CN210140731U - Energy-saving hot cutting machine for producing regenerated plastic woven bags - Google Patents

Abstract

The utility model discloses a production of recycled plastic braided bag is with energy-conserving earnestly machine belongs to braided bag production technical field. The cutting machine comprises a shell, a first air cylinder, a heat insulation plate, an electric heating plate, a heat conduction plate, a blade, a bolt, a second air cylinder, a first pressing plate, a third air cylinder, a second pressing plate, a first conveying belt mechanism, a second conveying belt mechanism, a fixing column and a cutting table; the right side wall of the heat conducting plate is provided with a threaded hole, the bottom wall of the heat conducting plate is provided with a groove, and the left end of the threaded hole is communicated with the right side wall of the groove; a connecting column is fixed at the top of the blade, a through hole is formed in the side wall of the connecting column, the connecting column is filled in the groove, a bolt is in threaded fit with the threaded hole, and the left end of the bolt penetrates through the through hole; the cutting table is positioned right below the blade; first conveyer belt mechanism, second conveyer belt mechanism are located the left and right sides of fixed column respectively, the utility model discloses be convenient for change the blade, cutting effect is good.

Description

Energy-saving hot cutting machine for producing regenerated plastic woven bags

Technical Field

The utility model relates to a braided bag production technical field, more specifically relates to a production of recycled plastic braided bag is with energy-conserving earnestly machine.

Background

A thermal cutting machine is a mechanical device that uses concentrated heat energy to melt and separate materials. Thermal cutting can be classified into gas cutting, electric arc cutting, plasma arc cutting, laser cutting, etc. according to the kind of heat energy used. The hot cutting machine is indispensable in the work of blanking, part processing, waste and scrap disassembly, installation and removal of metal materials in the industrial sector.

The woven bag, also called snakeskin bag, is one kind of plastic bag for packing, and its material is polyethylene, polypropylene and other chemical plastic material. In the in-process of weaving bag processing production, its corner generally all can produce deckle edge, in order to guarantee later stage lines off-line, improves the quality of braided bag, so all can get rid of the deckle edge, but the blade generally all is the installation fixed, leads to not being convenient for the later stage to dismantle it and get off to maintain.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to solve the technical problem of providing an energy-saving hot cutting machine for producing regenerated plastic woven bags, which is convenient for replacing blades and has good cutting effect.

To achieve the purpose, the utility model adopts the following technical proposal:

the utility model provides an energy-saving hot cutting machine for producing regenerated plastic woven bags, which comprises a shell, a first cylinder, a heat insulation plate, an electric heating plate, a heat conduction plate, a blade, a bolt, a second cylinder, a first pressing plate, a third cylinder, a second pressing plate, a first conveying belt mechanism, a second conveying belt mechanism, a fixed column and a cutting table;

the first cylinder, the heat insulation plate, the electric heating plate, the heat conduction plate, the blade, the bolt, the second cylinder, the first pressing plate, the third cylinder, the second pressing plate, the first conveying belt mechanism, the second conveying belt mechanism, the fixed column and the cutting table are all positioned in the shell;

the first air cylinder is fixed on the inner top wall of the shell, a telescopic shaft of the first air cylinder is fixedly connected with the upper surface of the heat insulation plate, the lower surface of the heat insulation plate is fixedly connected with the upper surface of the electric heating plate, and the lower surface of the electric heating plate is fixedly connected with the upper surface of the heat conduction plate;

the right side wall of the heat conducting plate is provided with a threaded hole, the bottom wall of the heat conducting plate is provided with a groove, and the left end of the threaded hole is communicated with the right side wall of the groove;

a connecting column is fixed at the top of the blade, a through hole is formed in the side wall of the connecting column, the connecting column is filled in the groove, the bolt is in threaded fit with the threaded hole, and the left end of the bolt penetrates through the through hole;

the fixed column is vertically fixed on the inner bottom wall of the shell, the cutting table is fixed at the upper end of the fixed column, and the cutting table is located right below the blade;

the second cylinder and the third cylinder are fixed on the inner top wall of the shell and are respectively positioned on the left side and the right side of the first cylinder;

the telescopic shaft of the second air cylinder is fixedly connected with the top wall of the first pressure plate, and the telescopic shaft of the third air cylinder is fixedly connected with the top wall of the second pressure plate;

the first conveying belt mechanism and the second conveying belt mechanism are respectively positioned at the left side and the right side of the fixed column, the first pressing plate is positioned above the first conveying belt mechanism, and the second pressing plate is positioned above the second conveying belt mechanism;

a discharge port and a feed port are respectively formed in the left side wall and the right side wall of the shell, and the discharge port and the feed port are respectively positioned on the left side of the first conveying belt mechanism and the right side of the second conveying belt mechanism;

the bottom of the shell is fixed with the roller, and the outer wall of the shell is fixed with the heat preservation layer.

Optionally, the first conveyor belt mechanism includes a first motor, a first belt, a first drive roller, and a first drive roller;

the power transmission end of the first motor is fixed to the first driving roller and fixedly connected with the first driving roller, the first driving roller is pivoted on the inner wall of the shell, the first driving roller is located on the right side of the first driving roller, and the belt is sleeved on the first driving roller and the first driving roller;

the second conveying belt mechanism comprises a second motor, a second belt, a second driving roller and a second transmission roller;

the power output end of the second motor is fixed to the second driving roller in fixed connection, the second driving roller is pivoted to the inner wall of the shell, the second driving roller is located on the right side of the second driving roller, and the belt is sleeved on the second driving roller and the second driving roller.

Optionally, a third motor is fixed on the inner wall of the housing;

the third motor is positioned above the second driving roller, and a compression roller is fixed at the power output end of the third motor.

Optionally, the lower surface of the first pressure plate and the lower surface of the second pressure plate are both fixed with an elastic plate.

Optionally, a first buffer spring, a second buffer spring and a third buffer spring are respectively sleeved on the telescopic shaft of the first cylinder, the telescopic shaft of the second cylinder and the telescopic shaft of the third cylinder;

the upper end and the lower end of the first buffer spring are respectively fixed at the bottom of the first cylinder and the upper surface of the heat insulation plate;

the upper end and the lower end of the second buffer spring are respectively fixed at the bottom of the second cylinder and the upper surface of the first pressing plate;

and the upper end and the lower end of the third buffer spring are respectively fixed at the bottom of the third cylinder and the upper surface of the second pressing plate.

The utility model has the advantages that:

the utility model discloses a telescopic shaft of first cylinder drives the blade and is fixed with heat insulating board, electric plate and heat-conducting plate to the lines cutting of braided bag between telescopic shaft of first cylinder and the blade. The electric heating plate is started to heat, and heat is conducted to the blade through the heat conducting plate, so that hot cutting is realized, and the cutting is efficient and rapid. Be fixed with the spliced pole of through-hole on the blade, the spliced pole is filled in the recess of heat-conducting plate, and the screw hole threaded connection through bolt and heat-conducting plate just runs through the through-hole and realizes the joint to the spliced pole to realize the locking to the blade, accessible bolt and screw hole cooperation are dismantled the blade, are convenient for maintain and change, are equipped with the second cylinder in addition, the third cylinder drives first clamp plate respectively, the second clamp plate compresses tightly the braided bag, improves the cutting quality.

Drawings

FIG. 1 is a schematic structural view of an energy-saving thermal cutting machine for producing a regenerated plastic woven bag according to an embodiment of the present invention;

fig. 2 is a schematic view of a partially enlarged structure of an energy-saving thermal cutting machine for producing a regenerative plastic woven bag according to an embodiment of the present invention.

In the figure:

1. a housing; 2. a first cylinder; 3. a heat insulation plate; 4. an electric hot plate; 5. a heat conducting plate; 6. a blade; 7. a bolt; 8. a second cylinder; 9. a first platen; 10. a third cylinder; 11. a second platen; 12. a first conveyor belt mechanism; 13. a second conveyor belt mechanism; 14. fixing a column; 15. cutting table; 16. a threaded hole; 17. A groove; 18. connecting columns; 19. a through hole; 20. a discharge port; 21. a feed inlet; 22. a heat-insulating layer; 23. A first motor; 24. a first belt; 25. a first drive roll; 26. a first drive roller; 27. a second motor; 28. a second belt; 29. a second drive roll; 30. a second driving roller; 31. a third motor; 32. a compression roller; 33. a first buffer spring; 34. a second buffer spring; 35. and a third buffer spring.

Detailed Description

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

FIG. 1 schematically shows a schematic structural view of an energy-saving thermal cutting machine for producing a regenerated plastic woven bag, according to the present invention; fig. 2 exemplarily shows a partially enlarged structural schematic diagram of an energy-saving thermal cutting machine for producing a regenerative plastic woven bag provided by the present invention. As shown in fig. 1 and 2, an energy-saving thermal cutting machine for producing a regenerated plastic woven bag comprises a shell 1, a first cylinder 2, a thermal insulation plate 3, an electric heating plate 4, a thermal conduction plate 5, a blade 6, a bolt 7, a second cylinder 8, a first pressing plate 9, a third cylinder 10, a second pressing plate 11, a first conveying belt mechanism 12, a second conveying belt mechanism 13, a fixed column 14 and a cutting table 15; the first air cylinder 2, the heat insulation plate 3, the electric heating plate 4, the heat conduction plate 5, the blade 6, the bolt 7, the second air cylinder 8, the first pressing plate 9, the third air cylinder 10, the second pressing plate 11, the first conveying belt mechanism 12, the second conveying belt mechanism 13, the fixing column 14 and the cutting table 15 are all positioned in the shell 1; the first air cylinder 2 is fixed on the inner top wall of the shell 1, a telescopic shaft of the first air cylinder 2 is fixedly connected with the upper surface of the heat insulation plate 3, the lower surface of the heat insulation plate 3 is fixedly connected with the upper surface of the electric heating plate 4, and the lower surface of the electric heating plate 4 is fixedly connected with the upper surface of the heat conduction plate 5; a threaded hole 16 is formed in the right side wall of the heat conducting plate 5, a groove 17 is formed in the bottom wall of the heat conducting plate 5, and the left end of the threaded hole 16 is communicated with the right side wall of the groove 17; a connecting column 18 is fixed at the top of the blade 6, a through hole 19 is formed in the side wall of the connecting column 18, the connecting column 18 is filled in the groove 17, the bolt 7 is in threaded fit with the threaded hole 16, and the left end of the bolt 7 penetrates through the through hole 19; the fixed column 14 is vertically fixed on the inner bottom wall of the shell 1, the cutting table 15 is fixed at the upper end of the fixed column 14, and the cutting table 15 is positioned under the blade 6; the second cylinder 8 and the third cylinder 10 are both fixed on the inner top wall of the shell 1, and the second cylinder 8 and the third cylinder 10 are respectively positioned at the left side and the right side of the first cylinder 2; the telescopic shaft of the second air cylinder 8 is fixedly connected with the top wall of the first pressure plate 9, and the telescopic shaft of the third air cylinder 10 is fixedly connected with the top wall of the second pressure plate 11; the first conveying belt mechanism 12 and the second conveying belt mechanism 13 are respectively positioned at the left side and the right side of the fixed column 14, the first pressing plate 9 is positioned above the first conveying belt mechanism 12, and the second pressing plate 11 is positioned above the second conveying belt mechanism 13; a discharge port 20 and a feed port 21 are respectively arranged on the left side wall and the right side wall of the shell 1, and the discharge port 20 and the feed port 21 are respectively positioned on the left side of the first conveying belt mechanism 12 and the right side of the second conveying belt mechanism 13; the bottom of the shell 1 is fixed with rollers, and the outer wall of the shell 1 is fixed with a heat-insulating layer 22.

The woven bags to be cut are put in through the feeding hole 21, the first motor 23 and the second motor 27 are started, the power output end of the first motor 23 drives the first belt 24 to slide through the first driving roller 26, and the power output end of the second motor 27 drives the second belt 28 to slide through the second driving roller 30. First belt 24, second belt 28 is counter-clockwise turning, consequently, the braided bag conveys to the upper surface of cutting bed 15 through second belt 28 earlier, cutting bed 15 top sets up wide narrow down, and the right-hand member of first belt 24 is pressed close to at both ends about cutting bed 15 top, the left end of second belt 28, be convenient for receive the braided bag of conveying, when the braided bag is located cutting bed 15, pause first motor 23 and the work of second motor 27, start second cylinder 8, third cylinder 10, the telescopic shaft of second cylinder 8 drives first clamp plate 9, the telescopic shaft of third cylinder 10 drives the one end of second clamp plate 11 decline to the braided bag and compresses tightly, it is protruding to avoid the braided bag to slide. The telescopic shaft of first cylinder 2 descends, starts the heating of electric plate 4, and electric plate 4 is to make the material that generates heat with electric heating alloy silk, makes insulating material with the mica soft board, and the outsourcing carries out the equipment that heats with aluminum plate, makes electric plate 4 generate heat through the circular telegram, makes blade 6 generate heat after 5 heat conduction through the heat-conducting plate to make the blade 6 that generate heat descend to the braided bag cutting, realize the hot cutting. The blade 6 can be locked by the threaded fit of the bolt 7 with the threaded hole 16 and by the insertion of the right end of the bolt 7 into the through hole 19 of the connecting post 18. After the telescopic shaft of the first cylinder 2, the telescopic shaft of the second cylinder 8 and the telescopic shaft of the third cylinder 10 rise, the first motor 23 and the second motor 27 are started. So that the cut woven bags continue to be conveyed through the first belt 24 and finally are discharged through the discharge port 20. The blade is convenient to detach due to the threaded fit, and the maintenance and the replacement of the blade are facilitated. The insulating panel 3 may be made of an insulating aluminium alloy material having a low thermal conductivity. The heat conducting plate 5 can be made of a copper material, which has good thermal conductivity. The heat preservation layer 22 prevents heat loss in the shell 1, is beneficial to heat preservation of the blade 6 and reduces heat loss. The insulation layer 22 may be made of insulation cotton material. The first cylinder 2, the second cylinder 8 and the third cylinder 10 can be selected from SC standard double-acting cylinders, and the cylinders are good in reliability and stable in buffer adjustment. If not specifically stated, the above fixed connection can be a welded connection.

Optionally, the first conveyor belt mechanism 12 includes a first motor 23, a first belt 24, a first drive roller 25, and a first drive roller 26; the power transmission end of the first motor 23 is fixed on a first driving roller 25 and fixedly connected, the first driving roller 26 is pivoted on the inner wall of the shell 1, the first driving roller 25 is positioned on the right side of the first driving roller 26, and the belt is sleeved on the first driving roller 25 and the first driving roller 26; the second conveyor belt mechanism 13 comprises a second motor 27, a second belt 28, a second driving roller 29 and a second driving roller 30; the power transmission end of the second motor 27 is fixed to the second driving roller 29 and is fixedly connected with the second driving roller 30, the second driving roller 30 is pivoted on the inner wall of the shell 1, the second driving roller 29 is located on the right side of the second driving roller 30, and the belt is sleeved on the second driving roller 29 and the second driving roller 30. The first motor 23 provides a rotational power to the first driving roller 25 to slide the first belt 24, and the second motor 27 provides a rotational power to the second driving roller 29 to slide the second belt 28. Asynchronous motors can be selected from the first motor 23 and the second motor 27, the asynchronous motors have the advantages of being low in manufacturing cost and high in reliability, and the woven bags can be conveyed more stably through belt transmission. SC standard double acting type air cylinders can be selected as the first air cylinder 2, the second air cylinder 8 and the third air cylinder 10, and the air cylinders are good in reliability and stable in buffering adjustment. The above-mentioned fixed connection may be a welded connection, unless otherwise specified.

Optionally, a third motor 31 is fixed on the inner wall of the housing 1; the third motor 31 is positioned above the second driving roller 29, and a pressure roller 32 is fixed at the power output end of the third motor 31. Set up compression roller 32 and do benefit to the braided bag that needs the cutting and carry out spacing flattening, avoid the braided bag to place and cross the wrinkle arch on second belt 27 and make the cutting inaccurate.

Optionally, an elastic plate is fixed to both the lower surface of the first pressing plate 9 and the lower surface of the second pressing plate 11. Set up the elastic plate and can effectively protect first clamp plate 9, second clamp plate 11, the telescopic shaft of avoiding second cylinder 8 to drive first clamp plate 9, third cylinder 10 strikes first belt 24, second belt 28 and makes first belt 24, second belt 28 damage when driving second clamp plate 11 and descend. The lower surface of first clamp plate 9, the lower surface and the elastic plate of second clamp plate 11, casing 1 outer wall and heat preservation 22 all can bond through the epoxy adhesive, and this adhesive is connected stably, and the heat resistance is good.

Optionally, the telescopic shaft of the first cylinder 2, the telescopic shaft of the second cylinder 8, and the telescopic shaft of the third cylinder 10 are respectively sleeved with a first buffer spring 33, a second buffer spring 34, and a third buffer spring 35; the upper end and the lower end of the first buffer spring 33 are respectively fixed at the bottom of the first cylinder 2 and the upper surface of the heat insulation plate 3; the upper end and the lower end of the second buffer spring 34 are respectively fixed at the bottom of the second cylinder 8 and the upper surface of the first pressing plate 9; the upper end and the lower end of the third buffer spring 35 are respectively fixed to the bottom of the third cylinder 10 and the upper surface of the second pressing plate 11. The impact generated when the telescopic shafts of the first cylinder 2, the second cylinder 8 and the third cylinder 10 move can be effectively buffered by arranging the first buffer spring 33, the second buffer spring 34 and the third buffer spring 35, and the first cylinder 2, the second cylinder 8 and the third cylinder 10 are effectively protected.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the spirit and scope of the invention. The present invention is not to be limited by the specific embodiments disclosed herein, and other embodiments that fall within the scope of the claims of the present application are intended to be within the scope of the present invention.

Claims (5)

1. The utility model provides a production of recycled plastic woven sack is with energy-conserving earnestly machine which characterized in that:

the cutting machine comprises a shell (1), a first cylinder (2), a heat insulation plate (3), an electric heating plate (4), a heat conduction plate (5), a blade (6), a bolt (7), a second cylinder (8), a first pressing plate (9), a third cylinder (10), a second pressing plate (11), a first conveying belt mechanism (12), a second conveying belt mechanism (13), a fixing column (14) and a cutting table (15);

the first air cylinder (2), the heat insulation plate (3), the electric heating plate (4), the heat conduction plate (5), the blade (6), the bolt (7), the second air cylinder (8), the first pressing plate (9), the third air cylinder (10), the second pressing plate (11), the first conveying belt mechanism (12), the second conveying belt mechanism (13), the fixed column (14) and the cutting table (15) are all located in the shell (1);

the first air cylinder (2) is fixed on the inner top wall of the shell (1), a telescopic shaft of the first air cylinder (2) is fixedly connected with the upper surface of the heat insulation plate (3), the lower surface of the heat insulation plate (3) is fixedly connected with the upper surface of the electric heating plate (4), and the lower surface of the electric heating plate (4) is fixedly connected with the upper surface of the heat conduction plate (5);

a threaded hole (16) is formed in the right side wall of the heat conducting plate (5), a groove (17) is formed in the bottom wall of the heat conducting plate (5), and the left end of the threaded hole (16) is communicated with the right side wall of the groove (17);

a connecting column (18) is fixed to the top of the blade (6), a through hole (19) is formed in the side wall of the connecting column (18), the connecting column (18) is filled in the groove (17), the bolt (7) is in threaded fit with the threaded hole (16), and the left end of the bolt (7) penetrates through the through hole (19);

the fixed column (14) is vertically fixed on the inner bottom wall of the shell (1), the cutting table (15) is fixed at the upper end of the fixed column (14), and the cutting table (15) is positioned right below the blade (6);

the second cylinder (8) and the third cylinder (10) are fixed on the inner top wall of the shell (1), and the second cylinder (8) and the third cylinder (10) are respectively positioned on the left side and the right side of the first cylinder (2);

the telescopic shaft of the second air cylinder (8) is fixedly connected with the top wall of the first pressing plate (9), and the telescopic shaft of the third air cylinder (10) is fixedly connected with the top wall of the second pressing plate (11);

the first conveying belt mechanism (12) and the second conveying belt mechanism (13) are respectively positioned at the left side and the right side of the fixed column (14), the first pressing plate (9) is positioned above the first conveying belt mechanism (12), and the second pressing plate (11) is positioned above the second conveying belt mechanism (13);

a discharge port (20) and a feed port (21) are respectively formed in the left side wall and the right side wall of the shell (1), and the discharge port (20) and the feed port (21) are respectively positioned on the left side of the first conveying belt mechanism (12) and the right side of the second conveying belt mechanism (13);

the bottom of the shell (1) is fixed with rollers, and the outer wall of the shell (1) is fixed with a heat-insulating layer (22).

2. The energy-saving heat cutting machine for producing regenerated plastic woven bags according to claim 1, characterized in that:

the first conveying belt mechanism (12) comprises a first motor (23), a first belt (24), a first driving roller (25) and a first driving roller (26);

the power transmission end of the first motor (23) is fixed to the first driving roller (25) and fixedly connected with the first driving roller (25), the first driving roller (26) is pivoted to the inner wall of the shell (1), the first driving roller (25) is located on the right side of the first driving roller (26), and the belt is sleeved on the first driving roller (25) and the first driving roller (26);

the second conveying belt mechanism (13) comprises a second motor (27), a second belt (28), a second driving roller (29) and a second transmission roller (30);

the power output end of the second motor (27) is fixed on the second driving roller (29) in fixed connection, the second driving roller (30) is pivoted on the inner wall of the shell (1), the second driving roller (29) is located on the right side of the second driving roller (30), and the belt is sleeved on the second driving roller (29) and the second driving roller (30).

3. The energy-saving heat cutting machine for producing regenerated plastic woven bags according to claim 2, characterized in that:

a third motor (31) is fixed on the inner wall of the shell (1);

the third motor (31) is positioned above the second driving roller (29), and a pressure roller (32) is fixed at the power output end of the third motor (31).

4. The energy-saving heat cutting machine for producing regenerated plastic woven bags according to claim 1, characterized in that:

elastic plates are fixed on the lower surfaces of the first pressing plate (9) and the second pressing plate (11).

5. The energy-saving heat cutting machine for producing regenerated plastic woven bags according to claim 1, characterized in that:

a telescopic shaft of the first cylinder (2), a telescopic shaft of the second cylinder (8) and a telescopic shaft of the third cylinder (10) are respectively sleeved with a first buffer spring (33), a second buffer spring (34) and a third buffer spring (35);

the upper end and the lower end of the first buffer spring (33) are respectively fixed at the bottom of the first cylinder (2) and the upper surface of the heat insulation plate (3);

the upper end and the lower end of the second buffer spring (34) are respectively fixed at the bottom of the second cylinder (8) and the upper surface of the first pressing plate (9);

the upper end and the lower end of the third buffer spring (35) are respectively fixed to the bottom of the third air cylinder (10) and the upper surface of the second pressing plate (11).

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