CN220657897U - Reinforcing structure of anode plate of electric dust collector - Google Patents

Abstract

Aiming at the defect that the anode plates in the prior art are easy to swing, the utility model provides an anode plate reinforcing structure of an electric dust collector, which belongs to the technical field of electric dust collectors and comprises a limiting mechanism for installing a plurality of anode plates, wherein one side of each anode plate is provided with a reinforcing rod penetrating through the anode plates, the reinforcing rods are transversely arranged, and the anode plates are provided with a plurality of reinforcing rods from top to bottom; the reinforcing rod body is contacted with the anode plate. According to the utility model, the anode plate is fixed at two ends through the limiting mechanism, so that the whole anode plate cannot move, the reinforcing rods are arranged on the anode plate body at a plurality of reinforcing places, and the anode plate body is reinforced through the reinforcing rods, so that the problem that the anode plate body is easy to be deformed by gas blowing is avoided.

Description

Reinforcing structure of anode plate of electric dust collector

Technical Field

The utility model belongs to the technical field of electric dust collectors, and particularly relates to an anode plate reinforcing structure of an electric dust collector.

Background

The basic working principle of the electric dust collector is as follows: a high voltage direct current is applied to the cathode wire of the electric precipitator, and an electrostatic field sufficient to separate the gas is maintained between the cathode wire and the anode plate. In the process of ionization of the dust-containing gas by a high-voltage electric field, the dust particles are charged, and under the action of the electric field force, the charged dust particles move towards the anode plate and are deposited on the anode plate, so that the dust particles are separated from the dust-containing gas, and then the vibration shaft is driven to rotate by the speed reducer, and the vibration hammer strikes the anode plate to enable the dust to fall into a collecting hopper at the lower part of the dust remover. The anode plate is generally thin and long, and is easy to swing or deform due to the impact of air flow in the electric dust collector, so that the distance between the anode plate and the cathode line is changed, and the dust collection effect of the electric dust collector is affected.

Disclosure of Invention

Aiming at the defect that an anode plate in the prior art is easy to swing, the utility model provides an anode plate reinforcing structure of an electric dust remover.

The utility model aims at realizing the following technical scheme: the utility model provides an electrostatic precipitator anode plate reinforced structure, includes the stop gear of installation polylith anode plate, is equipped with the stiffener that passes polylith anode plate at one side of anode plate, and this stiffener transversely sets up, and anode plate from the top down is provided with many stiffeners; the reinforcing rod body is contacted with the anode plate.

In the scheme, the anode plates are fixed at the two ends of the anode plate through the limiting mechanisms, so that the whole anode plate cannot move, the reinforcing rods are arranged on the anode plate body to reinforce the anode plate body, and the anode plate body is reinforced through the reinforcing rods, so that the problem that the anode plate body is easily deformed by gas blowing is avoided.

Preferably, the limiting mechanism comprises a limiting clamping seat positioned at the upper end of the anode plate and a limiting clamping seat positioned at the lower end of the anode plate.

Preferably, the limiting clamping seat comprises a base, a first groove for inserting the anode plate is formed in the base, and a shock pad is arranged between the anode plate and the first groove.

Preferably, a plurality of threaded holes are further formed in the side wall of the base, and the ejector rod bolts are tightly propped against the shock pad through the threaded holes. The two ends of the anode plate are fixed on the base through the ejector rod bolts, and the anode plate cannot move.

Preferably, the anode plate comprises an anode plate body, two ends of the anode plate body are respectively provided with a groove type folded edge, the groove type folded edge is formed by bending a first folded edge again at one end of the anode plate body to form a second folded edge, and the second folded edge is bent again to form a third folded edge to form a groove type overall.

Preferably, the second flanging is vertically provided with a plurality of through holes, and the reinforcing rods penetrate through and connect a plurality of anode plates which are arranged together in parallel.

Preferably, the anode plate body is provided with a second groove on the side surface of the reinforcing rod, and the shape of the second groove is the same as the shape of the reinforcing rod contacting the anode plate body.

Preferably, a plurality of isolation blocks are arranged between anode plates arranged in the same limiting mechanism, and the isolation blocks are respectively and fixedly connected with two adjacent anode plates.

Preferably, the isolation block comprises an isolation block body and mounting wings, wherein the mounting wings are positioned on two sides of the isolation block and are fixedly connected with the second flanging.

Compared with the prior art, the utility model has the following beneficial effects:

the anode plate is fixed through stop gear in both ends, makes the whole anode plate can not take place to remove, and the reinforcing rod's that has set up makes on the anode plate body more strengthen the place, consolidates the plate body of anode plate through the reinforcing rod to avoided the plate body of anode plate to be by the problem of gas blowing deformation easily.

Drawings

FIG. 1 is a block diagram of the present utility model;

FIG. 2 is an enlarged view of FIG. 1 at A;

FIG. 3 is a block diagram of the other side of the anode plate;

figure 4 is a top view of an anode plate;

fig. 5 is a structural diagram of the spacer block.

The marks in the figure: 1. an anode plate; 11. an anode plate body; 12. a first bending edge; 13. a second crimping edge; 14. a third crimp; 2. a base; 3. a first groove; 4. a shock pad; 5. a reinforcing rod; 6. a nut; 7. a spacer block; 71. a spacer body; 72. mounting the wing; 8. and a second groove.

Detailed Description

The utility model is further described below with reference to embodiments shown in the drawings in which:

as shown in fig. 1 to 5, an anode plate reinforcing structure of an electric precipitator comprises a limiting mechanism for installing a plurality of anode plates 1, wherein the limiting mechanism comprises a limiting clamping seat positioned at the upper end of the anode plates 1 and a limiting clamping seat positioned at the lower end of the anode plates. The limiting clamping seat comprises a base 2, a first groove 3 for inserting the anode plate 1 is formed in the base 2, and a shock pad 4 is arranged between the anode plate 1 and the first groove 3. The anode plate 1 is installed in the limit clamping seat in a sliding way from one side of the limit clamping seat. The side wall of the base 2 is also provided with a plurality of threaded holes, and the ejector rod bolts are tightly propped against the shock pad 4 through the threaded holes. The two ends of the anode plate 1 are fixed on the base 2 through the ejector rod bolts, and cannot move.

In this embodiment, the installation of two anode plates 1 is taken as an example, and the number of anode plates 1 in the actual use process can be increased according to the actual situation.

The anode plate 1 comprises an anode plate body 11, two ends of the anode plate body 11 are respectively provided with a groove type folded edge, the groove type folded edge is formed by arranging a first folded edge 12 at one end of the anode plate body 11, the end of the first folded edge 12 is folded again to form a second folded edge 13, and the end of the second folded edge 13 is folded again to form a third folded edge 14 to form a groove type overall. The second flanging 13 is vertically provided with a plurality of through holes, and the reinforcing rod 5 penetrates through and is connected with a plurality of anode plates which are arranged in parallel. On the anode plates at the two ends of the same limiting mechanism, the anode plates 1 are tightly connected together through nuts 6 screwed on the reinforcing rods 5, so that a plurality of anode plates are connected into a whole, and swing is not easy to occur.

The anode plate body 11 is provided with a second groove 8 on the side surface of the reinforcing rod 5, and the shape of the second groove 8 is the same as the shape of the reinforcing rod 5 contacting the anode plate body 11.

A plurality of isolation blocks 7 are arranged between anode plates arranged in the same limiting mechanism, and the isolation blocks 7 are respectively and fixedly connected with two adjacent anode plates. The spacer 7 and the reinforcing bars 5 are arranged at intervals, and the spacer 7 in this embodiment is located between the two reinforcing bars 5. The spacing block 7 not only increases the rigidity strength of the side edge of the anode plate, but also ensures that the spacing distance between the anode plates 1 is fixed, thereby facilitating the installation of the anode plates 1.

The isolation block 7 comprises an isolation block body 71 and mounting wings 72, wherein the mounting wings 72 are positioned on two sides of the isolation block, and the mounting wings 72 are fixedly connected with the second flanging 13. In this embodiment, the anode plate 1 is fixedly mounted by bolts.

The specific embodiments described herein are offered by way of example only to illustrate the spirit of the utility model. Those skilled in the art may make various modifications or additions to the described embodiments or substitutions thereof without departing from the spirit of the utility model or exceeding the scope of the utility model as defined in the accompanying claims.

Claims (9)

1. The utility model provides an electrostatic precipitator anode plate reinforced structure, includes the stop gear who installs polylith anode plate, its characterized in that, be equipped with on one side of anode plate (1) and pass stiffener (5) of polylith anode plate (1), this stiffener (5) transversely set up, and anode plate (1) from the top down is provided with many stiffeners (5); the pole body of the reinforcing pole (5) is contacted with the anode plate.

2. The anode plate reinforcing structure of the electric precipitator according to claim 1, wherein the limiting mechanism comprises a limiting clamping seat positioned at the upper end of the anode plate (1) and a limiting clamping seat positioned at the lower end of the anode plate (1).

3. The anode plate reinforcing structure of the electric precipitator according to claim 2, wherein the limiting clamping seat comprises a base (2), a first groove (3) for inserting the anode plate (1) is arranged on the base (2), and a shock pad (4) is arranged between the anode plate (1) and the first groove (3).

4. A reinforcing structure for an anode plate of an electric dust collector according to claim 3, wherein a plurality of threaded holes are further formed in the side wall of the base (2), and ejector rod bolts are tightly abutted to the shock pad (4) through the threaded holes.

5. The anode plate reinforcing structure of the electric dust collector according to claim 1, wherein the anode plate (1) comprises an anode plate body (11), two ends of the anode plate body (11) are respectively provided with a groove-shaped folded edge, the groove-shaped folded edge is formed by arranging a first folded edge (12) at one end part of the anode plate body (11), the end part of the first folded edge (12) is folded again to form a second folded edge (13), and the end part of the second folded edge (13) is folded again to form a third folded edge (14) to form a groove.

6. The reinforcing structure of the anode plate of the electric precipitator according to claim 5, wherein the second bent edge (13) is vertically provided with a plurality of through holes, and the reinforcing rod (5) penetrates through the anode plates (1) which are arranged together in parallel.

7. The reinforcing structure of the anode plate of the electric precipitator according to claim 5, wherein a second groove (8) is formed in the anode plate body (11) on the side surface of the reinforcing rod (5), and the shape of the second groove (8) is the same as the shape of the anode plate body (11) contacted by the reinforcing rod (5).

8. The reinforcing structure of the anode plate of the electric precipitator according to claim 1, wherein a plurality of isolation blocks (7) are arranged between the anode plates (1) arranged in the same limiting mechanism, and the isolation blocks (7) are fixedly connected with two adjacent anode plates (1) respectively.

9. The anode plate reinforcing structure of the electric precipitator according to claim 8, wherein the isolating block (7) comprises an isolating block body (71) and mounting wings (72), the mounting wings (72) are positioned on two sides of the isolating block, and the mounting wings (72) are fixedly connected with the second bending edges (13).