CN215137318U

CN215137318U - Filter equipment of epoxy coating

Info

Publication number: CN215137318U
Application number: CN202121306130.XU
Authority: CN
Inventors: 孙志勇; 田海长; 胡海涛; 田茂
Original assignee: Anhui Hengguang New Material Technology Co ltd
Current assignee: Anhui Hengguang New Material Technology Co ltd
Priority date: 2021-06-11
Filing date: 2021-06-11
Publication date: 2021-12-14
Anticipated expiration: 2031-06-11

Abstract

The utility model relates to an epoxy coating production facility technical field specifically is an epoxy coating's filter equipment, including filtering box, vice branch, main tributary pole, uide bushing and screw rod. The filtering box body is used for filtering impurities in the epoxy resin coating. The auxiliary supporting rod is positioned below the filtering box body in the vertical direction, and the top end of the auxiliary supporting rod is connected with the filtering box body. The top end of the main supporting rod is connected with the bottom of the auxiliary supporting rod in a sliding mode. The guide sleeve is arranged on the main supporting rod. The middle part of the screw rod is in threaded connection with the guide sleeve and moves along the guide sleeve when rotating relative to the guide sleeve. The first end of screw rod is connected with vice branch rotation, and is used for driving vice branch and removes. The device can adjust the angle of filtering box slope according to the characteristic of epoxy coating to can filter the epoxy coating of various characteristics, operating personnel easy operation, labour saving and time saving. In addition, the device can also clear away the granule impurity after filtering, and labour saving and time saving improves production efficiency.

Description

Filter equipment of epoxy coating

Technical Field

The utility model relates to an epoxy coating production facility technical field specifically is an epoxy coating's filter equipment.

Background

The epoxy resin coating is mainly used as an adhesive or a coating and is widely applied to the fields of water conservancy, traffic, machinery, electronics, household appliances, automobiles, aviation and the like. When the epoxy resin coating is used, the epoxy resin coating is coated on the surface of an object in a spraying, rolling or flow coating mode, and the epoxy resin coating is completely attached to the surface of the object through curing.

Under different application conditions, the requirements on the flowability and the viscosity of the epoxy resin coating are different. For example, the floor of a pharmaceutical workshop requires the use of an epoxy resin coating of the mildewproof and antibacterial type; the ground of an electronic instrument production workshop needs to use an antistatic epoxy resin coating; parking lots require the use of abrasion-resistant epoxy coatings, and the like. Before production, coating production enterprises need to produce epoxy resin coatings with different components and proportions according to different construction modes or different coating performance requirements.

During the manufacturing process, epoxy coatings are often contaminated with large particulates or other solid impurities that can affect the film forming and adhesion properties of the coating. If solid impurities are included in the epoxy resin coating, the coating film has defects or falls off in a large area. Therefore, in the production of epoxy resin coatings, the removal of impurities is of particular importance. At present, a filtering device is generally used to remove impurities in the epoxy resin coating.

In actual production, the epoxy resin coating is poured onto the inclined filter plate, and the purpose of filtering impurities is achieved through the self-flowability of the epoxy resin coating. However, in the filtering device in the prior art, the inclination angle is fixed and unadjustable, and the filtering device is only suitable for epoxy resin paint with strong fluidity and low viscosity; for epoxy resin coating with weak fluidity and high viscosity, the conventional filtering device is difficult to apply due to poor filtering effect, so that production enterprises purchase various filtering devices, the production cost is increased, and the production efficiency is reduced.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a filter equipment of epoxy coating aims at solving among the prior art and needs to use different filter equipment to the epoxy coating of different performance's problem.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes:

a filter assembly for epoxy coating, comprising:

the filtering box body is used for filtering impurities in the epoxy resin coating; the filter box body comprises an upper shell, a filter plate and a lower shell; in the vertical direction, the upper shell is positioned above the lower shell; the filter plate is positioned between the upper shell and the lower shell and is used for keeping impurities in the upper shell and enabling the filtered epoxy resin coating to flow into the lower shell when the epoxy resin coating flows through the filter plate;

the auxiliary supporting rod is positioned below the filtering box body in the vertical direction, and the top end of the auxiliary supporting rod is connected with the filtering box body and used for driving the filtering box body to move along the vertical direction;

the top end of the main supporting rod is connected with the bottom of the auxiliary supporting rod in a sliding manner;

the guide sleeve is arranged on the main supporting rod;

the middle part of the screw is in threaded connection with the guide sleeve and moves along the guide sleeve when rotating relative to the guide sleeve; the first end of the screw rod is rotatably connected with the auxiliary supporting rod and is used for driving the auxiliary supporting rod to move.

As another embodiment of the present application, a filter device for epoxy resin paint further includes:

the support is arranged on one side of the filtering box body and is connected with the filtering box body; and

the rotating shaft is arranged on the support; the first end of the rotating shaft is connected with the support, and the second end of the rotating shaft is rotatably connected with the auxiliary supporting rod.

As another embodiment of the application, the support is provided with a positioning groove, and the auxiliary support rod is provided with a positioning block in sliding fit with the positioning groove.

and the driving unit is connected with the screw rod and used for driving the screw rod to rotate.

the limiting hole is arranged on the main supporting rod; and

and the limiting pin penetrates through the limiting hole, is in abutting contact with the auxiliary supporting rod and is used for positioning the auxiliary supporting rod on the main supporting rod.

the residue opening is arranged in the filtering box body and is communicated with the cavity of the filtering box body;

the push plate is arranged in the filter box body, is connected with the filter plate of the filter box body and is used for pushing impurities remained on the filter plate to a residue port; and

the power mechanism is arranged in the filtering box body and is in sliding connection with the filtering box body; the power mechanism is connected with the push plate and used for driving the push plate to move.

As another embodiment of the present application, the power mechanism includes:

the nut is connected with the filtering box body in a sliding way, is connected with the push plate and is used for driving the push plate to move;

the screw rod is rotationally connected with the filtering box body, is in threaded connection with the nut and is used for driving the nut to move; and

and the power assembly is connected with the lead screw and is used for driving the lead screw to rotate.

As another embodiment of the present application, the power assembly includes:

the driven wheel is connected with the lead screw and is used for driving the lead screw to rotate;

the driving wheel is connected with the driven wheel and is used for driving the driven wheel to rotate;

the power shaft is connected with the driving wheel and is used for driving the driving wheel to rotate; and

and the power motor is connected with the power shaft and is used for driving the power shaft to rotate.

As another embodiment of the application, the number of the nuts is two, and the two nuts are respectively located on two sides of the push plate;

the number of the screw rods is two, and the screw rods correspond to the nuts one to one;

the number of the driven wheels is two, and the driven wheels correspond to the screw rods one by one;

the number of the driving wheels is two, and the driving wheels correspond to the driven wheels one by one; the two driving wheels are respectively connected with the power shaft.

and the flexible element is arranged at the bottom end of the push plate, the first end of the flexible element is connected with the push plate, and the second end of the flexible element is connected with the filter plate in a sliding manner.

Due to the adoption of the technical scheme, the utility model discloses the technological progress who gains is: the filtering box body is used for filtering impurities in the epoxy resin coating. The filter box body comprises an upper shell, a filter plate and a lower shell. The upper housing is located above the lower housing in a vertical direction. The filter is located between the upper shell and the lower shell and is used for keeping impurities in the upper shell and enabling the filtered epoxy resin coating to flow into the lower shell when the epoxy resin coating flows through the filter. The auxiliary supporting rod is located below the filtering box body in the vertical direction, and the top end of the auxiliary supporting rod is connected with the filtering box body and used for driving the filtering box body to move in the vertical direction. The top end of the main supporting rod is connected with the bottom of the auxiliary supporting rod in a sliding mode. The guide sleeve is arranged on the main supporting rod. The middle part of the screw rod is in threaded connection with the guide sleeve and moves along the guide sleeve when rotating relative to the guide sleeve. The first end of screw rod is connected with vice branch rotation, and is used for driving vice branch and removes.

Unfiltered epoxy coating is shifted to in the filter box, and operating personnel rotates the screw rod according to the mobility of epoxy coating, the characteristics of consistency, and the screw rod drives vice branch along the direction of uide bushing and goes up and down, and vice branch drives and filters the box and goes up and down to reach the inclination size of adjustment filter box and horizontal plane. When the epoxy resin coating with high fluidity and low viscosity is filtered, the angle between the filtering box body and the horizontal plane is reduced; when the epoxy resin coating with poor fluidity and high viscosity is filtered, the inclination angle between the filtering box body and the horizontal plane is increased.

Adopt the produced beneficial effect of above-mentioned technical scheme to lie in: the device is when using, can adjust the angle of filtering box slope according to the characteristic of epoxy coating to can filter the epoxy coating of various characteristics, operating personnel easy operation, labour saving and time saving has avoided purchasing multiple filtration equipment, thereby reduces manufacturing cost. In addition, the device can also clear away the granule impurity after filtering, and labour saving and time saving improves production efficiency.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive effort.

FIG. 1 is a schematic view of a filtering apparatus for epoxy resin coating provided by an embodiment of the present invention;

FIG. 2 is a schematic structural view of another angle of the filtering apparatus for epoxy resin coating provided by the embodiment of the present invention;

fig. 3 is a schematic structural view of the auxiliary support rod, the main support rod, the guide sleeve and the screw rod provided by the embodiment of the present invention;

FIG. 4 is an assembly view of the upper housing, filter plate and lower housing provided by an embodiment of the present invention;

fig. 5 is an assembly view of the secondary support bar and the primary support bar provided by the embodiment of the present invention;

fig. 6 is an assembly view of a support and a secondary support rod provided by an embodiment of the present invention;

fig. 7 is a top view of the upper housing, the push plate and the power mechanism according to the embodiment of the present invention.

Fig. 8 is a schematic structural diagram of the upper housing, the push plate and the flexible element according to an embodiment of the present invention.

Description of reference numerals:

10-a filter box body; 101-an upper shell; 102-a filter plate; 103-a lower shell; 11-secondary struts; 111-positioning blocks; 112-a connecting rod; 12-a primary strut; 121-opening; 122-a limiting hole; 123-a limit pin; 124-a cross bar; 13-a guide sleeve; 14-a screw; 15-a drive unit; 21-a support; 211-positioning grooves; 22-a rotating shaft; 30-residue port; 31-a push plate; 311-a flexible element; 32-a power motor; 321-a nut; 322-lead screw; 323-driven wheel; 324-a drive wheel; 325-power shaft; 326-a power motor; 41-spiral motor.

Detailed Description

In the following description, for purposes of explanation and not limitation, specific details are set forth, such as particular system structures, techniques, etc. in order to provide a thorough understanding of the embodiments of the invention. It will be apparent, however, to one skilled in the art that the present invention may be practiced in other embodiments that depart from these specific details. In other instances, detailed descriptions of well-known systems, devices, circuits, and methods are omitted so as not to obscure the description of the present invention with unnecessary detail.

The embodiment of the utility model provides an epoxy coating's filter equipment combines fig. 1, fig. 2, fig. 3, fig. 4 and fig. 5 to show, and epoxy coating's filter equipment is including filtering box 10, vice branch 11, main tributary pole 12, uide bushing 13 and screw rod 14. The filter box 10 is used to filter impurities in the epoxy resin paint. The filter case 10 includes an upper case 101, a filter plate 102, and a lower case 103. The upper case 101 is located above the lower case 103 in the vertical direction. The filter plate 102 is located between the upper case 101 and the lower case 103, and serves to allow impurities to remain in the upper case 101 and allow the filtered epoxy paint to flow into the lower case 103 when the epoxy paint flows through the filter plate 102. The auxiliary supporting rod 11 is located below the filtering box 10 in the vertical direction, and the top end of the auxiliary supporting rod is connected with the filtering box 10 and used for driving the filtering box 10 to move in the vertical direction. The top end of the main supporting rod 12 is connected with the bottom of the auxiliary supporting rod 11 in a sliding mode. The guide sleeve 13 is arranged on the main strut 11. The screw 14 is screw-coupled to the guide sleeve 13 at a middle portion thereof and moves along the guide sleeve 13 while rotating relative to the guide sleeve 13. The first end of the screw 14 is rotatably connected with the auxiliary supporting rod 11 and is used for driving the auxiliary supporting rod 11 to move.

The unfiltered epoxy paint is transferred into the filter case 10, and large particles or impurities in the epoxy paint are separated by the filter plate 102 disposed between the upper case 101 and the lower case 103. An operator rotates the screw 14 according to the characteristics of fluidity and viscosity of the epoxy resin coating, the screw 14 pushes the auxiliary support rod 11 to vertically lift under the guidance of the guide sleeve 13, and the auxiliary support rod 11 pushes one side of the filtering box body 10 to vertically lift, so that the size of the inclination angle between the filtering box body 10 and the horizontal plane is adjusted. When the fluidity and the viscosity of the epoxy resin coating are high and low, the angle between the inclined filtering box body and the horizontal plane is small, and when the fluidity and the viscosity of the epoxy resin coating are low, the inclination angle is large.

The second end of the secondary strut 11 is located in the opening 121 of the primary strut 11 and is able to slide up and down relative to the primary strut 12. When the epoxy coating mobility is strong, when filtering box 10 needs to reduce the angle, vice branch 11 retracts into the opening of main tributary pole 12, filters box 10 and drives at vice branch 11 and rotate, filters box 10 and reduces the inclination with the horizontal plane. When the epoxy coating mobility is low, when filter box 10 needs to increase the angle, vice branch 11 rises from main branch 12 opening part, and filter box 10 drives at vice branch 11 and rotates, and the inclination of filter box 10 and horizontal plane increases. The epoxy resin coating with poor fluidity can be filtered quickly in the filtering box body 10 with a certain inclination angle.

Specifically, the upper housing 101 is removably connected to the filter board 102. Specifically, the upper housing 101 and the filter plate 102 may be connected by bolts or by fasteners. Specifically, the upper housing 101 is detachably connected to the lower housing 103. Specifically, the upper housing 101 and the lower housing 103 may be connected by a flange or a bayonet, and may be periodically maintained or cleaned by an operator. Specifically, the filter plate 102 is preferably made of 304 stainless steel, which can increase the service life and reduce the replacement cost. Specifically, the pore size of the filter plate 102 is 10um to 1000 um.

A filter assembly for epoxy paint also includes a connecting rod 112 and a cross-bar 124. The connecting rod 112 is connected to the secondary strut 11 and is rotatably connected to a first end of the screw 14. The cross bar 124 is connected to the main bar 12, and the guide sleeve 13 is disposed on the main bar 12.

The screw 14 is rotatably connected with the guide sleeve 13 arranged on the cross rod 124, the screw 14 moves along the direction of the guide sleeve 13, the screw 14 drives the connecting rod 112 to move, the connecting rod 112 drives the auxiliary supporting rod 11 to move, and the auxiliary supporting rod 11 drives the filtering box body 10 to move. Specifically, the cross bar 124 is fixedly connected to the main bar 12. In particular, the cross bar 124 and the main bar 12 may be welded.

The guide sleeve 13 plays a role in guiding the screw 14, the screw 14 is guided to move up and down along the vertical direction, the screw 14 drives the connecting rod 112 to move, and the connecting rod 112 drives the auxiliary supporting rod 11 to move up or down along the direction of the guide sleeve 13. Specifically, the guide sleeve 13 and the main support rod 12 may be detachably connected or may be fixedly connected.

The filtering device for the epoxy resin coating further comprises a helical blade, a helical motor 41, a speed reducer and a discharge opening. The helical blade is disposed in the lower housing 103 for transporting the filtered epoxy coating out. The screw motor 41 is connected with the screw blade and is used for driving the screw blade to rotate and transfer. The second end of the reducer is connected to the screw motor 41 and the first end is connected to the helical blade. The discharge opening sets up in one side of casing down for the epoxy coating that will filter is transported away.

Screw motor 41 is connected with lower casing 103 rotates, and screw motor 41 drive reduction gear rotates, and the reduction gear drives helical blade and rotates, and helical blade drives the epoxy coating that filters and transmits outside the discharge opening, and epoxy coating conveys away through the discharge opening, reduces the stay of epoxy coating in lower casing 103. Specifically, the screw motor 41 is detachably connected to the lower housing 103. Specifically, the screw motor 41 and the lower housing 103 are rotatably connected by a bolt. Specifically, the screw motor 41 is detachably connected to the decelerator. Specifically, the screw motor 41 and the speed reducer may be connected by bolts. Specifically, the speed reducer is detachably connected with the helical blade. Specifically, the speed reducer and the helical blade may be connected by bolts.

As an embodiment, as shown in fig. 1, 2 and 6, the filtering apparatus for epoxy resin paint further includes a support 21 and a rotating shaft 22. The holder 21 is provided at one side of the filter housing 10 and is connected to the filter housing 10. The rotation shaft 22 is provided on the support 21. The first end of the rotating shaft 22 is connected with the support 21, and the second end is rotatably connected with the auxiliary strut 11.

When the auxiliary support rod 11 is lifted or lowered in use, the filter box 10 will increase or decrease the inclination angle between the filter box 10 and the horizontal plane by using the rotation shaft 22 as the axis. Specifically, the support 21 is detachably connected to the filter housing 10. Specifically, the support 21 and the filter housing 10 may be bolted. Specifically, the rotating shaft 22 is fixedly connected with the support 21. Specifically, the rotating shaft 22 and the support 21 may be welded.

As an embodiment, as shown in fig. 6, the support 21 has a positioning groove 211, and the secondary support rod 11 has a positioning block 111 slidably engaged with the positioning groove 211.

The first end of the positioning block 111 is connected with the auxiliary support rod 11, and the second end is connected with the support 21. The locating slot 211 and the locating slot 211 are matched for use, so that the locating function is achieved for the auxiliary supporting rod 11, the auxiliary supporting rod 11 is probably ensured not to shake when rotating, and the stability of the auxiliary supporting rod 11 when rotating is improved.

As an example, as shown in fig. 1, 2 and 3, the filtering apparatus for epoxy resin paint further includes a driving unit 15. The driving unit 15 is connected to the screw 14 for driving the screw 14 to rotate.

When the filter box body 10 is used, the driving unit 15 has a limiting effect on the filter box body 10, when the filter box body 10 needs to be inclined to reduce the angle, the driving unit 15 transports the driving screw 14 to descend, and the screw 14 drives the filter box body 10 to descend. When the filter box 10 needs to be tilted to be enlarged, the driving unit 15 rotates reversely to drive the screw 14 to ascend, and the screw 14 drives the filter box 10 to ascend.

Specifically, the driving unit 15 may adopt a transmission manner of a pulley, a chain wheel, a chain or a manual handle, and an optimal manner may be selected according to actual production requirements. Specifically, the driving unit 15 is connected to the second end of the screw 14. Specifically, the driving unit 15 is detachably connected to the screw 14. The drive unit 15 and the screw 14 may be bolted.

As an embodiment, as shown in fig. 1, 2, 3 and 5, the filtering apparatus for epoxy resin paint further includes a limiting hole 122 and a limiting pin 123. The limiting hole 122 is provided on the main bar 12. The limit pin 123 is inserted into the limit hole 122 and contacts against the auxiliary support rod 11 to position the auxiliary support rod 11 on the main support rod 12.

The filter box body 10 is adjusted by the screw 14 to prevent the screw 14 from loosening and displacing in the production process. In view of this, the present embodiment provides the stopper hole 122 and the stopper pin 123. Specifically, the axis of the limit pin 123 is perpendicular to the axis of the auxiliary strut 11, and the limit pin 123 connects the auxiliary strut 11 with the main strut 12 through the limit hole 122, so as to ensure that the auxiliary strut 11 does not deviate in the using process.

As an embodiment, as shown in fig. 1 and 2, the filtering apparatus for epoxy resin paint further includes a residue opening 30, a push plate 31 and a power mechanism. The residue port 30 is disposed in the filtering box 10 and is communicated with the cavity of the filtering box 10. The push plate 31 is disposed in the filter housing 10 and connected to the filter plate 102 of the filter housing 10, for pushing the impurities remaining on the filter plate 102 to the residue port 30. The power mechanism is arranged in the filtering box body 10 and is connected with the filtering box body 10 in a sliding way. The power mechanism is connected with the push plate 31 and is used for driving the push plate 31 to move.

The filter 102 filters out and intercepts the particles or impurities in the epoxy resin coating on the filter 102, and when the filter is used, the epoxy resin coating stops being injected, the power mechanism starts to drive the push plate 31 to move towards the residue port 30, the push plate 30 pushes the particles or impurities to move, and the particles or impurities flow out along the residue port 30. When the particles or impurities are pushed to the residue port 30, the power mechanism moves in reverse to the initial position, and then injects the epoxy resin coating into the filter case 10 again.

Specifically, the residue port 30 is connected to the upper case 101. Specifically, the upper shell is provided with a slag outlet, and the residue outlet 30 is communicated with the slag outlet, so that particles or impurities can flow out through the residue outlet conveniently. Specifically, the residue port 30 is detachably connected to the upper case 101. Specifically, the residue port 30 and the upper case 101 may be bolted together.

As an embodiment, as shown in fig. 3 and 6, the power mechanism includes a nut 321, a lead screw 322, and a power assembly. The nut 321 is slidably connected to the filter box 10 and connected to the push plate 31 for driving the push plate 31 to move. The screw rod 322 is rotatably connected to the filter box 10 and is in threaded connection with the nut 321 for driving the nut 321 to move. The power assembly is connected with the lead screw 322 and is used for driving the lead screw 322 to rotate.

The power assembly drives the screw rod 322 to rotate, the screw rod 322 drives the nut 321 to move, and the nut 321 drives the push plate 31 to move. Specifically, the power assembly can adopt a gear set transmission mode, a belt pulley transmission mode and a chain wheel and chain transmission mode.

As an example, as shown in fig. 2 and 7, the power assembly includes a driven wheel 323, a driving wheel 324, a power shaft 325, and a power motor 326. The driven wheel 323 is connected with the lead screw 322 and is used for driving the lead screw 322 to rotate. The driving wheel 324 is connected with the driven wheel 323 and is used for driving the driven wheel 323 to rotate. The power shaft 325 is connected to the driving wheel 324 and is used for driving the driving wheel 324 to rotate. The power motor 326 is coupled to the power shaft 325 and is configured to drive the power shaft 325 in rotation.

The transmission mode of belt pulley and sprocket chain all has occupation space big, the transmission inefficiency problem, consequently adopts the transmission mode of gear train in this embodiment. The power motor 326 drives the power shaft 325 to rotate, the power shaft 325 drives the driving wheel 324 to rotate, the driving wheel 324 drives the driven wheel 323 to rotate, and the driven wheel 323 drives the lead screw 322 to rotate. Specifically, the driving wheel 324 and the driven wheel 323 can adopt a direct meshing transmission mode, a belt pulley transmission mode or a transmission mode of meshing a plurality of gears of a chain wheel and a chain.

In view of this, in the present embodiment, the driven wheel 323 and the driving wheel 324 are both bevel gears. Because the bevel gear has a large transmission mode torsion, low noise, stable transmission and strong bearing capacity, in this embodiment, the driven wheel 323 and the driving wheel 324 both adopt the bevel gear.

As an embodiment, as shown in fig. 2, 7 and 8, the number of the nuts 321 is two, and the two nuts 321 are respectively located at two sides of the push plate 31. The number of the lead screws 322 is two, and the lead screws 322 correspond to the nuts 321 one by one. The number of the driven wheels 323 is two, and the driven wheels 323 correspond to the lead screws 322 one by one. The number of the driving wheels 324 is two, and the driving wheels 324 correspond to the driven wheels 323 one by one. The two drive wheels 324 are each connected to a power shaft 325.

Two lead screws 42 are respectively positioned at both sides of the filter box body 10, and the length direction of the lead screws 42 is consistent with the moving direction of the push plate 31. Two nuts 41 are located on either side of the push plate 31. In the moving process, the rotating speeds of the two lead screws 42 are consistent, so that the moving speeds of the two nuts 41 are consistent, and the push plate 31 can be uniformly stressed.

As an example, referring to fig. 8, the filtering apparatus for epoxy resin paint further includes a flexible member 311. The flexible member 311 is disposed at the bottom end of the push plate 31, and has a first end connected to the push plate 31 and a second end slidably connected to the filter plate 102.

The bottom of the push plate 31 is provided with a flexible member 311, and the flexible member 311 can be attached to the bottom plate of the filter plate 102, thereby pushing the particles or impurities on the filter plate 102 into the residue port 30. In addition, the use of the flexible member 311 can reduce noise and can reduce abrasion of the push plate 31 to the filter plate 102. Specifically, the flexible element 311 may be a brush or a cotton cloth. The flexible element 311 is detachably connected to the push plate 31, so that the flexible element 311 can be cleaned or replaced regularly.

The device is at the in-process that uses, can adjust the angle of filtering the box slope according to the characteristic of epoxy coating to can filter the epoxy coating of various characteristics, operating personnel easy operation, labour saving and time saving has avoided purchasing other filtration equipment, thereby reduction in production cost. In addition, the device can also clear away the granule impurity after filtering, and labour saving and time saving improves production efficiency.

The above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the spirit and scope of the embodiments of the present invention, and are intended to be included within the scope of the present invention.

Claims

1. A filter device for epoxy resin paint, comprising:

the guide sleeve is arranged on the main supporting rod;

2. The epoxy coating filter device of claim 1, further comprising:

3. The epoxy resin coating filter device of claim 2, wherein: the support is provided with a positioning groove, and the auxiliary supporting rod is provided with a positioning block in sliding fit with the positioning groove.

4. The epoxy coating filter device of claim 1, further comprising:

5. The epoxy coating filter device of claim 1, further comprising:

the limiting hole is arranged on the main supporting rod; and

6. The epoxy coating filter device of claim 1, further comprising:

7. The epoxy coating filter device of claim 6, wherein the power mechanism comprises:

8. The epoxy coating filter device of claim 7, wherein the power assembly comprises:

9. The epoxy resin coating filter device of claim 8, wherein: the number of the nuts is two, and the two nuts are respectively positioned on two sides of the push plate;

10. The epoxy coating filter device of claim 6, further comprising: