CN109454527B

CN109454527B - Device for treating surface coating of non-oriented silicon steel

Info

Publication number: CN109454527B
Application number: CN201811287242.8A
Authority: CN
Inventors: 黄双; 李忠武; 邱忆; 蒋祝爽; 张俊鹏; 张婷婷
Original assignee: Wuhan Iron and Steel Co Ltd
Current assignee: Wuhan Iron and Steel Co Ltd
Priority date: 2018-10-31
Filing date: 2018-10-31
Publication date: 2020-11-17
Anticipated expiration: 2038-10-31
Also published as: CN109454527A

Abstract

The invention discloses a treatment device for a non-oriented silicon steel surface coating, which consists of a machine body shell and a main structure arranged in the machine body shell, wherein a power indicator lamp and a switch control button are arranged on the machine body shell; the main structure comprises a sample fixing system, a sample polishing system and an equipment control unit, wherein the sample fixing system, the sample polishing system, a power indicator lamp and a switch control button are respectively connected with the equipment control unit. The invention has the beneficial effects that: the coating treatment device comprises the abrasive belt machine, and is combined with a plurality of groups of cylinders, and the coating on the surface of the sample is polished by using a mechanical polishing mode; and alkali liquor does not need to be specially prepared and the reaction time is controlled, so that the manual interference is less, and the coating is removed more uniformly.

Description

Device for treating surface coating of non-oriented silicon steel

Technical Field

The invention relates to the technical field of coating treatment, in particular to a treatment device for a carbon surface coating of non-oriented silicon steel, which can automatically remove the surface coating and recover coating powder in the carbon content detection and sample preparation process of a non-oriented silicon steel finished product.

Background

The non-oriented silicon steel is mainly used for iron core materials of motors, and the carbon content in steel plates determines the timeliness of the iron core materials and influences the service life of the iron core materials. Therefore, the carbon content of the steel plate is detected in production, and the surface coating of the steel plate needs to be removed in order to truly reflect the carbon content of the material. At present, the treatment method of the surface coating of the steel plate is an alkali soaking method, namely, heating alkali liquor by a heating furnace to boil the alkali liquor into saturated alkali solution, soaking a steel plate sample in the saturated alkali solution for 2 minutes, and then taking out the steel plate sample to be brushed by clean water. The method has higher requirements on the boiling of the alkali solution and the control of the soaking time of the sample, and simultaneously needs to prepare the alkali solution, the treatment of the waste alkali is more complicated, and the environment is easily polluted by the flushing wastewater.

Disclosure of Invention

The invention aims to provide a carbon surface coating treatment device for non-oriented silicon steel, which has high automation degree and overcomes the defects of the prior art.

The technical scheme adopted by the invention is as follows: a treatment device for a non-oriented silicon steel surface coating comprises a machine body shell and a main structure arranged in the machine body shell, wherein a power indicator lamp and a switch control button are arranged on the machine body shell; the main structure comprises a sample fixing system, a sample polishing system and an equipment control unit, wherein the sample fixing system, the sample polishing system, a power indicator lamp and a switch control button are respectively connected with the equipment control unit.

According to the scheme, the sample fixing system comprises a sample fixing structural part and a cylinder A, a sample groove used for placing a sample is formed in the front end of the sample fixing structural part, the sample groove stretches out of the engine body shell, the cylinder A is arranged above the sample groove, a push rod of the cylinder A is provided with a pressure head, and the pressure head is downward opposite to the sample groove.

According to the scheme, the sample polishing system comprises a cylinder B, a grinder fixing seat, a grinder and rollers, wherein a push rod of the cylinder B is connected with the front end of the grinder fixing seat, the bottom surface of the front end of the grinder fixing seat is in contact with the rollers, the rear end of the grinder fixing seat is hinged to a cylinder supporting seat, and the cylinder supporting seat is arranged on a bottom plate of the machine body shell; the roller is arranged at the top of the roller seat, and the roller seat is fixed on the sample fixing structural part; the abrasive belt on the driven belt wheel can be in contact with the upper surface of a sample placed in the sample groove.

According to the above scheme, processing apparatus still includes the dust collection system, and the dust collection system includes dust discharge pipe and dust catcher, the front end of dust discharge pipe links to each other with sample fixed structure spare, and the rear end of dust discharge pipe links to each other with the dust catcher.

According to the scheme, the sample fixing system further comprises a sliding assembly, wherein the sliding assembly comprises a cylinder C, a sliding block and a sliding rail, and the cylinder C is located below the sample groove and fixed at the inner bottom of the machine body shell; a push rod of the cylinder C is connected with the outer side of the sample fixing structural part; the sliding rail is fixed below the sample groove, the length direction of the sliding rail is the same as the axial direction of the sample fixing structural part, the sliding block is installed on the sliding rail in a sliding mode, and the bottom of the sliding block is connected with the air cylinder C; when the cylinder C starts, the push rod of the cylinder C pushes the sample fixing structural part to move along the axis direction, and meanwhile, the slide rail is driven to move, and the slide block and the slide rail slide relatively.

According to the scheme, the sample polishing system further comprises a translation assembly, the translation assembly comprises a cylinder D, a moving block and a guide rail, the cylinder D is fixed on a cylinder supporting seat, and a push rod of the cylinder D is connected with the outer side of the rear end of a grinder fixing seat; the moving block is arranged at the bottom of the cylinder B and matched with the guide rail, the guide rail is fixed at the inner bottom of the machine body shell, and the length direction of the guide rail is the same as the telescopic direction of the cylinder D.

According to the scheme, a connecting rod B penetrates through the air cylinder supporting seat; the inner end of the connecting rod B is arranged on the side surface of the fixed structural part of the abrasive belt machine, the outer end of the connecting rod B is sleeved with a compression spring, and the end head of the outer end of the connecting rod B is provided with a spring fixing clamping sleeve.

According to the scheme, the whole body of the machine body shell is rectangular, and four corners of the outer bottom of the machine body shell are provided with a ground foot respectively.

The invention has the beneficial effects that:

1. the coating treatment device comprises the abrasive belt machine, and is combined with a plurality of groups of cylinders, and the coating on the surface of the sample is polished by using a mechanical polishing mode; alkali liquor does not need to be specially prepared and the reaction time is not controlled, so that the manual interference is less, and the coating is removed more uniformly;

2. the dust collecting system is designed, dust generated in the polishing process can be automatically pumped, the environmental pollution is reduced, and the working environment of operators is ensured;

3. the invention has the advantages of simple and convenient sample preparation, high speed, good feasibility and high reliability.

Drawings

FIG. 1 is a general schematic diagram of one embodiment of the present invention.

Fig. 2 is a first schematic internal structure diagram of the present embodiment.

Fig. 3 is a rear view of fig. 2.

Fig. 4 is a right side view of fig. 2.

Fig. 5 is a top view of fig. 2.

Wherein: 1. a body housing; 2. a power indicator light; 3. a switch button; 4. a sample; 5. a base plate; 6. a cylinder C; 7. a sample fixing structure; 8. a slider; 9. a slide rail; 10. a support frame; 11. a cylinder A; 12. a pressure head; 13. a guide rail; 14. a moving block; 15. a cylinder B; 16. a universal head link; 17. a roller seat; 18. a roller; 19. a cylinder supporting seat; 20. a cylinder D; 21. a belt sander fixing seat; 22. an abrasive belt machine; 23. an abrasive belt; 24. a connecting rod A; 25. a connecting rod B; 26. a compression spring; 27. the spring fixes the cutting sleeve; 28. a dust discharge pipe; 29. and (5) ground feet.

Detailed Description

For a better understanding of the present invention, reference is made to the following detailed description taken in conjunction with the accompanying drawings.

As shown in fig. 1, the device for treating the surface coating of the non-oriented silicon steel consists of a machine body shell 1 and a main structure arranged in the machine body shell 1, wherein the machine body shell 1 is provided with a power indicator lamp 2 and a switch control button 3; as shown in fig. 2 to 5, the main structure includes a sample fixing system, a sample polishing system and an equipment control unit, the sample fixing system, the sample polishing system, the power indicator 2 and the switch control button 3 are respectively connected with the equipment control unit, wherein the sample fixing system includes a sample fixing structural member 7 and a cylinder a11, a sample groove for placing a sample 4 is provided at the front end of the sample fixing structural member 7 (the length direction of the sample groove is the same as the axial direction of the sample fixing structural member 7), the front end of the sample groove extends out of the machine body shell 1 (an operator can directly place the sample 4 into the sample groove at the outside), a support frame 10 is installed on the sample fixing structural member 7, a cylinder a11 is provided on the support frame 10, a push rod of the cylinder a11 is provided with a pressure head 12, and the pressure head 12 faces the sample groove downwards; the sample polishing system comprises a cylinder B15, a grinder fixing seat 21, a grinder 22 (which can be a pneumatic grinder) and a roller 18, wherein a push rod of the cylinder B15 is connected with the lower end of a connecting rod 16, the upper end of the connecting rod 16 is hinged with a connecting rod A24, the connecting rod A24 is arranged at the front end of the grinder fixing seat 21, the bottom surface of the front end of the grinder fixing seat 21 is in contact with the roller 18, the rear end of the grinder fixing seat 21 is hinged on a cylinder supporting seat 19, and the cylinder supporting seat 19 is arranged on a bottom plate 5; the roller 18 is arranged at the top of the roller seat 17, and the roller seat 17 is fixed on the sample fixing structural part 7; the grinder 22 comprises a driving belt wheel, a driven belt wheel and an abrasive belt, the abrasive belt is wound between the driving belt wheel and the driven belt wheel, a belt wheel shaft of the driving belt wheel is arranged at the rear end of the grinder fixing seat 21, and the abrasive belt on the driven belt wheel can be in contact with the upper surface of the sample 4 placed in the sample groove.

Preferably, the processing apparatus further comprises a dust collection system including a dust discharge pipe 28 and a vacuum cleaner, the front end of the dust discharge pipe 28 is connected to the sample fixing structure 7, and the rear end of the dust discharge pipe 28 is connected to the vacuum cleaner.

Preferably, the sample fixing system further comprises a sliding assembly, wherein the sliding assembly comprises a cylinder C6, a slide block 8 and a slide rail 9, the cylinder C6 is positioned below the sample groove and is fixed at the inner bottom of the machine body shell 1; a push rod of the air cylinder C6 is connected with the outer side of the sample fixing structural part 7; the slide rail 9 is fixed below the sample groove, the length direction of the slide rail 9 is the same as the axial direction of the sample fixing structural part 7, the slide block 8 is slidably mounted on the slide rail 9, and the bottom of the slide block 8 is connected with the cylinder body of the cylinder C6; when the cylinder C6 is started, the sample fixing structural member 7 is pushed to move along the axial direction, and simultaneously the slide rail 9 is driven to move, and the slide block 8 and the slide rail 9 slide relatively.

Preferably, the sample polishing system further comprises a translation assembly, the translation assembly comprises an air cylinder D20, a moving block 14 and a guide rail 13, the air cylinder D20 is fixed on the air cylinder supporting seat 19, and a push rod of the air cylinder D20 is connected with the outer side of the rear end of the grinder fixing seat 21; the moving block 14 is arranged at the bottom of the cylinder B15, the moving block 14 is matched with the guide rail 13, the guide rail 13 is fixed at the inner bottom of the machine body shell 1, and the length direction of the guide rail 13 is the same as the expansion direction of the cylinder D20.

Preferably, a connecting rod B25 passes through the cylinder support seat 19, and the connecting rod B25 can rotate in a hole of the cylinder support seat 19; the inner end of the connecting rod B25 is installed on the side surface of the fixed structural part 21 of the belt sander, the outer end of the connecting rod B25 is sleeved with a compression spring 26, and the outer end of the connecting rod B25 is provided with a spring fixing clamping sleeve 27 to prevent the compression spring 26 from falling off.

Preferably, the machine body shell 1 is rectangular as a whole, and four corners of the outer bottom of the machine body shell 1 are respectively provided with a ground pin 29.

In the invention, the cylinder A11, the cylinder B15, the cylinder C6 and the cylinder D20 are respectively connected with an equipment control unit, and the operation of each cylinder is controlled by the equipment control unit.

The working principle of the invention is as follows: as shown in fig. 3, the sample 4 is placed in the sample groove of the sample fixing structure 7, and then the switch knob 3 is pressed, and the apparatus control unit controls the operation of each cylinder. The invention mainly comprises the following processes:

1. the test piece 4 moves laterally in the axial direction of the test piece fixing structure 7.

When the air cylinder A11 is started, the push rod of the air cylinder A11 drives the pressure head 12 to press the sample 4; when the air cylinder C6 is started, the push rod of the air cylinder C6 pushes the sample fixing structural part 7, so that the slide rail 9 which is matched and installed on the sample fixing structural part 7 and the slide block 8 slide relatively.

2. The abrasive belt 23 is moved transversely in the direction of the axis of the sample-holding structure 7.

The push rod of the air cylinder B15 drives the connecting rod 16 connected with the air cylinder B15 to only do downward pulling action, and the connecting rod 16 enables the end of the belt sander fixed structural part 21 to be pulled downward through the connecting rod A24; a push rod of the air cylinder C6 pushes the sample fixing structural part 7 to enable the roller 18 to move backwards, and the bottom surface cambered surface of the belt sander fixing structural part 21 moves along the roller 18; because the connecting rod B25 can rotate in the hole on the cylinder supporting seat 19, the head of the belt sander 22 installed in the round hole of the belt sander fixing seat 21 faces downwards; the belt sander 22 nose is lowered to bring the sanding belt 23 on the driven wheel into contact with the surface of the test sample 4 to begin sanding the surface coating of the test sample 4. A push rod of the cylinder C6 pushes the sample fixing structural part 7 to reciprocate along the axial direction, and the abrasive belt 23 polishes the surface coating of the sample 4 in a reciprocating manner along the axial direction; when cylinder C6 push rod moves sample holding structure 7 back to the top, sanding belt 23 stops sanding with its sanding surface away from the surface of sample 4.

3. The abrasive belt 23 is moved longitudinally in a direction perpendicular to the axis of the sample-holding structure 7.

The device control unit controls the push rod of the air cylinder D20 to push forwards, the belt sander fixing seat 21 drives the belt sander 22 to move in parallel (perpendicular to the axial direction of the sample fixing structural part 7), and the air cylinder A15 is matched with the moving block 14 to slide along the guide rail 13; when the push rod of the air cylinder D20 retracts, the belt sander 22 moves back under the action of the compression spring 26, the air cylinder A15 moves back along the moving block 13, and the abrasive belt 23 is driven to grind longitudinally (perpendicular to the axial direction of the sample fixing structural component 7) on the surface of the sample 4; after the equipment control unit controls the number of times of reciprocating polishing, the air cylinder C6 moves back to the top point, the polishing of the sand surface of the abrasive belt 23 is stopped when the sand surface is separated from the surface of the sample 4, and the abrasive belt machine 22 rotates.

And after the upper surface of the sample 4 is polished, taking out the sample, turning over the sample, and polishing the other surface of the sample.

It should be noted that the above-mentioned embodiments are only preferred embodiments of the present invention, and the present invention is not limited thereto, and although the present invention has been described in detail with reference to the embodiments, it will be apparent to those skilled in the art that modifications can be made to the technical solutions described in the above-mentioned embodiments, or equivalent substitutions of some technical features, but any modifications, equivalents, improvements and the like within the spirit and principle of the present invention shall be included in the protection scope of the present invention.

Claims

1. A device for treating a non-oriented silicon steel surface coating is characterized by comprising a machine body shell and a main structure arranged in the machine body shell, wherein a power indicator lamp and a switch control button are arranged on the machine body shell; the main structure comprises a sample fixing system, a sample polishing system and an equipment control unit, wherein the sample fixing system, the sample polishing system, a power indicator lamp and a switch control button are respectively connected with the equipment control unit; the sample fixing system comprises a sample fixing structural part and a cylinder A, wherein a sample groove for placing a sample is formed in the front end of the sample fixing structural part, the sample groove extends out of the machine body shell, the cylinder A is arranged above the sample groove, a push rod of the cylinder A is provided with a pressure head, and the pressure head is downwards opposite to the sample groove; the sample polishing system comprises a cylinder B, a grinder fixing seat, a grinder and rollers, wherein a push rod of the cylinder B is connected with the front end of the grinder fixing seat, the bottom surface of the front end of the grinder fixing seat is in contact with the rollers, the rear end of the grinder fixing seat is hinged to a cylinder supporting seat, and the cylinder supporting seat is arranged on a bottom plate of the machine body shell; the roller is arranged at the top of the roller seat, and the roller seat is fixed on the sample fixing structural part; the grinding machine comprises a driving belt wheel, a driven belt wheel and an abrasive belt, the abrasive belt is wound between the driving belt wheel and the driven belt wheel, a belt wheel shaft of the driving belt wheel is arranged at the rear end of a grinding machine fixing seat, and the abrasive belt on the driven belt wheel can be in contact with the upper surface of a sample placed in a sample groove; the sample polishing system further comprises a translation assembly, the translation assembly comprises a cylinder D, a moving block and a guide rail, the cylinder D is fixed on a cylinder supporting seat, and a push rod of the cylinder D is connected with the outer side of the rear end of the grinding machine fixing seat; the moving block is arranged at the bottom of the cylinder B, the moving block is matched with the guide rail, the guide rail is fixed at the inner bottom of the machine body shell, and the length direction of the guide rail is the same as the telescopic direction of the cylinder D; the sample fixing system also comprises a sliding assembly, wherein the sliding assembly comprises a cylinder C, a sliding block and a sliding rail, and the cylinder C is positioned below the sample groove and fixed at the inner bottom of the machine body shell; a push rod of the cylinder C is connected with the outer side of the sample fixing structural part; the sliding rail is fixed below the sample groove, the length direction of the sliding rail is the same as the axial direction of the sample fixing structural part, the sliding block is installed on the sliding rail in a sliding mode, and the bottom of the sliding block is connected with the air cylinder C; when the cylinder C starts, the push rod of the cylinder C pushes the sample fixing structural part to move along the axis direction, and meanwhile, the slide rail is driven to move, and the slide block and the slide rail slide relatively.

2. The apparatus for treating surface coating of non-oriented silicon steel as set forth in claim 1, further comprising a dust collecting system including a dust discharging pipe and a dust collector, wherein a front end of the dust discharging pipe is connected to the sample fixing structure, and a rear end of the dust discharging pipe is connected to the dust collector.

3. The apparatus for treating surface coating of non-oriented silicon steel as set forth in claim 1, wherein a connecting rod is passed through the supporting base; the inner end of the connecting rod is arranged on the side surface of the fixed structural part of the belt sander, the outer end of the connecting rod is sleeved with a compression spring, and the end head of the outer end of the connecting rod is provided with a spring fixing clamping sleeve.

4. The apparatus for treating surface coating of non-oriented silicon steel as set forth in claim 1, wherein the body case has a rectangular shape as a whole, and four corners of an outer bottom of the body case are provided with a foot, respectively.