CN211358092U - Mould and burn board subassembly - Google Patents

Abstract

The utility model discloses a sintered plate component, which is applied to a sintered plate dust remover and comprises a shell; the filter element assembly comprises plastic burning plate filter elements arranged in the shell in an array manner; a vibrating support disposed between the filter element assembly and the housing; the nozzle of the air injection device is positioned above the plastic burning plate filter elements and corresponds to the upper end opening of each plastic burning plate filter element; the vibrating support comprises an upper support assembly and a lower support assembly, and the filter element assembly is arranged between the upper support assembly and the lower support assembly. The beneficial effects are that: after the filter element assembly filters a period of time to the air, at this moment open air jet system, to the pulse air current that the input has the frequency in the filter element assembly, the filter element assembly then can be rocked about last bracket component produces to the cooperation lower carriage component enables the filter element assembly of different attached impurity volume to produce wavy rocking from top to bottom, improves the work efficiency who moulds and burns the board.

Description

Mould and burn board subassembly

Technical Field

The utility model relates to a mould board subassembly of burning with filter effect especially relates to an adopt to mould dust remover of board subassembly of burning.

Background

The plastic sintered plate dust remover replaces the traditional cloth bag with a unique wave type plastic sintered plate filter core, and the plastic sintered plate is of a rigid structure, cannot deform and has no framework abrasion, so that the plastic sintered plate dust remover is long in service life, and under some working conditions, the service life of the plastic sintered plate dust remover is more than 10 times that of the cloth bag. The surface of the sintered plate is deeply treated, so that the pore diameter is fine and uniform, the sintered plate has hydrophobicity, and dust with high water content is not easy to adhere to the sintered plate, so that the sintered plate dust remover is the best choice when treating high water content and fibrous dust. In addition, because the high-precision process manufacturing of the sintered plate keeps uniform micron-sized aperture, ultrafine dust and high-concentration dust can be processed, the inlet concentration of the bag collector is generally less than 20 g/m < 3 >, and the inlet concentration of the sintered plate dust collector can reach 500 g/m < 3 >. It can simplify secondary dust collection into primary dust collection, not only is the process convenient, but also can reduce cost and energy consumption and reduce floor area and space pipeline.

Chinese utility model patent document with publication number "CN 209123555U" discloses "a burn board dust remover moulds of even cloth wind", the device adopts the ash bucket air inlet, respectively from ash bucket both sides air inlet, the even dust collecting chamber that gets into burn board dust remover of moulding of the even through-hole that distributes on even gas distribution guide plate of broken up, even gas distribution guide plate at 45 degrees inclinations can make the burn board of moulding far-end apart from the air-supply line and the even gas of burn board distribution of near-end, it is big to avoid gas distribution inequality to arouse that it moulds the burn board filtration burden individually, and simultaneously, the efficiency of removing dust is improved. But after the board adsorbs the dust of moulding fever, because the pulse vibration efficiency among the prior art is not high, the device can't effectually get rid of the dust that adsorbs on the board subassembly of moulding fever to the dust removal effect of device has been influenced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a mould and burn board subassembly can effectively solve and mould and burn board subassembly because the not high influence of pulse vibration frequency moulds board vibration efficiency to the influence is based on the efficiency of the dust remover of moulding the setting of board subassembly.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme: comprises a shell; the filter element assembly comprises plastic burning plate filter elements arranged in the shell in an array manner; a vibrating support disposed between the filter element assembly and the housing; the nozzle of the air injection device is positioned above the plastic burning plate filter elements and corresponds to the upper end opening of each plastic burning plate filter element; wherein the vibration support comprises an upper support component and a lower support component, and the filter element component is arranged between the upper support component and the lower support component; the upper bracket component is horizontally and elastically connected with the filter element component; the lower bracket component is elastically connected with the filter element component in the longitudinal direction; the lower extreme of casing is equipped with the air inlet that is used for waste gas to get into, the upper end of casing is equipped with the gas outlet that is used for through filtering gaseous outflow. When the sintering plate filters air, the air firstly enters the shell from the air inlet and then passes through the filter element assembly, then air particles pass through micropores in the filter element assembly, and impurity particles in the air are left on the surface of the filter element assembly, so that the air is filtered; after the filter element assembly filters air for a period of time, a large amount of impurity dust particles can be accumulated on the surface of the filter element assembly, and due to the reason of air flowing, the amount of impurities attached to the surface of each filter element assembly is different, at the moment, the air injection device is opened, pulse airflow with frequency is input into the filter element assembly, the filter element assembly can shake left and right in the upper support assembly, and the filter element assembly with different amounts of attached impurities can shake up and down in a wave shape by matching with the lower support assembly, so that the pulse efficiency of the filter element assembly is improved, and the working efficiency of the plastic sintered plate dust remover is improved.

Furthermore, a plurality of mounting bars which are uniformly arranged are clamped on the vibrating plate, vent grooves which penetrate through the mounting bars from top to bottom are formed in the mounting bars, and a plastic burning plate filter element is fixed between the mounting bars. Utilize the mounting bar is right mould and burn board filter core and fix, and set up the air channel in the mounting bar and can with the high-pressure pulse air current that air jet system produced blows in mould and burn in the middle of the board filter core, make mould and burn the board filter core and give pulse vibration transmission for the vibration support.

Further, the upper bracket component comprises the vibrating plate and a positioning plate which slides with the vibrating plate; the filter element assembly can be arranged in the vibrating plate in a vertically sliding mode. When the plastic burning plate filter element is subjected to pulse vibration, the mounting bar positioned at the upper end of the plastic burning plate filter element and the vibrating plate can slide up and down.

Furthermore, a groove is formed in the vibrating plate, an elastic piece is further arranged in the groove, one end of the elastic piece is fixed to the inner side of the positioning plate, and the other end of the elastic piece is fixed to the outer side of the vibrating plate. The vibration plate can transmit the pulse vibration received by the plastic burning plate filter element to the elastic element, so that the plastic burning plate filter element can elastically move in the horizontal direction, and the vibration efficiency of the plastic burning plate filter element is greatly improved along with the contraction and release of the pulse frequency according to the elastic potential energy of the elastic element.

Furthermore, the lower bracket component comprises a plurality of elastic strips which are arranged at the lower end of the filter element component, fixed on the inner wall of the shell and arranged at equal intervals. Utilize the elasticity strip can be so that filter element group spare is in receive pulse vibration time, produce fore-and-aft elasticity, the cooperation upper bracket subassembly improves filter element group spare deashing efficiency.

Furthermore, the inner side of the vibrating plate is provided with a filtering plate, and slots which correspond to the mounting bars up and down and can allow the sintered plate filter element to pass through are formed in the filtering plate. After the plastic sintered plate filter element is used for removing dust from air, the air can enter the filter plate, and the filter plate is used for carrying out secondary adsorption filtration treatment on tiny impurities in the air; when the air injection device outputs pulse air pressure to make the vibrating plate vibrate, the filtering plate can vibrate along with the vibrating plate, and impurities attached to the filtering plate are removed.

Furthermore, the air injection device comprises an air tank arranged on the outer side of the shell, a vent pipe communicated with the air tank, a pulse valve arranged at the joint of the vent pipe and the air tank, and a nozzle arranged at the lower end of the vent pipe and corresponding to the air inlet. In the process of spraying air by the air spraying device, the pulse valve is firstly opened, high-pressure air in the air tank enters the breather pipe at a pulse frequency, and then the high-pressure air is sprayed out from the nozzle to perform pulse vibration on the sintering plate filter element.

Furthermore, the upper end and the lower end of the shell are respectively provided with a conical body communicated with the air inlet, and the interior of the conical body is hollow; the conical body positioned at the upper end of the shell is communicated with the air outlet, one side of the conical body positioned at the lower end of the shell is communicated with the air inlet, and the lower end of the conical body is communicated with the waste pipe. The conical body guides air and impurity dust by utilizing the inclined surface, so that the efficiency of air input and output and impurity dust output is improved conveniently.

Compared with the prior art, the utility model has the advantages that:

after the plastic burning plate assembly filters air for a period of time, a large amount of impurity dust particles can be accumulated on the surface of the plastic burning plate assembly, and due to the reason that air flows, the amount of impurities attached to the surface of each plastic burning plate filter element is also different, at the moment, the air injection device is opened, pulse airflow with frequency is input into the plastic burning plate filter element, the plastic burning plate assembly can swing left and right on the upper support assembly, and the plastic burning plate filter elements with different amounts of attached impurities can swing up and down in a wavy mode by matching with the lower support assembly, the pulse efficiency of the plastic burning plate assembly is improved, and the working efficiency of the plastic burning plate dust remover is improved.

Drawings

FIG. 1 is a three-dimensional structure of the present invention;

FIG. 2 is a cross-sectional view of the present invention

Fig. 3 is a part view of an upper bracket assembly of the present invention;

fig. 4 is a cross-sectional view of the upper bracket assembly of the present invention;

FIG. 5 is a part view of a vibrating plate according to the present invention;

FIG. 6 is a part view of the positioning plate of the present invention;

FIG. 7 is a diagram of the installation position of the plastic sintered plate filter element of the present invention;

FIG. 8 is a diagram of the position relationship of the filter plate according to the present invention;

fig. 9 is a part diagram of the plastic sintered plate filter element of the present invention.

Description of reference numerals:

1. a housing; 2. a conical body; 3. an air inlet; 4. an air outlet; 5. a waste pipe; 6. positioning a plate; 7. a vibrating plate; 701. a groove; 8. an elastic member; 9. a filter plate; 10. an elastic strip; 11. a filter element assembly; 1101. sintering the plate filter element; 1102. mounting a bar; 1103. a vent channel; 12. a gas tank; 13. a pulse valve; 14. a breather pipe; 15. a nozzle; 16. a vibration bracket; 17. an air injection device; 18. an upper bracket assembly; 19. a lower bracket assembly.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally formed; may be mechanically coupled, may be electrically coupled or may be in communication with each other; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

Referring to fig. 1-5, an embodiment of the plastic sintered plate assembly of the present invention includes a housing 1; a filter cartridge assembly 11, the filter cartridge assembly 11 comprising a matrix of sintered plate filter cartridges 1101 disposed within the housing 1; a vibration bracket 16, the vibration bracket 16 is arranged between the filter element assembly 11 and the shell 1; an air injection device 17, wherein a nozzle 15 of the air injection device 17 is positioned above the plastic burning plate filter cores 1101 and corresponds to an upper end opening of each plastic burning plate filter core 1101; wherein the vibration support 16 comprises an upper support assembly 18 and a lower support assembly 19, and the filter element assembly 11 is arranged between the upper support assembly 18 and the lower support assembly 19; the upper bracket component 18 is horizontally and elastically connected with the filter element component 11; the lower bracket component 19 is elastically connected with the filter element component 11 in the longitudinal direction; the lower end of the shell 1 is provided with an air inlet 3 for waste gas to enter, and the upper end of the shell 1 is provided with an air outlet 4 for filtered gas to flow out; when the plastic burning plate dust remover filters air, the air firstly enters the shell 1 from the air inlet 3 and then passes through the filter element assembly 11, then air particles can pass through micropores in the filter element assembly 11, and impurity particles in the air can be left on the surface of the filter element assembly 11 to finish the filtration of the air; after filter element group spare 11 filters a period of time to the air, a large amount of impurity dust particles can be built up on filter element group spare 11 surface, and because the reason that the air flows, so every filter element group spare 11 surface attached impurity volume also is different, at this moment open air jet system 17, to the pulse air current that the input has the frequency in the filter element group spare 11, filter element group spare 11 then can be rocked about last bracket component 18 produces, and cooperation lower bracket component 19 enables different filter element group spares 11 of attached impurity volume to produce wavy rocking from top to bottom, improve filter element group spare 11 pulse efficiency, thereby improve the work efficiency who moulds the board dust remover.

Referring to fig. 6 and 7, an embodiment of the plastic burning board assembly of the present invention includes a housing 1; a filter cartridge assembly 11, the filter cartridge assembly 11 comprising a matrix of sintered plate filter cartridges 1101 disposed within the housing 1; a vibration bracket 16, the vibration bracket 16 is arranged between the filter element assembly 11 and the shell 1; an air injection device 17, wherein a nozzle 15 of the air injection device 17 is positioned above the plastic burning plate filter cores 1101 and corresponds to an upper end opening of each plastic burning plate filter core 1101; wherein the vibration support 16 comprises an upper support assembly 18 and a lower support assembly 19, and the filter element assembly 11 is arranged between the upper support assembly 18 and the lower support assembly 19; the upper bracket component 18 is horizontally and elastically connected with the filter element component 11; the lower bracket component 19 is elastically connected with the filter element component 11 in the longitudinal direction; be equipped with the air inlet 3 that is used for waste gas to get into at the lower extreme of casing 1, the upper end of casing 1 is equipped with the gas outlet 4 that is used for through filtering gaseous outflow, and the last card of vibration board 7 has a plurality of align to grid's mounting bar 1102, is provided with the air channel 1103 that runs through from top to bottom in the mounting bar 1102, is fixed with between the mounting bar 1102 and moulds fever board filter core 1101. When the plastic burning plate dust remover filters air, the air firstly enters the shell 1 from the air inlet 3 and then passes through the filter element assembly 11, then air particles can pass through micropores in the filter element assembly 11, and impurity particles in the air can be left on the surface of the filter element assembly 11 to finish the filtration of the air; after the filter element assembly 11 filters air for a period of time, a large amount of impurity dust particles are accumulated on the surface of the filter element assembly 11, and due to the reason of air flowing, the amount of impurities attached to the surface of each filter element assembly 11 is also different, at this time, the air injection device 17 is opened, pulse airflow with frequency is input into the filter element assembly 11, the filter element assembly 11 can shake left and right on the upper support assembly 18, and the filter element assembly 11 with different amounts of impurities attached can shake up and down in a wave shape by matching with the lower support assembly 19, so that the pulse efficiency of the filter element assembly 11 is improved, and the working efficiency of the plastic sintered plate dust remover is improved; for the filter element assembly 11, the plastic sintered plate filter element 1101 is fixed by using a mounting bar 1102, and the air injection device 17 can be connected by arranging an air vent groove 1103 in the mounting bar 1102; the generated high-pressure pulse airflow is blown into the middle of the plastic sintered plate filter element 1101, so that the plastic sintered plate filter element 1101 is affected by the pulse to generate shaking.

Referring to fig. 4, 5, 6 and 7, an embodiment of the plastic sintered plate assembly of the present invention includes a housing 1; a filter cartridge assembly 11, the filter cartridge assembly 11 comprising a matrix of sintered plate filter cartridges 1101 disposed within the housing 1; a vibration bracket 16, the vibration bracket 16 is arranged between the filter element assembly 11 and the shell 1; an air injection device 17, wherein a nozzle 15 of the air injection device 17 is positioned above the plastic burning plate filter cores 1101 and corresponds to an upper end opening of each plastic burning plate filter core 1101; wherein the vibration support 16 comprises an upper support assembly 18 and a lower support assembly 19, and the filter element assembly 11 is arranged between the upper support assembly 18 and the lower support assembly 19; the upper bracket component 18 is horizontally and elastically connected with the filter element component 11; the lower bracket component 19 is elastically connected with the filter element component 11 in the longitudinal direction; an air inlet 3 for waste gas to enter is arranged at the lower end of the shell 1, an air outlet 4 for filtered gas to flow out is arranged at the upper end of the shell 1, a plurality of uniformly arranged mounting bars 1102 are clamped on the vibrating plate 7, ventilation grooves 1103 which penetrate up and down are arranged in the mounting bars 1102, a plastic burning plate filter element 1101 is fixed between the mounting bars 1102, and the upper support assembly 18 comprises the vibrating plate 7 and a positioning plate 6 which slides with the vibrating plate 7; the filter element assembly 11 is slidably disposed up and down in the vibration plate 7. A groove 701 is formed in the vibrating plate 7, an elastic member 8 is further arranged in the groove 701, one end of the elastic member 8 is fixed to the inner side of the positioning plate 6, and the other end of the elastic member is fixed to the outer side of the vibrating plate 7. The lower bracket component 19 comprises a plurality of elastic strips 10 which are arranged at the lower end of the filter element component 11, fixed on the inner wall of the shell 1 and arranged at equal intervals; in this embodiment, in addition to embodiment 1, for the filter element assembly 11, the plastic sintered plate filter element 1101 is fixed by the mounting bar 1102, and the air injection device 17 can be inserted into the air injection groove 1103 provided in the mounting bar 1102; blowing the generated high-pressure pulse airflow into the middle of the plastic burning plate filter element 1101, so that the plastic burning plate filter element 1101 is affected by the pulse to generate shaking; when the sintering plate filter element 1101 is subjected to pulse vibration, the mounting bar 1102 positioned at the upper end of the sintering plate filter element 1101 and the vibrating plate 7 can slide up and down; the vibrating plate 7 transmits the pulse vibration received by the sintering plate filter element 1101 to the elastic part 8, so that the sintering plate filter element 1101 is elastically moved in the horizontal direction, and the elastic strip 10 can enable the filter element assembly 11 to generate longitudinal elastic force along with the contraction and release of the pulse frequency when receiving the pulse vibration, and the upper support assembly 18 is matched to improve the ash removal efficiency of the filter element assembly 11.

Referring to fig. 9, the utility model discloses an embodiment of the board subassembly that burns is moulded to the mould, vibration board 7 inboard is equipped with a filter 9, is provided with in the filter 9 and corresponds from top to bottom with mounting bar 1102 and can supply to mould the slot 901 that burns board filter core 1101 and pass through.

After the air is dedusted by the sintered plate filter element 1101, the air enters the filter plate 9, and the filter plate 9 is used for carrying out secondary adsorption filtration treatment on tiny impurities in the air; when the air jet device 17 outputs pulse air pressure to vibrate the vibration plate 7, the filter plate 9 is vibrated along with the vibration plate 7, and impurities attached to the filter plate 9 are removed.

The above description is only for the specific embodiment of the present invention, but the technical features of the present invention are not limited thereto, and any person skilled in the art can make changes or modifications within the scope of the present invention.

Claims (10)

1. The utility model provides a burn board subassembly moulds and burns board dust remover for moulding which characterized in that: comprises that

A housing (1);

a filter cartridge assembly (11), the filter cartridge assembly (11) comprising a sintered plate filter cartridge (1101) arranged in an array within the housing (1);

a vibrating support (16), said vibrating support (16) being arranged between said filter element assembly (11) and said housing (1);

an air injection device (17), wherein a nozzle (15) of the air injection device (17) is positioned above the burning plate filter element (1101) and corresponds to an upper end opening of each burning plate filter element (1101);

wherein the vibrating support (16) comprises an upper support assembly (18) and a lower support assembly (19), the filter element assembly (11) being disposed between the upper support assembly (18) and the lower support assembly (19); the upper support component (18) is horizontally and elastically connected with the filter element component (11); the lower bracket component (19) is elastically connected with the filter element component (11) in the longitudinal direction; the lower extreme of casing (1) is equipped with air inlet (3) that are used for waste gas to get into, the upper end of casing (1) is equipped with gas outlet (4) that are used for through filtering gas outflow.

2. The fused plate assembly of claim 1, wherein: the filter element assembly (11) comprises mounting bars (1102), and a sintered plate filter element (1101) fixed between the mounting bars (1102); and a ventilation groove (1103) which penetrates through the installation bar (1102) up and down is formed in the installation bar.

3. The fused plate assembly of claim 2, wherein: the upper support component (18) comprises a vibrating plate (7) and a positioning plate (6) which slides with the vibrating plate (7); the filter element assembly (11) can be arranged in the vibrating plate (7) in a vertically sliding mode.

4. The fused plate assembly of claim 3, wherein: the outer edge of the vibrating plate (7) is provided with a groove (701), an elastic piece (8) is further arranged in the groove (701), one end of the elastic piece (8) is fixed to the inner side of the positioning plate (6), and the other end of the elastic piece is fixed to the outer side of the vibrating plate (7).

5. The fused plate assembly of claim 3, wherein: the inner side of the vibrating plate (7) is provided with a filtering plate (9), and the filtering plate (9) is internally provided with a slot (901) which corresponds to the mounting bar (1102) up and down and can allow the sintering plate filter element (1101) to pass through.

6. The fused plate assembly of claim 1 or 2, wherein: the lower bracket component (19) comprises a plurality of elastic strips (10) which are arranged at the lower end of the filter element component (11), fixed on the inner wall of the shell (1) and arranged at equal intervals.

7. The fused plate assembly of claim 1 or 2, wherein: the air injection device (17) comprises an air tank (12) arranged on the outer side of the shell (1), an air pipe (14) communicated with the air tank (12), a pulse valve (13) arranged at the joint of the air pipe (14) and the air tank (12), and a nozzle (15) arranged at the lower end of the air pipe (14) and corresponding to the air inlet (3).

8. The fused plate assembly of claim 3, wherein: the air injection device (17) comprises an air tank (12) arranged on the outer side of the shell (1), an air pipe (14) communicated with the air tank (12), a pulse valve (13) arranged at the joint of the air pipe (14) and the air tank (12), and a nozzle (15) arranged at the lower end of the air pipe (14) and corresponding to the air inlet (3).

9. The fused plate assembly of claim 1, wherein: the upper end and the lower end of the shell (1) are respectively provided with a conical body (2) communicated with the air inlet (3), and the conical body (2) is hollow; the conical body (2) positioned at the upper end of the shell (1) is communicated with the air outlet (4), one side of the conical body (2) positioned at the lower end of the shell (1) is communicated with the air inlet (3), and the lower end of the conical body is communicated with the waste pipe (5).

10. The fused plate assembly of claim 6, wherein: the upper end and the lower end of the shell (1) are respectively provided with a conical body (2) communicated with the air inlet (3), and the conical body (2) is hollow; the conical body (2) positioned at the upper end of the shell (1) is communicated with the air outlet (4), one side of the conical body (2) positioned at the lower end of the shell (1) is communicated with the air inlet (3), and the lower end of the conical body is communicated with the waste pipe (5).

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