CN220257283U - High-efficient dust collecting equipment - Google Patents

Abstract

The utility model relates to the field of air purification, and discloses high-efficiency dust removing equipment which comprises a filter tank and a water collecting bucket which is arranged below an anode plate and is used for receiving water, wherein a tank cover is arranged at an upper tank opening of the filter tank, a water inlet hole is formed in the end face of the tank cover, a connector extends upwards from an upper orifice of the water inlet hole, a filter plate is arranged in the filter tank, a sweeping rod and a transmission assembly are further arranged on the upper end face of the filter plate, the transmission assembly is used for driving the sweeping rod to rotate by utilizing kinetic energy generated by water flow impact as a driving source, the sweeping rod rotates to sweep the upper end face of the filter plate, the filter plate is cleaned by the sweeping rod, the blocking of the filter hole of the filter plate is prevented by the aid of water flow impact as a driving source, the filter tank is energy-saving, the two groups of filter tanks can be cleaned alternately, the filtering process of water does not need to be suspended, and the air purification process does not need to be suspended.

Description

High-efficient dust collecting equipment

Technical Field

The utility model relates to the field of air purification, in particular to efficient dust removal equipment.

Background

The wet-type electrostatic precipitator is a common air purification device, it utilizes the electrostatic precipitator principle to purify air, compare with other kind of air purification device, wet-type electrostatic precipitator's anode plate surface is formed with the water film of one deck from top to bottom, the water film can wash the air pollution thing of attaching on the anode plate, the inner wall to the anode plate washs, so purifying effect is preferred, wherein, the water film is generally through the clean water of water pump extraction, spray towards the anode plate inner wall through devices such as spray pipe, and in order to avoid the water wasting, generally can collect the water after washing, carry out reuse after filtering, and among the prior art, most commonly utilize the filter screen to filter the air pollution thing of the inside of water, there is some not enough: after long-time use, air pollutants very easily block the filtering holes of the filter screen to influence water flow, so that air purification needs to be suspended at intervals, the filter device is disassembled and cleaned, the air purification process is delayed, and the disassembly and the cleaning are complex, tedious and inconvenient.

Disclosure of Invention

In order to solve the problems mentioned in the background above, the present utility model provides a high-efficiency dust removing apparatus.

In order to achieve the technical purpose, the technical scheme adopted by the utility model is as follows.

The utility model provides a high-efficient dust collecting equipment, including filtering the jar, set up in the anode plate below and be used for receiving the water catch bowl of water, the last tank opening department of filtering the jar is provided with the cover, the inlet opening has been seted up to the terminal surface of cover, the last drill way of inlet opening extends up has the joint, be provided with the filter plate in the filtering jar, the up end of filter plate still is provided with sweeps pole and transfer assembly, transfer assembly is used for utilizing the kinetic energy that rivers impact produced to order about to sweep the pole and take place rotatoryly for the driving source, sweep the pole and rotate the up end to the filter plate.

Further, a first slot and a second slot are formed in the inner wall of the filter tank, and the first slot and the second slot penetrate through the end face of the upper tank opening of the filter tank;

the outer wall of the filter plate extends to be provided with a bulge, and the installation between the filter plate and the filter tank is realized through the cooperation of the bulge and the first slot.

Further, the upper end face of the filter plate coaxially extends to form a convex column, the lower end face of the sweeping rod is provided with a mounting hole, the sweeping rod is sleeved outside the convex column through the mounting hole, and the lower end face of the sweeping rod is attached to the upper end face of the filter plate.

Further, both ends of the sweeping rod are in the shape of cambered surfaces coaxial with the filter plate and with the same diameter.

Further, the transmission assembly comprises a transmission shaft which is arranged on the upper end face of the sweeping rod and is coaxial with the filter plate, a sealing shell is rotatably arranged at the upper end of the transmission shaft, the upper end of the transmission shaft extends into the sealing shell, a rotating shaft which is horizontally arranged is further arranged on the sealing shell, two ends of the rotating shaft extend out of the sealing shell and are respectively provided with a fan blade, and the rotating shaft and the transmission shaft are in power connection through a power transmission piece;

the outer wall of the sealing shell is extended with a supporting rod, and the free end of the supporting rod extends into the second slot;

the water inlet is positioned above the fan blade and is positioned on one side of the rotating shaft, and two water inlets are correspondingly arranged on the same side of the rotating shaft.

Further, connect and correspond to be provided with two and two connect between realizing the intercommunication through last pipeline, the bottom of filter tank is provided with down the pipeline, and the end and the water pump of lower pipeline are connected.

Further, the lower end face of the tank cover is provided with a first inserting rod inserted into the first inserting groove and a second inserting rod inserted into the second inserting groove, the lower end of the first inserting rod is in contact with the upper end face of the protrusion, and the lower end of the second inserting rod is in contact with the upper end face of the supporting rod.

Further, the filter tank is provided with two groups, and the two groups of upper pipelines are communicated through a third connecting pipe, the third connecting pipe is communicated with the water collecting bucket through a fourth connecting pipe, the third connecting pipe is provided with a first control valve which is respectively positioned at the four sides of the connecting pipe, the two groups of lower pipelines are communicated through a first connecting pipe, the first connecting pipe is communicated with the water pump through a second connecting pipe, and the first connecting pipe is provided with a second control valve which is respectively positioned at the two sides of the second connecting pipe.

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

in the utility model, in the water filtering process, the fan blades are impacted by water flow to rotate, the fan blades rotate together with the rotating shaft, the rotating shaft rotates through the power transmission piece and rotates together with the sweeping rod, the sweeping rod rotates to sweep the filter plate, the filter holes of the filter plate are prevented from being blocked, and the whole sweeping process is realized by utilizing the water flow impact, so that the energy is saved;

furthermore, in the utility model, the two groups of filter tanks are arranged, and when the filter tanks are cleaned or maintained, the two groups of filter tanks can be cleaned alternately, so that the filtration process of water does not need to be suspended, and the air purification process does not need to be suspended.

Drawings

FIG. 1 is a schematic diagram of the prior art;

FIG. 2 is a schematic diagram of the structure of the present utility model;

FIG. 3 is an exploded view of the present utility model;

FIG. 4 is a schematic view of a can lid;

FIG. 5 is a schematic illustration of a filter plate and transfer assembly;

fig. 6 is a second schematic view of a filter plate and transfer assembly.

The reference numerals in the drawings are:

1. a filter tank; 101. a first slot; 102. a second slot; 2. a can lid; 201. a joint; 202. the first inserting rod is arranged; 203. the second inserting rod is arranged; 3. a filter plate; 301. a protrusion; 302. a convex column; 4. a sweep bar; 5. a transmission shaft; 6. a sealed housing; 7. a support rod; 8. a rotating shaft; 9. a fan blade; 10. a lower pipeline; 11. an upper pipeline; 12. a first connecting pipe; 13. a second connecting pipe; 14. a third connecting pipe; 15. and a connecting pipe IV.

Detailed Description

In order to further describe the technical means and effects adopted by the present utility model for achieving the intended purpose, the following detailed description will refer to the specific implementation, structure, characteristics and effects according to the present utility model with reference to the accompanying drawings and preferred embodiments.

As shown in fig. 1, in the prior art, a wet electric precipitator generally uses a water pump d to pump water and guide the water into a water tank through a water pipe c, the water tank surrounds the top edge of each anode conductive cylinder a, the water is full of water which is overflowed from the water tank and flows into the inner wall of the anode conductive cylinder a, so that the inner wall of the anode conductive cylinder a is provided with a layer of water film, b represents a cathode corona wire, in order to avoid water resource waste, the water left from the inner wall of the anode conductive cylinder a is filtered and reused by a filtering device generally.

Example 1

As shown in fig. 2 to 6, a high efficiency dust removing apparatus includes a filter tank 1, a water collecting bucket disposed under an anode plate and for receiving water.

The upper tank opening of the filter tank 1 is provided with a tank cover 2, the end surface of the tank cover 2 is provided with a water inlet, and the upper orifice of the water inlet extends upwards to form a joint 201.

A filter plate 3 is arranged in the filter tank 1.

Specific:

as shown in fig. 3, the inner wall of the filter tank 1 is provided with a first slot 101 and a second slot 102, both of which penetrate to the upper tank opening end face of the filter tank 1.

As shown in fig. 5, the outer wall of the filter plate 3 is extended with a protrusion 301, and the filter plate 3 and the filter tank 1 are mounted by the protrusion 301 and the first slot 101.

Further, as shown in fig. 5 and 6, the upper end surface of the filter plate 3 is further provided with a sweeping rod 4 and a transmission assembly, the transmission assembly is used for driving the sweeping rod 4 to rotate by using kinetic energy generated by water flow impact as a driving source, and the sweeping rod 4 cleans the upper end surface of the filter plate 3 in the rotating process, that is, the sweeping rod 4 continuously cleans the filter plate 3 in the water filtering process, so that air pollutants in water are difficult to adhere to the filter plate 3, and the cleaning period of the filter plate 3 is greatly prolonged.

Specific:

as shown in fig. 5 and 6, the upper end surface of the filter plate 3 extends coaxially with the boss 302, the lower end surface of the sweep bar 4 is provided with a mounting hole, the sweep bar 4 is sleeved outside the boss 302 through the mounting hole, the lower end surface of the sweep bar 4 is attached to the upper end surface of the filter plate 3, preferably, both ends of the sweep bar 4 are arc surfaces with the same diameter as the filter plate 3 coaxially, which means that the sweeping range of the sweep bar 4 is increased.

As shown in fig. 5 and 6, the transmission assembly includes a transmission shaft 5 disposed on an upper end surface of the sweeping rod 4 and coaxial with the filter plate 3, a sealing shell 6 is rotatably disposed at an upper end of the transmission shaft 5, an upper end of the transmission shaft 5 extends into the sealing shell 6, a rotating shaft 8 horizontally disposed is further disposed on the sealing shell 6, two ends of the rotating shaft 8 extend out of the sealing shell 6 and are respectively provided with a fan blade 9, and a power connection is formed between the rotating shaft 8 and the transmission shaft 5 through a power transmission member, such as a prior bevel gear technology.

The outer wall of the sealing shell 6 is extended with a supporting rod 7, and the free end of the supporting rod 7 extends into the second slot 102.

The water inlet is positioned above the fan blade 9 and on one side of the rotating shaft 8, and two water inlets are correspondingly arranged on the same side of the rotating shaft 8.

The joints 201 are correspondingly provided with two joints 201, the two joints 201 are communicated through the upper pipeline 11, and the upper pipeline 11 is also communicated with the water collecting bucket.

The bottom of the filter tank 1 is provided with a lower pipeline 10, and the tail end of the lower pipeline 10 is connected with a water pump.

The working process of the first embodiment is specifically:

the water which is washed from the anode plate and falls down flows into the filter tank 1 through the water collecting bucket, the upper pipeline 11, the connector 201 and the water inlet hole in sequence after being collected by the water collecting bucket, and contacts with the fan blades 9, under the impact of water flow, the fan blades 9 rotate together with the rotating shaft 8, the rotating shaft 8 rotates with the transmitting shaft 5 through the power transmission piece, the transmitting shaft 5 rotates with the sweeping rod 4, the sweeping rod 4 rotates to sweep the filter plate 3, and the blocking of the filter holes of the filter plate 3 is prevented;

at the same time, after being filtered by the filter plate 3, the water leaves the lower pipe 10 to the water pump, thus forming a circulating water.

Further, since the filter plate 3 is mounted in the filter tank 1 through the cooperation of the first slot 101 and the protrusion 301, and the seal housing 6 is connected with the filter tank 1 through the cooperation of the support rod 7 and the second slot 102, in the use process, the filter plate 3 and the transmission assembly are easy to shake under the impact of water flow, therefore, as shown in fig. 3 and 4, the lower end surface of the tank cover 2 is provided with the first insert rod 202 inserted into the first slot 101 and the second insert rod 203 inserted into the second slot 102, and the lower end of the first insert rod 202 contacts with the upper end surface of the protrusion 301, and the lower end of the second insert rod 203 contacts with the upper end surface of the support rod 7, so that the filter plate 3 and the support rod 7 are pressed and limited to avoid shaking of the filter plate 3 and the transmission assembly.

Example two

As shown in fig. 2, the filter tank 1 is provided with two groups, and the structure on the filter tank 1 is correspondingly provided with two groups.

The two groups of upper pipelines 11 are communicated through a third connecting pipe 14, the third connecting pipe 14 is communicated with the water collecting bucket through a fourth connecting pipe 15, and a first control valve which is respectively positioned on two sides of the fourth connecting pipe 15 is arranged on the third connecting pipe 14.

The two groups of lower pipelines 10 are communicated through a first connecting pipe 12, the first connecting pipe 12 is communicated with the water pump through a second connecting pipe 13, and a second control valve which is respectively positioned on two sides of the second connecting pipe 13 is arranged on the first connecting pipe 12.

Because the filter tank 1 is provided with two groups, when the filter tank 1 is cleaned regularly (the cleaning period of the filter tank 1 is greatly prolonged in the first embodiment, but the filter tank 1 still needs to be cleaned regularly), the two groups of filter tanks 1 can be cleaned alternately, so that the filtering process of water does not need to be suspended, the air cleaning process does not need to be suspended, and the alternate cleaning of the two groups of filter tanks 1 is realized by the cooperation of the first control valve and the second control valve of the two groups, which is not repeated.

The present utility model is not limited to the above embodiments, but is capable of modification and variation in detail, and other modifications and variations can be made by those skilled in the art without departing from the scope of the present utility model.

Claims (8)

1. The utility model provides a high-efficient dust collecting equipment, includes filtration jar (1), sets up in anode plate below and is used for receiving the water catch bowl of water, its characterized in that: the upper tank mouth department of filtering jar (1) is provided with cover (2), and the inlet opening has been seted up to the terminal surface of cover (2), and upward extension of the last drill way of inlet opening has joint (201), is provided with filter plate (3) in filtering jar (1), and the up end of filter plate (3) still is provided with sweeps pole (4) and transfer module, and transfer module is used for utilizing the kinetic energy that rivers impact produced to order about sweeping pole (4) to take place rotatoryly for the actuating source, sweeps pole (4) rotatory up end to filter plate (3).

2. A high efficiency dust removing apparatus as set forth in claim 1, wherein: the inner wall of the filter tank (1) is provided with a first slot (101) and a second slot (102), and the first slot (101) and the second slot (102) penetrate through the end face of the upper tank opening of the filter tank (1);

the outer wall of the filter plate (3) is extended with a bulge (301), and the filter plate (3) and the filter tank (1) are installed through the cooperation of the bulge (301) and the first slot (101).

3. A high efficiency dust removing apparatus according to claim 1 or 2, characterized in that: the upper end face of the filter plate (3) is coaxially extended with a convex column (302), the lower end face of the sweeping rod (4) is provided with a mounting hole, the sweeping rod (4) is sleeved outside the convex column (302) through the mounting hole, and the lower end face of the sweeping rod (4) is attached to the upper end face of the filter plate (3).

4. A high efficiency dust removing apparatus according to claim 3, wherein: both ends of the sweeping rod (4) are in an arc surface shape coaxial with the filter plate (3) and with equal diameter.

5. A high efficiency dust removing apparatus according to claim 3, wherein: the transmission assembly comprises a transmission shaft (5) which is arranged on the upper end face of the sweeping rod (4) and is coaxial with the filter plate (3), a sealing shell (6) is rotatably arranged at the upper end of the transmission shaft (5), the upper end of the transmission shaft (5) stretches into the sealing shell (6), a rotating shaft (8) which is horizontally arranged is further arranged on the sealing shell (6), two ends of the rotating shaft (8) stretch out of the sealing shell (6) and are respectively provided with a fan blade (9), and the rotating shaft (8) and the transmission shaft (5) form power connection through a power transmission piece;

the outer wall of the sealing shell (6) is extended with a supporting rod (7), and the free end of the supporting rod (7) extends into the second slot (102);

the water inlet is positioned above the fan blades (9) and is positioned on one side of the rotating shaft (8), and two water inlets are correspondingly arranged on the same side of the rotating shaft (8).

6. The high efficiency dust removing apparatus according to claim 5, wherein: the two connectors (201) are correspondingly arranged, the two connectors (201) are communicated through the upper pipeline (11), the bottom of the filter tank (1) is provided with the lower pipeline (10), and the tail end of the lower pipeline (10) is connected with the water pump.

7. The high efficiency dust removing apparatus according to claim 5, wherein: the lower end face of the tank cover (2) is provided with a first inserting rod (202) inserted into the first inserting groove (101) and a second inserting rod (203) inserted into the second inserting groove (102), the lower end of the first inserting rod (202) is in contact with the upper end face of the protrusion (301), and the lower end of the second inserting rod (203) is in contact with the upper end face of the supporting rod (7).

8. The high efficiency dust removing apparatus of claim 6, wherein: the filtering tank (1) is provided with two groups, the two groups of upper pipelines (11) are communicated through a third connecting pipe (14), the third connecting pipe (14) is communicated with the water collecting bucket through a fourth connecting pipe (15), the third connecting pipe (14) is provided with a first control valve which is respectively positioned at two sides of the fourth connecting pipe (15), the two groups of lower pipelines (10) are communicated through a first connecting pipe (12), the first connecting pipe (12) is communicated with the water pump through a second connecting pipe (13), and the first connecting pipe (12) is provided with a second control valve which is respectively positioned at two sides of the second connecting pipe (13).