CN219076566U - Orifice plate lining rubber tool - Google Patents

Abstract

The utility model discloses a hole plate rubber lining tool, which comprises a vacuum suction head, wherein a cavity is formed in the vacuum suction head, and one end of the vacuum suction head, which is far away from the connection with a negative pressure generating mechanism, is implemented as an adsorption end; the puncture mechanism is arranged in the cavity and provided with a puncture part, one end of the puncture part, which faces the direction of the adsorption end, is implemented as a tip, a gap is formed between the puncture mechanism and the inner wall of the vacuum suction head, and rubber to be lined is sucked into the holes of the porous plate to be lined under the action of negative pressure and is punctured by the tip of the puncture part. The vacuum suction head is adopted to generate suction force to suck the rubber to be lined into the hole, the rubber in the hole is punctured by the tip end of the puncturing mechanism, the punctured rubber can be tightly attached to the inner wall of the hole under the action of the suction force, and the efficiency of lining the rubber of the hole plate is improved without rolling by a press roller.

Description

Orifice plate lining rubber tool

Technical Field

The utility model belongs to the technical field of rubber liners, and particularly relates to a hole plate rubber lining tool.

Background

The sticking of one or more layers of corrosion-resistant and wear-resistant rubber liners to metal equipment is a very effective method of protecting metal equipment from damage by corrosive or abrasive media. The method has been widely used in chemical industry, electric power condenser, water treatment equipment, ion exchange resin, etc. Many porous plates are arranged in the devices, and some devices have dozens or even hundreds of holes, the pore diameter of the porous plates is 35-45 mm before rubber lining, the thickness of the rubber lining is 3-5 mm, and the pore diameter of the rubber lining is 25-35 mm.

The prior porous plate rubber lining method comprises the steps of carrying out sand blasting treatment on equipment comprising a porous plate, brushing a rubber binder, spreading a rubber plate which is also coated with the binder on the surface of the porous plate after air drying, rolling by a press roller, tightly adhering the rubber plate on the plane of the porous plate, and then flushing rubber lined on the porous plate into the pores by a blowing method by a blowing equipment, namely, using the air pressure of compressed air, so that the front end of the rubber plate on the porous plate is broken after being blown into the pores, the rubber is adhered to the pore wall due to the large elasticity, the rubber is not completely adhered to the pore wall, the edge of the rubber is in a saw-tooth shape, the rubber is tightly pressed to the pore wall by the press roller, and the defects of tilting, bubbling, delamination and the like are easy to occur to the rubber on the porous plate, and the efficiency is also low. In addition, the method is only suitable for lining glue on a perforated plate with the steel plate thickness less than or equal to 30mm, and the perforated plate with larger thickness is difficult to blow the glue plate to a proper position in the hole completely. For the porous plate, the prior method is to vertically press the rubber on the porous plate by using a cylindrical cone head, push the rubber plate into the hole, squeeze the rubber plate contacted with the cone head into a hole shape, then cross-roll for at least 2 times, tightly press the rubber plate on the hole wall by using a press roller, and heat and press vulcanization in a vulcanizing tank after rubber lining is completed. Because the process is completely manual operation, the efficiency is low, and the defects of tilting, bubbling, delamination and the like of the rubber plate are easily caused by partial rolling in-place in the hole.

Therefore, it is necessary to develop a hole plate rubber lining tool to solve the above technical problems.

Disclosure of Invention

In view of at least one of the above technical problems, the present utility model aims to: a low pressure orifice plate lining rubber frock is provided.

The technical scheme of the utility model is as follows:

the utility model aims to provide a hole plate rubber lining tool, which comprises the following components:

the vacuum suction head is provided with a cavity therein, and one end of the vacuum suction head, which is far away from the connection with the negative pressure generating mechanism, is implemented as an adsorption end;

the puncture mechanism is arranged in the cavity and provided with a puncture part, one end of the puncture part, which faces the direction of the adsorption end, is implemented as a tip, a gap is formed between the puncture mechanism and the inner wall of the vacuum suction head, and rubber to be lined is sucked into the holes of the porous plate to be lined and is punctured by the tip of the puncture part under the action of negative pressure.

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

according to the hole plate rubber lining tool, the vacuum suction head is used for generating suction force to suck rubber to be lined into the holes of the hole plate to be lined with rubber from the opposite side of the vacuum suction head, the rubber in the holes is punctured through the tip end of the puncturing mechanism, the punctured rubber can be tightly attached to the inner wall of the holes under the action of the suction force, and the pressing roller is not needed to roll, so that the efficiency of the hole plate rubber lining is improved. The problem of among the prior art adopt the method of blowing to carry out the lining of perforated plate to glue, because of rubber elasticity is big, lead to partial rubber and pore wall to have the space, need roll the back just can closely laminate on the pore wall through the compression roller.

Drawings

The utility model is further described below with reference to the accompanying drawings and examples:

FIG. 1 is a schematic diagram of a cross-sectional structure of an orifice plate rubber lining tool according to an embodiment of the utility model;

fig. 2 is a schematic diagram of a cross-sectional structure of the hole plate lining tool according to the embodiment of the utility model when the tool is used for lining rubber on a hole plate.

FIG. 3 is a schematic diagram of a cross-sectional structure of a hole plate lining tool for a hole plate lining according to an embodiment of the present utility model;

fig. 4 is a schematic structural diagram of a porous plate and a vulcanization tool after the completion of rubber lining by using the hole plate rubber lining tool according to the embodiment of the utility model.

Wherein: 1. a vacuum suction head; 10. a cavity; 101. a first lumen; 102. a second lumen; 103. a third lumen; 11. a first body; 111. a connection end; 12. a second body; 13. a mounting wall; 2. a lancing mechanism; 21. a mounting frame; 22. a blade; 3. a seal ring; 4. an anti-sticking film; 5. an electromagnetic valve; 6. vacuum rubber tube; 7. a porous plate; 71. a hole; 8. rubber to be lined; 9. and (5) vulcanizing the tool.

Detailed Description

The objects, technical solutions and advantages of the present utility model will become more apparent by the following detailed description of the present utility model with reference to the accompanying drawings. It should be understood that the description is only illustrative and is not intended to limit the scope of the utility model. In addition, in the following description, descriptions of well-known structures and techniques are omitted so as not to unnecessarily obscure the present utility model.

Examples

Referring to fig. 1 to 4, an orifice plate lining rubber tool of the present embodiment includes a vacuum suction head 1, a puncture mechanism 2 and a negative pressure generating mechanism (not shown). The vacuum suction head 1 has a cavity 10 therein and the end of the vacuum suction head 1 remote from the connection with the negative pressure generating mechanism is embodied as an adsorption end which is adsorbed to the perforated plate 7 to be lined with glue. The negative pressure generating mechanism is used for vacuumizing the vacuum suction head 1 so as to generate negative pressure in the vacuum suction head 1 to form suction force. The puncturing mechanism 2 is arranged in the cavity and is provided with a puncturing part, one end of the puncturing part facing the direction of the adsorption end is implemented as a tip, a gap is formed between the puncturing mechanism 2 and the inner wall of the vacuum suction head 1, and the rubber to be lined 8 is sucked into the hole of the porous plate 7 to be lined with rubber under the action of negative pressure and is punctured by the tip of the puncturing part. The vacuum suction head 1 is adopted to correspond to the hole 71 to be lined with the rubber of the porous plate 7 to be lined with the rubber, negative pressure is generated in the vacuum suction head 1 by utilizing the negative pressure generating mechanism, the rubber 8 to be lined is adsorbed into the hole 71 of the porous plate 7 by the suction force, the puncture mechanism 2 is arranged in the vacuum suction head 1, the tip of the puncture mechanism 2 punctures the rubber 8 to be lined, and the punctured rubber can be continuously tensioned by the suction force along the radial direction under the action of the suction force to be tightly attached to the inner wall of the hole 71 of the porous plate 7 without rolling by a compression roller, and then the rubber is directly vulcanized in a vulcanizing tank without tilting, bubbling or delamination, so that the rubber lining efficiency of the porous plate is improved. The problem of among the prior art adopt the method of blowing to carry out the lining of perforated plate to glue, because of rubber elasticity is big, lead to partial rubber and pore wall to have the space, need roll the back just can closely laminate on the pore wall through the compression roller.

According to a preferred embodiment of the present utility model, as shown in fig. 1 to 3, the end of the vacuum cleaner head 1 to which the negative pressure generating mechanism is connected is implemented as a connection end 111. The vacuum cleaner head 1 comprises a first body 11 having a first interior cavity 101 and a second body 12 having a second interior cavity 102, the end of the first body 11 remote from the second body 12, i.e. the left end of the first body 11 as shown in fig. 1, being embodied as a connecting end 111, and the end of the second body 12 remote from the first body 11, i.e. the right end of the second body 12 as shown in fig. 1, being embodied as a suction end. The aperture of the first lumen 101 is smaller than the aperture of the second lumen 102. The outer diameter of the first body 11 is smaller than the outer diameter of the second body 12. The length L1 of the first body 11 is greater than the length L2 of the second body 12. The first body 11 is intended to be held by an operator. Preferably, the aperture D1 of the first lumen 101 is 8-12 mm. So as to be matched with the electromagnetic valve 5 and provide the vacuum suction head 1 with proper vacuum degree. The aperture D2 of the second inner cavity 102 and the aperture D0 of the porous plate 7 to be lined with glue satisfy: d2-d0=12 mm to 20mm. The outer diameter D3 of the second body 12 and the aperture D2 of the second lumen 102 satisfy: d3-d2=12 mm to 20mm. So as to ensure a sufficient sealing area with the porous plate 7 to be lined with glue and prevent air leakage. The length l=l1+l2=100 mm to 140mm of the vacuum cleaner head 1. Is convenient for an operator to hold.

According to a preferred embodiment of the present utility model, as shown in fig. 1 to 3, a sealing ring 3 is disposed on the adsorption end, the thickness of the sealing ring 3 is 3mm, and the inner diameter of the sealing ring 3 is consistent with the inner hole of the second inner cavity 102. As the seal ring 3, an existing conventional rubber seal ring 3 such as neoprene can be selected. Is directly stuck on the adsorption end of the vacuum suction head 1 by a sticking mode. The vacuum suction head 1 can be effectively protected, the abrasion of the vacuum suction head 1 is prevented, the function of protecting the porous plate 7 to be lined with glue can be also achieved, and the abrasion caused by the hard contact between the vacuum suction head 1 and the porous plate 7 to be lined with glue is prevented.

According to a preferred embodiment of the present utility model, as shown in fig. 1 to 3, the sealing ring 3 is provided with an anti-adhesive film 4 at a side far from the end connected to the adsorption end, i.e., at the right end as shown in fig. 1. Preferably, the release film 4 is a Teflon release film 4 with one side being self-adhesive and the other side being release to prevent the vacuum cleaner head 1 from adhering to the adhesive and rubber on the porous plate 7 to be lined with glue.

According to a preferred embodiment of the present utility model, as shown in fig. 1 to 3, the inner wall where the first inner cavity 101 and the second inner cavity 102 meet encloses a third inner cavity 103, the aperture of the third inner cavity 103 is between the aperture of the first inner cavity 101 and the aperture of the second inner cavity 102, and the first inner cavity 101, the second inner cavity 102 and the third inner cavity 103 together form the cavity 10. The wall of the second interior space 102 facing the first interior space 101 is embodied as a mounting wall 13 for the lancing mechanism 2. The lancing mechanism 2 comprises a mounting frame 21 fixed to the mounting wall 13 and a blade 22 mounted in a position intermediate the face of the mounting frame 21 facing the suction end, the mounting frame 21 extending from the third internal cavity 103 into the second internal cavity 102, the blade 22 being located in the second internal cavity 102 and extending in a direction coincident with the axis of the vacuum cleaner head 1. It should be noted that the tip of the blade 22 is flush with or slightly within the port of the suction end, i.e., to the left of the port of the suction end as shown in fig. 1, so as to avoid injury to the person when the tip protrudes outside. Specifically, the inner cavity 10 is smaller along the direction from the adsorption end to the connection end 111, so that a step surface is formed at the joint of the third inner cavity 103 and the first inner cavity 101, the step surface is the installation wall 13, the installation frame 21 is in a cylindrical shape or a U-shape between the third inner cavity 103 and the first inner cavity 101, and besides providing a foundation for installing the blade 22, the second inner cavity 102, the third inner cavity 103 and the first inner cavity 101 are also required to be communicated. The blade 22 is a tapered blade 22 as shown in fig. 1.

According to a preferred embodiment of the present utility model, as shown in fig. 1 to 3, a solenoid valve 5 is connected to the connection end 111 of the vacuum cleaner head 1. Such as a conventional electromagnetic valve, with an air hole that mates with the connecting end 111 of the vacuum cleaner head 1. A button (not shown) is provided on the electromagnetic valve to facilitate control of the on-off of the vacuum cleaner head 1 to the negative pressure generating mechanism. In operation, a negative pressure is generated in the suction head by simply pressing a button of the electromagnetic valve 5.

Preferably, the negative pressure generating mechanism is a vacuum pump, preferably an existing conventional negative pressure oilless vacuum pump with a microcomputer, meets the environmental protection requirement, and has the power of 3KW, the vacuum range of 0 to-0.10 MPa and the vacuum degree of-0.10 MPa so as to provide sufficient negative pressure for the suction head. The electromagnetic valve 5 is connected with a vacuum pump through a vacuum rubber pipe 6. The inner diameter of the vacuum rubber tube 6 is 8 mm-10 mm, and the outer diameter is 12 mm-15 mm. So as to ensure that the vacuum suction head 1 can be provided with sufficient negative pressure, and is convenient to move in the rubber lining equipment and not easy to damage.

The process of the porous plate 7 rubber lining tool for the porous steel plate rubber lining is as follows:

s1, carrying out sand blasting and rust removal treatment on the surface of a porous plate 7 to be lined with glue to achieve the Sa2.5 level; and after purging, according to the material of the rubber 8 to be lined, coating a natural rubber adhesive such as an SP-2 adhesive, coating the SP-2 adhesive for the second time after air drying, and air drying for later use.

S2, coating the SP-2 adhesive once to obtain a rubber plate to be lined with the rubber 8, and air-drying for later use;

and S3, spreading the glue plate obtained in the step S2 on one surface of the porous plate 7 obtained in the step S1, rolling the glue plate by using a pressing roller, and tightly adhering the glue plate to the surface of the porous plate 7 to be lined with glue.

S4, starting a vacuum pump, holding the vacuum suction head 1 by hand, pressing a button of the electromagnetic valve 5, moving the vacuum suction head 1 to the vicinity of the hole of the porous plate 7 obtained in the S3, automatically adsorbing the vacuum suction head 1 to the porous plate 7, covering one hole, sucking a rubber plate opposite to the porous plate 7 into the hole within 2 seconds, and tightly adhering the rubber plate to the hole wall; the tip is then moved to the next well and the operation is continued until the operation has completed all wells.

S5, rubber lining is carried out on the other surface of the porous plate 7, and the rubber lining plates with rubber lining on the two surfaces and in the holes are obtained;

s6, inserting a vulcanization tool 9 (an expansion pipe-aluminum pipe) immersed in soapy water into the rubber lining hole of the rubber lining plate obtained in the S5;

and S7, moving the rubber lining plate obtained in the step S6 to a vulcanizing tank, pressurizing, heating and vulcanizing for a plurality of hours according to the vulcanizing process of the rubber lining material, then cooling to 60 ℃, reducing the pressure to 0, opening the vulcanizing tank, and checking the quality of rubber lining, thereby completing the rubber lining of the porous plate 7.

It is to be understood that the above-described embodiments of the present utility model are merely illustrative of or explanation of the principles of the present utility model and are in no way limiting of the utility model. Accordingly, any modification, equivalent replacement, improvement, etc. made without departing from the spirit and scope of the present utility model should be included in the scope of the present utility model. Furthermore, the appended claims are intended to cover all such changes and modifications that fall within the scope and boundary of the appended claims, or equivalents of such scope and boundary.

Claims (10)

1. The utility model provides a orifice plate lining gluey frock which characterized in that includes:

the vacuum suction head is provided with a cavity therein, and one end of the vacuum suction head, which is far away from the connection with the negative pressure generating mechanism, is implemented as an adsorption end;

the puncture mechanism is arranged in the cavity and provided with a puncture part, one end of the puncture part, which faces the direction of the adsorption end, is implemented as a tip, a gap is formed between the puncture mechanism and the inner wall of the vacuum suction head, and rubber to be lined is sucked into the holes of the porous plate to be lined and is punctured by the tip of the puncture part under the action of negative pressure.

2. The orifice plate lining tooling of claim 1, wherein the end of the vacuum suction head connected with the negative pressure generating mechanism is implemented as a connecting end;

the vacuum suction head comprises a first main body with a first inner cavity and a second main body with a second inner cavity, wherein one end of the first main body far away from the second main body is implemented as the connecting end, and one end of the second main body far away from the first main body is implemented as the adsorbing end;

the aperture of the first inner cavity is smaller than that of the second inner cavity.

3. The orifice plate lining tooling of claim 2, wherein an outer diameter of the first body is smaller than an outer diameter of the second body; and/or

The length L1 of the first body is greater than the length L2 of the second body.

4. A hole plate glue lining tooling according to claim 2 or 3, wherein the first and second inner cavities are coaxially arranged.

5. The hole plate rubber lining tool according to claim 4, wherein the aperture D1 of the first inner cavity is 8-12 mm;

the aperture D2 of the second inner cavity and the aperture D0 of the porous plate to be lined with glue meet the following conditions: d2-d0=12 mm to 20mm;

the outer diameter D3 of the second main body and the aperture D2 of the second inner cavity satisfy the following conditions: d3-d2=12 mm to 20mm;

the length L=L1+L2=120 mm-160 mm of the vacuum suction head.

6. The hole plate rubber lining tool according to claim 2, wherein the inner wall at the joint of the first inner cavity and the second inner cavity encloses a third inner cavity, the aperture of the third inner cavity is between the aperture of the first inner cavity and the aperture of the second inner cavity, and the first inner cavity, the second inner cavity and the third inner cavity jointly form the cavity;

the wall surface of the second inner cavity facing to one side of the first inner cavity is implemented as a mounting wall for mounting the puncturing mechanism;

the piercing mechanism comprises a mounting frame fixed on the mounting wall and a blade arranged at the middle position of the surface of the mounting frame facing the adsorption end, the mounting frame extends from the third inner cavity to the second inner cavity, and the blade is positioned in the second inner cavity and has the extending direction consistent with the axis of the vacuum suction head.

7. The orifice plate lining frock of claim 1, wherein a sealing ring is arranged on the adsorption end, and the thickness of the sealing ring is 3mm.

8. The orifice plate lining frock of claim 7, wherein the sealing washer is kept away from the one end of being connected with the adsorption terminal and is equipped with the anti-sticking membrane.

9. The orifice plate lining frock of claim 1, wherein the connecting end of the vacuum suction head is connected with an electromagnetic valve.

10. The hole plate rubber lining tool according to claim 9, wherein the negative pressure generating mechanism is a vacuum pump, and the electromagnetic valve is connected with the vacuum pump through a vacuum rubber pipe;

the inner diameter of the vacuum rubber tube is 8-10 mm, and the outer diameter is 12-15 mm.

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