significantly compared to 1.0, so that the post insulator 10 can have advantages such as low cost and high strength at the same time by setting the binding ratio in the range of 0.2 to 1.0.

With reference to fig. 1 and 2, a first sealing groove 133 is disposed on a disk surface of the flange 132 facing the hollow insulating tube 110, the first sealing groove 133 is located inside the flange barrel 131, and a first sealing element (not shown) is disposed in the first sealing groove 133. Specifically, the first sealing element is disposed in the first sealing groove 133, and when one end of the hollow insulating tube 110 abuts against the disk surface of the flange 132 facing the hollow insulating tube 110, the first sealing element is clamped between the disk surface of the flange 132 and the end surface of the hollow insulating tube 110, so as to perform a sealing function, prevent a gap from being left between the hollow insulating tube 110 and the flange barrel 130, and prevent external water vapor from entering the hollow insulating tube 110, thereby preventing the micro water value in the hollow insulating tube 110 from being too high.

In one embodiment, when the hollow insulating tube 110 and the two flanges 130 are fixed by gluing, the inner wall of the flange barrel 131 is further provided with a second sealing groove 134 adjacent to the flange 132, and a second sealing member (not shown) is provided in the second sealing groove 134. Specifically, the second sealing element has a different function from the first sealing element, and the second sealing element is used to prevent an adhesive in the process of cementing the flange 130 and the hollow insulating tube 110 from entering the first sealing groove 133 to corrode the first sealing element, so that the first sealing element is prevented from failing, and the sealing between the hollow insulating tube 110 and the flange 130 is prevented from being affected.

In other embodiments, when the hollow insulating tube 110 and the two flanges 130 are fixed by gluing, the second sealing groove and the second sealing element may not be provided, as long as the flange 130 is sleeved in the end of the hollow insulating tube 110, the flange 132 is in sufficient contact with the end of the hollow insulating tube 110, so that the first sealing element is sufficiently compressed, and further, the flange 132 and the end of the hollow insulating tube 110 are in a sealed state, and the adhesive in the gluing process cannot enter the contact surface between the flange 132 and the hollow insulating tube 110.

Referring to fig. 1, 4 and 5, the width of the first sealing groove 133 is constant (as shown in fig. 4) or gradually decreases (as shown in fig. 5) in a direction approaching the hollow insulating tube 110. Specifically, the first sealing groove 133, the width of which is kept constant in the direction close to the hollow insulating tube 110, is convenient to process, but the first sealing element therein may slide or even fall off, and in this case, in order to avoid the first sealing element from sliding relatively in the first sealing groove 133, the first sealing element is further fixed in the first sealing groove 133 by an adhesive, and the adhesive may be resin or silica gel; compared with the first sealing groove 133 with the width being unchanged in the direction close to the hollow insulating tube 110, the first sealing groove 133 with the width gradually decreasing in the direction close to the hollow insulating tube 110 can ensure that the first sealing element cannot easily fall off although the processing process is more complicated, and in the scheme, the first sealing element can be bonded and fixed in the first sealing groove through the adhesive, so that the first sealing element is further prevented from falling off. The width of the first sealing groove 133 may be linearly decreased in a direction approaching the hollow insulating tube 110 (as shown in fig. 4), or may be curvilinearly decreased (not shown), which is not limited herein.

The second sealing groove 134 has the same structure as the first sealing groove 133, and will not be described herein.

In another application scenario, referring to fig. 1 and fig. 2, the hollow insulating tube 110 is fixedly connected to the two flanges 130 through interference fit, at this time, the outer diameter of the hollow insulating tube 110 is slightly larger than the inner diameter of the flange barrel 131, and the hollow insulating tube 110 is press-fitted into the flange barrel 131 through a pressure device, so that the end surface of the hollow insulating tube 110 abuts against the disk surface of the flange 132.

A first sealing groove 133 is disposed on a disk surface of the flange 132 facing the hollow insulating tube 110, the first sealing groove 133 is located inside the flange barrel 131, and a first sealing member (not shown) is disposed in the first sealing groove 133. Specifically, the first sealing element is disposed in the first sealing groove 133, and when one end of the hollow insulating tube 110 abuts against the disk surface of the flange 132 facing the hollow insulating tube 110, the first sealing element is clamped between the disk surface of the flange 132 and the end surface of the hollow insulating tube 110, so as to perform a sealing function, prevent a gap from being left between the hollow insulating tube 110 and the flange barrel 130, and prevent external water vapor from entering the hollow insulating tube 110, thereby preventing the micro water value in the hollow insulating tube 110 from being too high.

The adhesive is coated on the outer wall of the hollow insulating tube 110 and/or the inner wall of the flange barrel 131, so that the connection strength between the hollow insulating tube 110 and the flange 130 is further improved, and the adhesive further seals the tightly combined hollow insulating tube 110 and the flange barrel 131, so that other sealing structures do not need to be arranged between the outer wall of the hollow insulating tube 110 and the inner wall of the flange barrel 131, that is, the second sealing groove and the second sealing element do not need to be arranged.

Specifically, when hollow insulating tube 110 and two flanges 130 pass through interference fit fixed connection, hollow insulating tube 110 and flange 130 complex magnitude of interference make between the two can combine closely, then need not to set up the second seal groove again, can also scribble the gluing agent between hollow insulating tube 110 and a flange section of thick bamboo 131 in addition, further improve the joint strength between hollow insulating tube 110 and a flange section of thick bamboo 131, gluing agent between hollow insulating tube 110 and a flange section of thick bamboo 131 can form further sealedly simultaneously, guarantee sealed effect.

Further, when the hollow insulating tube 110 is fixedly connected with the two flanges 130 through interference fit, since the adhesive is directly coated between the hollow insulating tube 110 and the flange barrel 131, the inner wall of the flange barrel 131 also does not need to be provided with the inner annular groove and the circulation groove, so that the structure of the flange 130 is further simplified, the process steps are reduced, the production efficiency is improved, and the cost is reduced. Of course, in other embodiments, the inner wall of the flange cylinder 131 may still be provided with an inner annular groove and a flow channel, so that the adhesive is fully filled between the hollow insulating tube 110 and the flange cylinder 131, thereby improving the connection strength.

With continued reference to fig. 1, the disk surface of the flange 132 facing the hollow insulating tube 110 is further provided with a drying device 140 for removing moisture inside the post insulator 10, and the drying device 140 is located inside the hollow insulating tube 110 and includes a drying agent box 141 and a drying agent 142 disposed inside the drying agent box 141, which is simple in structure and convenient to manufacture. Specifically, the desiccant container 141 has a cage shape, the desiccant container 141 is reversely fastened to the flange 130, and the desiccant is disposed in the desiccant container 141. A connecting lug (not shown) perpendicular to the drying agent box 141 extends from the opening of the drying agent box 141, and a plurality of connecting holes (not shown) are formed in the connecting lug and are used for being fixedly connected with the disk surface of the flange 130 facing the hollow insulating tube 110.

It should be noted that, in other embodiments, the drying device may have other structures, for example, the drying agent box is not provided with a connecting lug, and the drying agent box is fixed on the flange by welding, which is not limited herein. Simultaneously, drying device also can all set up a plurality of on two flanges.

The drying agent box 141 may be made of a conductive material, such as a metal material. And the through holes with the same size and uniform distribution are arranged on the periphery of the drying agent box 141 to form a shielding cage, and the principle of the shielding cage is utilized to ensure that the drying agent box 141 does not influence the internal electric field of the hollow insulating tube 110. Of course, the desiccant cartridge may also be made of a non-conductive material, such as plastic.

In other embodiments, the material and shape of the drying agent box are not limited to this embodiment, and the distribution and size of the through holes are not limited to this embodiment as long as the requirements of the shielding cage can be satisfied. And, in the axial of the post insulator 10, the height of the drying device is set to be less than that of the flange cylinder, so that the drying device made of metal is prevented from influencing the electric field distribution near the flange. Of course, the height of the drying device may also be set to be the same as the height of the flange cylinder or slightly higher than the height of the flange cylinder, as long as the drying device can satisfy the shielding cage principle, i.e. the electric field inside the hollow insulating tube 110 is not affected.

Wherein, the desiccant is packed in the cloth bag and bound up to prevent the desiccant from scattering.

In an application scenario, the cloth bag packed with the drying agent is fixed in the drying agent box 141, and in order to avoid the cloth bag from being knocked and damaged due to external force during transportation and installation of the post insulator 10, the cloth bag can be fixed by means of bundling and the like.

In another application scenario, the cloth bag is made into a thin cloth bag, so that the area of the cloth bag laid on the disc surface of the flange 132 is as large as possible, and further, the drying agent can be laid in the cloth bag to be in contact with the ambient air in the hollow insulating tube 110 in the largest area, so that the drying agent can effectively absorb moisture, and the drying effect is better. Preferably, the area of the flat spread of the cloth bag is equal to the cross-sectional area of the drying agent box 141. Further, sew with long stitches or the sew with long stitches of the criss-cross check of system cross on the sack etc. make and form a plurality of little check on the sack, all pack in every little check and have the drier, guarantee that the drier evenly fills, it is stable with the area homogeneous of the interior ambient air contact of hollow insulating tube 110, exert drying action better, avoid the drier simultaneously because gravity influences, pile up certain department in the sack and influence its adsorption efficiency.

Referring to fig. 1 and 2, in an application scenario, the flange 132 has an equal thickness, the drying device 140 is fixed on the surface of the flange 132 facing the hollow insulating tube 110, and the drying device 140 can be fixed on the flange 132 by welding, gluing, screwing, or the like. In addition, when adopting the spiro union mode, need set up the screw hole on the quotation of ring flange 132, punch and to a certain extent can influence the mechanical properties of ring flange 132, consequently in another application scenario, also can thicken the thickness of ring flange 132 to realize good mechanical properties.

With reference to fig. 1 and 3, in another application scenario, a boss 1321 is disposed on one side of the flange 132 close to the hollow insulating tube 110, and the drying device 140 is fixedly connected to the boss 1321, so that the mechanical property of the flange 132 is not affected by the screw holes 1322 without increasing the thickness of the flange 132 as a whole, and the economy is more superior. Specifically, the boss 1321 is disposed coaxially with the flange 132, the boss 1321 extends in the axial direction of the flange 130 in the direction away from the flange 132, and the disk outer diameter of the boss 1321 is smaller than the inner diameter of the flange barrel 131, specifically, the disk outer diameter of the boss 1321 only needs to be slightly larger than or equal to the outer diameter of the drying device 140 so as to fix the drying device 140, so that a step surface is formed between the boss 1321 and the disk surface of the flange 132 facing the hollow insulating tube 110, the material consumption of the flange 130 is reduced as much as possible, the cost can be saved, and the weight of the flange 130 can be reduced. At this time, the screw hole 1322 is provided in the boss 1321, that is, the drying device 140 is connected and fixed to the boss 1321. Assuming that the height of the protruding flange 132 of the boss 1321 toward the disk surface of the hollow insulating tube 110 is H (as shown in fig. 3), the depth of H is consistent with that of the screw holes 1322, so that the mechanical property of the flange 130 is prevented from being affected by the arrangement of the screw holes 1322, excessive material waste can be avoided, and the economical efficiency is good. Meanwhile, the surface of the boss 1321 may be circular as the flange 132, or may be in other shapes, such as square, diamond, etc., and the boss 1321 and the flange 132 may be integrally formed, or may be fixedly connected by other manners, which is not limited herein. The screw holes 1322 formed in the boss 1321 correspond to the coupling holes, and after the coupling holes are matched with the screw holes 1322, screws are inserted to fixedly couple the drying device 140 to the flange 130.

The beneficial effect of this application is: different from the prior art, the post insulator 10 of the present application is a hollow structure, that is, the core of the post insulator 10 adopts the hollow insulating tube 110, and the inside of the hollow insulating tube 110 is ambient air, so that on one hand, the crack defect and the interface problem of the post insulator 10 caused by solid filling are avoided, and the electrical performance of the post insulator 10 is affected; on the other hand, because the ambient air is not filled through the inflation device, the step of inflation is then removed from, therefore also need not to set up the inflation device on its flange 130, for example inflation valve etc. simplified the structure, the cost is reduced, compare in traditional structure, the overall cost has reduced 30% at least, reduced gas leakage, the risk point of technology defect simultaneously, post insulator 10 can not produce the negative pressure state in the operation process, consequently need not to set up monitoring devices, and the ambient air also need not to carry out special treatment (for example drying process etc.), and overall performance is promoted. Meanwhile, the three layers of seals are arranged on the contact surface of the hollow insulating tube 110 and the flange 130, so that the overall sealing performance of the post insulator 10 is further improved, and external water vapor is prevented from entering the interior of the post insulator 10.

While the utility model has been described with reference to the above disclosure and features, it will be understood by those skilled in the art that various changes and modifications in the above constructions and materials can be made, including combinations of features disclosed herein either individually or in any combination, as appropriate, without departing from the spirit of the utility model. Such variations and/or combinations are within the skill of the art to which the utility model pertains and are within the scope of the following claims.

Claims (9)

1. The drying device is characterized by comprising a drying agent box and a drying agent, wherein the drying agent box is in a cage shape, through holes are formed in the periphery of the drying agent box, the drying agent is wrapped in a cloth bag, the cloth bag is placed in the drying agent box after being bundled, and the tiled area of the cloth bag is equal to the cross-sectional area of the drying agent box.

2. The drying apparatus of claim 1, wherein said cloth bag is quilted to form cells in said cloth bag, said cells being filled with said desiccant.

3. The drying apparatus of claim 1, wherein the opening of the drying agent box is extended with a coupling lug perpendicular to the drying agent box.

4. Drying apparatus according to claim 1 in which the desiccant container is made of an electrically conductive material.

5. Post insulator, comprising a flange to which a drying device according to any one of claims 1 to 4 is fixed.

6. The post insulator of claim 5, wherein said drying means includes a desiccant container and a desiccant, said desiccant container having a cage shape, said desiccant being disposed within said desiccant container.

7. The post insulator according to claim 6, wherein a connecting lug perpendicular to the drying agent box extends from the opening of the drying agent box, a connecting hole is formed in the connecting lug, a screw hole is formed in the flange, and a fastener is arranged through the connecting hole after the connecting hole is matched with the screw hole to fixedly connect the drying agent box with the flange.

8. The post insulator of claim 5, wherein said flange includes a flange barrel and a flange plate, said flange barrel being axially hollow, said flange plate covering an end of said flange barrel, said drying means being located on a face of said flange plate facing said flange barrel.

9. The post insulator of claim 8, wherein the height of the drying means is smaller than the height of the flange cylinder in the axial direction of the post insulator.

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