CN110586326A

CN110586326A - Cathode frame and wet-type electrostatic precipitator

Info

Publication number: CN110586326A
Application number: CN201910965100.0A
Authority: CN
Inventors: 任海涛; 许曼; 王宏
Original assignee: Shenhua Tianjin Coal Dock Co Ltd
Current assignee: Guoneng Tianjin Port Co ltd
Priority date: 2019-10-11
Filing date: 2019-10-11
Publication date: 2019-12-20
Anticipated expiration: 2039-10-11
Also published as: CN110586326B

Abstract

The invention relates to a cathode frame and a wet-type electric dust collector, which comprise a cathode hanging beam, cathode wires, a first connecting piece and a pushing piece, wherein the cathode wires are hung on the cathode hanging beam, and a plurality of cathode wires are arranged at intervals along the length direction of the cathode hanging beam; one end of the first connecting piece is movably connected to the cathode hanging beam, and the other end of the first connecting piece is connected to the cathode line; the pushing piece is abutted against or connected with the cathode wire and is used for pushing the cathode wire to move. The pushing piece drives the cathode wire to move, and then drives the first connecting piece to move relative to the cathode hanging beam, and finally the cathode wire moves relative to the cathode hanging beam, so that the distance from the cathode wire to the anode plate is adjusted, and the dust removal efficiency of the electric dust remover is convenient to change. In addition, the cathode frame is simple in structure, a swing-proof rod is not needed, the height of the electric dust collector is favorably reduced, the cost is reduced, the generation of a creepage phenomenon is effectively reduced, and the service life of the electric dust collector is favorably prolonged.

Description

Cathode frame and wet-type electrostatic precipitator

Technical Field

The invention relates to the technical field of wet-type electric dust collectors, in particular to a cathode frame and a wet-type electric dust collector.

Background

The conventional wet-type electric precipitator cathode frame includes cathode hanger beams and cathode wires. Pressure-bearing insulators are arranged at two ends of the electric dust collector shell, and the cathode hanging beam is transversely arranged on the two pressure-bearing insulators. The upper ends of a plurality of cathode wires are hung on the cathode hanging beam according to a specified interval, a piece of anode plate is arranged between every two adjacent cathode wires, the lower ends of the cathode wires are connected with the anti-swing rod, the two ends of the anti-swing rod are connected with the shell of the electric dust collector through a connecting plate with a long eye groove, the long eye groove is vertically downward, the two ends of the anti-swing rod can slide in the long eye groove, and the position of the cathode wires can be adjusted. However, the anti-swing rod is arranged in the wet electric dust collector, so that the wet electric dust collector is higher in height, and the cost is increased. In addition, after the anti-swing rod is used, the creepage phenomenon is easily generated in the wet electric dust collector, so that the normal operation of the wet electric dust collector is influenced.

Disclosure of Invention

In view of the above, there is a need to provide a cathode frame and a wet electric dust collector which can effectively prevent the generation of the creepage phenomenon, have a simple structure, and reduce the cost.

A cathode frame comprising:

a cathode suspension beam;

the cathode wires are suspended on the cathode hanging beam, and the plurality of cathode wires are arranged at intervals along the length direction of the cathode hanging beam;

one end of the first connecting piece is movably connected to the cathode hanging beam, and the other end of the first connecting piece is connected to the cathode line;

and the pushing piece is abutted against or connected with the cathode wire and is used for pushing the cathode wire to move.

The technical solution is further explained below:

in one embodiment, the cathode hanging beam is provided with a first mounting hole along the length direction thereof, one end of the first connecting piece is arranged in the first mounting hole in a penetrating manner, and the first connecting piece can move along the length direction of the cathode hanging beam in the first mounting hole.

In one embodiment, the cathode frame further includes a second connecting member fixed to the cathode suspension beam, the second connecting member is provided with a second mounting hole, one end of the first connecting member is inserted into the second mounting hole, and the first connecting member is movable in the second mounting hole along the length direction of the cathode suspension beam.

In one embodiment, the second connecting member is an angle steel connecting member, one end of the angle steel connecting member is connected to the cathode hanging beam, the other end of the angle steel connecting member is provided with the second mounting hole, and the second mounting hole is a kidney-shaped hole arranged along the length direction of the cathode hanging beam.

In one embodiment, the first connecting member comprises a pin shaft seat and a pin shaft penetrating through the pin shaft seat, the pin shaft seat is movably connected to the cathode hanging beam, the pin shaft is arranged in the pin shaft seat, and the end of the pin shaft extends out of the pin shaft seat and is connected to the cathode wire.

In one embodiment, the pushing pieces and the cathode wires are arranged in a one-to-one correspondence mode, the pushing pieces are connected to the cathode wires, and when the pushing pieces move, the pushing pieces drive the cathode wires to move.

In one embodiment, two side surfaces of the cathode wire respectively abut against at least one pushing piece, the pushing pieces abut against the side surfaces of the cathode wire, and when the pushing pieces on the two side surfaces of the cathode wire move in the same direction for equal distances, the pushing pieces drive the cathode wire to move.

In one embodiment, the surface of the cathode hanging beam facing the cathode wire is provided with a fixed part, and the pushing part is movably connected with the fixed part.

In one embodiment, the fixing part is flat steel, and the pushing part is an adjusting bolt.

The wet electric dust collector comprises a shell and the cathode frame, wherein the cathode frame is arranged in the shell.

The cathode frame and the wet electric dust collector at least have the following beneficial effects:

(1) the cathode frame provided by the embodiment connects the cathode line to the cathode hanging beam by arranging the first connecting piece. The cathode lines are respectively connected to the first connecting piece and the pushing piece. When the pushing piece is moved, the first connecting piece can move relative to the cathode hanging beam, so that the pushing piece drives the cathode wire to move, the first connecting piece is further driven to move relative to the cathode hanging beam, and finally the cathode wire moves relative to the cathode hanging beam, so that the distance from the cathode wire to the anode plate is adjusted, and the dust removal efficiency of the electric dust remover is convenient to change. This negative pole frame construction is simple, need not use and prevents the pendulum rod, is favorable to reducing the height of electrostatic precipitator, and reduce cost effectively reduces the production of creepage simultaneously, is favorable to improving electrostatic precipitator's life.

Drawings

Fig. 1 is a schematic structural diagram of a cathode frame according to an embodiment of the present invention;

FIG. 2 is an enlarged schematic view of FIG. 1 at P;

FIG. 3 is a schematic top view of the structure of FIG. 2;

fig. 4 is a schematic structural view of a cathode suspension beam provided in another embodiment of the present invention and connected to a second connection member;

fig. 5 is a schematic structural view of a cathode frame with a pushing member disposed only on one side of a cathode line according to another embodiment of the present invention.

Description of reference numerals: 100. a cathode frame; 110. a cathode suspension beam; 111. a first mounting hole; 112. a fixed part; 120. a cathode line; 130. a first connecting member; 131. a pin shaft seat; 132. a pin shaft; 140. a pusher member; 150. an anode plate; 160. a second connecting member; 161. a second mounting hole; 162. a first folded surface; 163. a second folded surface; 200. a pressure-bearing insulator; 300. a housing.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, but rather should be construed as broadly as the present invention is capable of modification in various respects, all without departing from the spirit and scope of the present invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The present embodiment provides a cathode frame 100 and a wet type electric precipitator having the advantages of effectively preventing the generation of the creepage phenomenon, having a simple structure, and reducing the cost, which will be described in detail with reference to the accompanying drawings.

In one embodiment, referring to fig. 1 to 3, a cathode frame 100 includes a cathode suspension beam 110, a cathode wire 120, a first connecting member 130, and a pushing member 140. The cathode lines 120 are suspended from the cathode hanger beam 110, and a plurality of cathode lines 120 are arranged at intervals along the length direction of the cathode hanger beam 110. The longitudinal direction is a direction in which the longest side of the cathode suspension beam 110 is located. One end of the first connector 130 is movably connected to the cathode hanging beam 110, and the other end of the first connector 130 is connected to the cathode line 120. The pushing member 140 abuts or is connected to the cathode line 120 for pushing the cathode line 120 to move.

The conventional wet electrostatic precipitator cathode frame 100 includes cathode hanger beams 110 and cathode wires 120. Pressure-bearing insulators 200 are arranged at two ends of the electric dust collector shell 300, and the cathode hanging beam 110 is transversely arranged on the two pressure-bearing insulators 200. The upper ends of a plurality of cathode wires 120 are hung on the cathode hanging beam 110 at regular intervals, a piece of anode plate 150 is arranged between every two adjacent cathode wires 120, the lower ends of the cathode wires 120 are connected with the anti-swing rod, the two ends of the anti-swing rod are connected with the shell 300 of the electric dust collector through the connecting plate processed with the long-hole groove, the long-hole groove is vertically downward, the two ends of the anti-swing rod can slide in the long-hole groove, and the position of the cathode wires 120 can be adjusted. However, the anti-swing rod is arranged in the wet electric dust collector, so that the wet electric dust collector is higher in height, and the cost is increased. In addition, after the anti-swing rod is used, the creepage phenomenon is easily generated in the wet electric dust collector, so that the normal operation of the wet electric dust collector is influenced.

However, the cathode frame 100 of the present embodiment connects the cathode line 120 to the cathode hanger beam 110 by providing the first connection member 130. The cathode line 120 is connected to the first connecting member 130 and the pushing member 140, respectively. When the pushing member 140 is moved, since the first connecting member 130 can move relative to the cathode hanging beam 110, the pushing member 140 drives the cathode wire 120 to drive the first connecting member 130 to move relative to the cathode hanging beam 110, and finally the cathode wire 120 moves relative to the cathode hanging beam 110, so as to adjust the distance from the cathode wire 120 to the anode plate 150, which is beneficial to adjusting the dust removal efficiency of the electric dust remover at any time. This negative pole frame 100 simple structure need not use and prevents the pendulum rod, is favorable to reducing electrostatic precipitator's height, and reduce cost effectively reduces the production of creepage phenomenon simultaneously, is favorable to improving electrostatic precipitator's life.

In one embodiment, referring to fig. 1 to 3, the cathode hanging beam 110 is provided with a first mounting hole 111 along the length direction thereof, one end of the first connecting element 130 is inserted into the first mounting hole 111, and the first connecting element 130 is movable in the first mounting hole 111 along the length direction of the cathode hanging beam 110. Specifically, the first mounting hole 111 may be a kidney-shaped hole, the first connecting member 130 may be a rod member, and an end cap is disposed at the top of the rod member. After the rod piece is arranged in the waist-shaped hole in a penetrating mode, the end cover of the rod piece cannot pass through the waist-shaped hole due to the fact that the end cover is large in size, and therefore the rod piece can move in the waist-shaped hole along the length direction of the waist-shaped hole. The end of the rod far from the end cap is connected with the end of the cathode wire 120 by screwing, welding, etc., and is not limited in this respect. Thus, when the pushing member 140 drives the cathode wire 120 to move, the cathode wire 120 drives the rod member to move in the kidney-shaped hole, and finally the cathode wire 120 moves relative to the cathode hanging beam 110, so that the distance from the cathode wire 120 to the anode plate 150 can be adjusted, which is beneficial to conveniently and rapidly adjusting the dust removal efficiency of the electric dust collector.

As another alternative, referring to fig. 1 and 4, the cathode frame 100 further includes a second connecting member 160. The second connecting member 160 is fixed to the cathode hanging beam 110, the second connecting member 160 is provided with a second mounting hole 161, one end of the first connecting member 130 is inserted into the second mounting hole 161, and the first connecting member 130 can move in the second mounting hole 161 along the length direction of the cathode hanging beam 110. Specifically, the second connection member 160 may be an angle steel connection member, one end of which is connected to the cathode hanging beam 110, and the other end of which is provided with a second mounting hole 161. The angle iron connector includes a first folded surface 162 and a second folded surface 163, and the first folded surface 162 is fixed to the cathode suspension beam 110 by welding, screwing, or the like. The second folded surface 163 is parallel to the surface of the cathode hanging beam 110 facing the cathode line 120, and the second folded surface 163 is provided with a second mounting hole 161. The second mounting hole 161 is a kidney-shaped hole formed along the length direction of the cathode hanging beam 110, and the first connecting member 130 may still be a rod member having an end cap at the top thereof. After the rod piece is arranged in the waist-shaped hole in a penetrating mode, the end cover of the rod piece cannot pass through the waist-shaped hole due to the fact that the end cover is large in size, and therefore the rod piece can move in the waist-shaped hole along the length direction of the waist-shaped hole. The end of the rod far from the end cap is connected with the end of the cathode wire 120 by screwing, welding, etc., and is not limited in this respect. Thus, when the pushing member 140 drives the cathode wire 120 to move, the cathode wire 120 drives the first connecting member 130 to move in the second mounting hole 161, and finally the cathode wire 120 moves relative to the cathode hanging beam 110, so that the distance from the cathode wire 120 to the anode plate 150 can be adjusted, which is beneficial to changing the dust removal efficiency of the electric dust remover.

It is understood that the first connecting member 130 may have other connecting structures besides the above-mentioned rod structure, and is not limited in particular. The second connecting member 160 may be an angle steel connecting member or a metal plate, one end of the metal plate is fixed to the cathode suspension beam, and the other end of the metal plate is provided with a second mounting hole 161 for penetrating the first connecting member 130.

Further, referring to fig. 1 to 3, the first connecting member 130 includes a pin shaft seat 131 and a pin shaft 132 passing through the pin shaft seat 131, the pin shaft seat 131 is movably connected to the cathode hanging beam 110, the pin shaft 132 is disposed in the pin shaft seat 131, and an end of the pin shaft 132 extends out of the pin shaft seat 131 and is connected to the cathode wire 120. Specifically, the cathode hanging beam 110 is provided with a waist-shaped hole, the width of the waist-shaped hole is smaller than the outer diameter of the pin shaft seat 131, the width of the waist-shaped hole is larger than or equal to the inner diameter of the pin shaft seat 131, and the length of the waist-shaped hole is larger than the outer diameter of the pin shaft seat 131. Thus, the pin shaft seat 131 does not pass through the kidney-shaped hole, but only outside the kidney-shaped hole, but the pin shaft 132 can pass through the kidney-shaped hole. Thus, one end of the pin 132 is inserted into the pin holder 131, and the other end of the pin 132 is connected to the cathode ray 120 through the kidney hole. The other end of the pin 132 is connected to the cathode line 120 by screwing. It is understood that the pin 132 and the cathode wire 120 may be connected together by welding or other methods. And is not particularly limited herein. Thus, when the pushing member 140 drives the cathode wire 120 to move, the cathode wire 120 drives the pin shaft 132 and the pin shaft seat 131 to move along the kidney-shaped hole, and finally the cathode wire 120 moves relative to the cathode hanging beam 110, so that the distance from the cathode wire 120 to the anode plate 150 can be adjusted, and the dust removal efficiency of the electric dust remover can be changed.

In one embodiment, referring to fig. 5, the pushing members 140 are disposed corresponding to the cathode lines 120, the pushing members 140 are connected to the cathode lines 120, and when the pushing members 140 move, the pushing members 140 drive the cathode lines 120 to move. Since the pushing member 140 and the cathode wire 120 are connected, when the pushing member 140 moves, the cathode wire 120 moves along with the pushing member, and the first connecting member 130 connected to the cathode wire 120 also moves along the length direction of the cathode suspension beam 110, so that the cathode wire 120 moves relative to the cathode suspension beam 110, thereby adjusting the distance from the cathode wire 120 to the anode plate 150.

As another alternative, please refer to fig. 1 and fig. 2, two side surfaces of the cathode line 120 respectively abut against at least one pushing member 140, and the pushing member 140 abuts against the side surface of the cathode line 120. When the pushers 140 on the two sides of the cathode line 120 move in the same direction for an equal distance, the pushers 140 drive the cathode line 120 to move. Since the pushers 140 and the cathode lines 120 are in an interference relationship, the pushers 140 on both sides of the cathode lines 120 sandwich the cathode lines 120. When the pushers 140 on both sides of the cathode line 120 move in the same direction for an equal distance, the cathode line 120 clamped between the pushers 140 also moves in the same direction for an equal distance, and the first connecting member 130 connected to the cathode line 120 also moves in the length direction of the cathode suspension beam 110, so that the cathode line 120 moves relative to the cathode suspension beam 110, and the distance from the cathode line 120 to the anode plate 150 can be adjusted.

Further, referring to fig. 1 and 2, the cathode hanging beam 110 has a fixing portion 112 on a surface thereof facing the cathode line 120, and the pushing member 140 is movably connected to the fixing portion 112. Specifically, the fixing portion 112 is provided with a through hole (not shown), and the pushing member 140 is inserted into the through hole.

Referring to fig. 5, when the pushing members 140 and the cathode lines 120 are disposed in a one-to-one correspondence, the fixing portions 112 and the cathode lines 120 are also disposed in a one-to-one correspondence. A fixing part 112 is provided at one side of a cathode line 120, and a pushing part 140 is connected to the cathode line 120 after passing through a through hole of the fixing part 112. At this time, only the pushing member 140 needs to be controlled to move relative to the fixing portion 112, the pushing member 140 drives the cathode wire 120 to move toward the direction close to the fixing portion 112 or away from the fixing portion 112, and the first connecting member 130 connected to the cathode wire 120 is also driven by the cathode wire 120 to move along the length direction of the cathode hanging beam 110, so that the cathode wire 120 finally moves relative to the cathode hanging beam 110.

Referring to fig. 2, when two side surfaces of the cathode line 120 respectively abut against at least one pushing member 140, two sides of one cathode line 120 are respectively provided with a fixing portion 112. Specifically, the fixing portion 112 is provided with a through hole, and the pushing member 140 is disposed through the through hole. The pushing members 140 on both sides of the cathode line 120 respectively penetrate through the through holes of the fixing portions 112 on both sides of the cathode line 120 and then abut against the cathode line 120. At this time, it is only necessary to move the pushing members 140 on both sides of the cathode line 120, so that the pushing members 140 move relative to the fixing portion 112, and the pushing members 140 on both sides of the cathode line 120 move in the same direction, and the cathode line 120 sandwiched between the pushing members 140 also moves. The first connecting member 130 connected to the cathode wire 120 is also moved along the length direction of the cathode hanging beam 110 by the cathode wire 120, and finally the cathode wire 120 is moved relative to the cathode hanging beam 110. Since the anode plate 150 is fixedly disposed in the cathode frame 100, the distance between the cathode wire 120 and the anode plate 150 is changed after the cathode wire 120 moves, thereby changing the dust removing efficiency of the electric dust remover. Thus, a better dust removal effect can be obtained by continuously adjusting the position of the cathode line 120 relative to the anode plate 150.

Specifically, referring to fig. 2, the fixing portion 112 is a flat steel, and the pushing member 140 is an adjusting bolt. The flat steel is disposed on a surface of the cathode hanging beam 110 facing the cathode wire 120, and a length direction of the flat steel is perpendicular to a length direction of the cathode hanging beam 110.

The flat steels are arranged on the cathode hanging beam 110 in parallel and at a certain distance, and a cathode wire 120 is arranged between every two flat steels. The flat steel is provided with a through hole, and the adjusting bolt is arranged in the through hole in a penetrating way and abutted to the cathode wire 120. The adjusting bolt is provided with a nut in a penetrating mode, and the adjusting bolt is screwed up through the nut after penetrating through the through hole, so that the adjusting bolt is fixed on the flat steel. When the cathode wire 120 needs to be moved, the nuts are loosened, and the adjusting bolts on the two sides of the cathode wire 120 are moved, so that the adjusting bolts move relative to the flat steel, and the adjusting bolts on the two sides of the cathode wire 120 need to move towards the same direction, so that the cathode wire 120 clamped between the adjusting bolts also moves along with the adjusting bolts. The first connecting member 130 connected to the cathode wire 120 is also moved along the length direction of the cathode hanging beam 110 by the cathode wire 120, and finally the cathode wire 120 is moved relative to the cathode hanging beam 110. After the cathode lines 120 move, the distance between the cathode lines 120 and the anode plate 150 is also changed, thereby changing the dust removal efficiency of the electric dust remover. As another alternative, a flat steel is disposed on only one side of the cathode wire 120, a through hole is formed in the flat steel, and an adjusting bolt is inserted into the through hole and connected to the cathode wire 120. The end of the adjusting bolt is welded or screwed to the cathode wire 120. The adjusting bolt is provided with a nut in a penetrating mode, and the adjusting bolt is screwed up through the nut after penetrating through the through hole, so that the adjusting bolt is fixed on the flat steel. When the cathode wire 120 needs to be moved, the nut is only required to be unscrewed, and then the adjusting bolt on one side of the cathode wire 120 is moved, so that the adjusting bolt moves relative to the flat steel, and the cathode wire 120 connected with the adjusting bolt also moves along with the adjusting bolt. The first connecting member 130 connected to the cathode wire 120 is also moved along the length direction of the cathode hanging beam 110 by the cathode wire 120, and finally the cathode wire 120 is moved relative to the cathode hanging beam 110. After the cathode lines 120 move, the distance between the cathode lines 120 and the anode plate 150 is also changed, thereby changing the dust removal efficiency of the electric dust remover.

It is understood that the fixing portion 112 may have other structures such as a metal ring fixed on the surface of the cathode suspension beam 110 facing the cathode wire 120, besides the flat steel. And the adjusting bolt penetrates through the metal ring and then the nut is screwed down, so that the adjusting bolt is fixed on the metal ring. Therefore, the specific structure of the fixing portion 112 is not limited herein. The pushing member 140 may be a screw rod or the like, instead of an adjusting bolt, and is not limited herein.

In one embodiment, referring to fig. 1, a wet electric dust collector includes a housing 300 and the cathode frame 100 according to any of the above embodiments, wherein the cathode frame 100 is disposed in the housing 300. Since the wet electric precipitator includes the cathode frame 100 described above, the technical effects are brought by the cathode frame 100, and the beneficial effects already include the beneficial effects of the cathode frame 100, so that no further description is provided herein.

This negative pole frame 100 need not use and prevents the pendulum rod, only needs impeller 140 to drive the removal of negative pole line 120, effectively reduces wet-type electrostatic precipitator's height, also can prevent to produce the creepage phenomenon in the wet-type electrostatic precipitator simultaneously, guarantees electrostatic precipitator's normal operating.

The cathode frame 100 according to the embodiment of the present invention is provided with the first connecting member 130 to connect the cathode line 120 to the cathode suspension beam 110. The cathode line 120 is connected to the first connecting member 130 and the pushing member 140, respectively. When the pushing member 140 is moved, since the first connecting member 130 can move relative to the cathode hanging beam 110, the pushing member 140 drives the cathode wire 120 to further drive the first connecting member 130 to move relative to the cathode hanging beam 110, and finally the cathode wire 120 moves relative to the cathode hanging beam 110, so as to adjust the distance from the cathode wire 120 to the anode plate 150, and change the dust removal efficiency of the electric dust remover. It is also possible to find an optimum distance value by changing the distance from the cathode line 120 to the anode plate 150 several times, thereby obtaining a better dust removal effect. This negative pole frame 100 simple structure need not use and prevents the pendulum rod, is favorable to reducing electrostatic precipitator's height, and reduce cost effectively reduces the production of creepage phenomenon simultaneously, is favorable to improving electrostatic precipitator's life.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A cathode frame, comprising:

a cathode suspension beam;

2. The cathode frame according to claim 1, wherein the cathode suspension beam is provided with a first mounting hole along a length direction thereof, one end of the first connecting member is inserted into the first mounting hole, and the first connecting member is movable in the first mounting hole along the length direction of the cathode suspension beam.

3. The cathode frame according to claim 1, further comprising a second connecting member fixed to the cathode suspension beam, wherein the second connecting member has a second mounting hole, one end of the first connecting member is inserted into the second mounting hole, and the first connecting member is movable in the second mounting hole along a length direction of the cathode suspension beam.

4. The cathode frame according to claim 3, wherein the second connecting member is an angle steel connecting member, one end of the angle steel connecting member is connected to the cathode hanging beam, the other end of the angle steel connecting member is provided with the second mounting hole, and the second mounting hole is a kidney-shaped hole arranged along the length direction of the cathode hanging beam.

5. The cathode frame of claim 1, wherein the first connecting member comprises a pin shaft seat and a pin shaft inserted into the pin shaft seat, the pin shaft seat is movably connected to the cathode hanging beam, the pin shaft is arranged in the pin shaft seat, and an end of the pin shaft extends out of the pin shaft seat and is connected to the cathode wire.

6. The cathode frame according to any one of claims 1 to 5, wherein the pushers are provided in one-to-one correspondence with the cathode strands, the pushers being connected to the cathode strands and, when moved, driving the cathode strands.

7. The cathode frame according to any one of claims 1 to 5, wherein two side surfaces of the cathode line respectively abut against at least one of the pushing members, the pushing members abut against the side surfaces of the cathode line, and the pushing members drive the cathode line to move when the pushing members on the two side surfaces of the cathode line move in the same direction for an equal distance.

8. The cathode frame according to claim 7, wherein the surface of the cathode hanger beam facing the cathode wire is provided with a fixing portion to which the pushing member is movably connected.

9. The cathode frame according to claim 8, wherein the fixing portion is a flat steel, and the urging member is an adjusting bolt.

10. A wet electrostatic precipitator including a housing and a cathode frame as claimed in any one of claims 1 to 9, the cathode frame being disposed within the housing.