CN113579209A - Tool bit capable of not scratching extruded surface object and manufacturing device - Google Patents

Abstract

The invention relates to a cutter head without scratching extruded surface objects and a manufacturing device, comprising an equipment shell and an alloy casting component, wherein the lower end inside the equipment shell is sequentially provided with a belt conveyor and a first electric slide rail from left to right, the upper end of the belt conveyor is provided with a cutter, the upper end of the first electric slide rail is provided with the alloy casting component, the alloy casting component comprises a casting groove, a guide groove and a mirror layer, the left side and the right side of the casting groove are provided with the guide groove, and the mirror layer is arranged inside the casting groove. The invention has the beneficial effects that: this not fish tail extrusion surface's tool bit and manufacturing installation can directly melt smooth tool bit to can make the tool bit can not scratch the surface of extrudate when using, use the mode of counter weight simultaneously to make the cutter keep vertical, the equipment of being convenient for carries out the founding tool bit, the dish of polishing of equipment also can be by a large scale with cutter in close contact with, the equipment of being convenient for is polished tool surface.

Description

Tool bit capable of not scratching extruded surface object and manufacturing device

Technical Field

The invention relates to the technical field of manufacturing, in particular to a cutter head without scratching an extruded surface object and a manufacturing device.

Background

The tool bit is required to be used for cutting the extruded path in the plastic processing process, and the tool bit can be processed and manufactured by using manufacturing equipment for the tool bit in the processing process.

When the surface of the cutter head is subjected to fusion casting by the conventional manufacturing device, the smoothness of the surface of the mold is insufficient, so that the machined cutter head is easy to scrape patterned plastics when in use.

Therefore, it is necessary to design a cutter head and a manufacturing apparatus that do not scratch the extruded surface material in view of the above problems.

Disclosure of Invention

The invention aims to provide a cutter head without scratching an extruded surface object and a manufacturing device, and aims to solve the problem that when the manufacturing device is used for casting the surface of the cutter head, the smoothness of the surface of a mould is insufficient at the cutter head part, so that the cutter head machined by equipment is easy to scratch plastic when in use.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a not fish tail extrusion surface thing's tool bit and manufacturing installation, includes equipment casing and alloy founding subassembly, the inside lower extreme of equipment casing has set gradually band conveyer and first electronic slide rail from a left side to the right side, and band conveyer's upper end is provided with the cutter, the upper end of first electronic slide rail is provided with alloy founding subassembly, alloy founding subassembly includes founding groove, guiding gutter and mirror layer, and the left and right sides in founding groove is provided with the guiding gutter, the inside in founding groove is provided with mirror layer.

Preferably, the guiding gutter is symmetrical about the central axis of the casting groove, and the mirror layer is connected with the casting groove in an embedded manner.

Preferably, a first motor is installed to the upper end of equipment casing, and the inside upper wall of equipment casing has set gradually centre gripping subassembly and installation cover from a left side to the right side, the lower extreme of installation cover is connected with left side frame subassembly, and one side of left side frame subassembly installs right side frame subassembly, the lower extreme of right side frame subassembly is provided with adjusting part.

Preferably, the clamping assembly comprises a second electric sliding rail, a first multi-section hydraulic cylinder, a connecting pin, a connecting frame, a cylinder and a counterweight chain, the first multi-section hydraulic cylinder is installed at the lower end of the second electric sliding rail, the lower end of the first multi-section hydraulic cylinder is connected with the connecting frame through the connecting pin, the cylinder is installed at the lower end of the connecting frame, and the counterweight chain is arranged on the left side and the right side of the connecting frame.

Preferably, the cylinder and the counterweight chain are symmetrical about a central axis of the connecting frame, and the connecting frame and the first multi-section hydraulic cylinder form a movable structure through the connecting pin.

Preferably, the left frame assembly comprises a second multi-section hydraulic cylinder, a left L frame, a first electromagnet, a second electromagnet and a support rod, the lower end of the second multi-section hydraulic cylinder is provided with the left L frame, the right side of the left L frame is sequentially provided with the first electromagnet and the support rod from bottom to top, and the second electromagnet is arranged inside the left L frame.

Preferably, the right side frame subassembly includes right L frame, third electro-magnet, spring, guide arm and loop bar, and has set gradually third electro-magnet and spring down on the left side of right L frame from last, the one end of spring is connected with the loop bar, and the upper and lower both sides of loop bar are provided with the guide arm.

Preferably, the loop bar forms an elastic structure with the right L-shaped frame through a spring, and the loop bar forms a sliding structure with the right L-shaped frame through a guide rod.

Preferably, the adjusting part includes threaded rod, second motor, thread bush, the electronic slide rail of third, spherical connecting block, movable sleeve, third motor and the dish of polishing, and the lower extreme of threaded rod is connected with the second motor, the external connection of threaded rod has the thread bush, and the left side of thread bush is connected with the electronic slide rail of third, the left side of the electronic slide rail of third is connected with spherical connecting block, and the left side of spherical connecting block is connected with the movable sleeve, the internally mounted of movable sleeve has the third motor, and the left side of third motor is connected with the dish of polishing.

Preferably, be swing joint between spherical connecting block and the movable sleeve, and the dish of polishing passes through to constitute revolution mechanic between third motor and the movable sleeve.

Compared with the prior art, the invention has the beneficial effects that: this equipment can directly be founded smooth tool bit to can make the tool bit can not scratch the surface of extrudate when using, use the mode of counter weight simultaneously to make the cutter keep vertical, the equipment of being convenient for carries out the founding tool bit, the dish of polishing of equipment also can be by a large scale and cutter in close contact with, the equipment of being convenient for is polished tool surface.

1. The mirror surface layer is embedded in the casting groove and is smooth enough, so that the alloy solution in the casting groove has better smoothness after solidification, the smoothness of a cutter processed by equipment is high enough, the cutter can be prevented from scraping products when in use, and the left side and the right side of the casting groove are provided with the flow guide grooves, so that the redundant alloy flowing out of the casting groove can be guided, and the alloy is prevented from dripping on the first electric slide rail and damaging the first electric slide rail.

2. The surface of the cutter machined by the invention has enough smoothness, so that the cutter cannot scratch the surface of an extruded product in the use process, and the cutter can be better applied to the machining of plastics.

3. The left side and the right side of the connecting frame are provided with the heavy distribution chains, so that the connecting frame which forms a rotating structure between the connecting pin and the first multi-section hydraulic cylinder is kept horizontal by means of the gravity of the heavy distribution chains, a cutter clamped by the cylinder is in a vertical state, and the equipment can conveniently cast alloy by the cutter.

4. The invention can continuously push the adjusting component by means of the sleeve rod through the elastic telescopic structure formed by the guide rod and the spring and the right L-shaped frame, so that the grinding disc can be in close contact with the cutter, and the grinding disc can conveniently grind the cutter.

5. According to the invention, through the movable structure formed between the movable sleeve and the spherical connecting block, the movable sleeve can rotate at any angle, so that the contact area between the polishing disc and the cutter is maximized for polishing, and meanwhile, the stay bar can position and guide the movement of the right frame component, so that the left L frame and the right L frame can be kept relatively horizontal, and the polishing disc can polish the cutter conveniently.

Drawings

FIG. 1 is a schematic front view of a cutting head and manufacturing apparatus for non-scratching an extruded surface according to the present invention;

FIG. 2 is a schematic perspective partial view of an alloy melt cast component of a cutting head and manufacturing device for non-scratching an extruded surface object according to the present invention;

FIG. 3 is an enlarged cross-sectional view of the right frame assembly of the cutting head and manufacturing apparatus of the present invention without scratching the extruded surface;

FIG. 4 is an enlarged schematic view of a cutting head and manufacturing apparatus for a non-marring extruded surface material of the present invention at A in FIG. 3;

FIG. 5 is a schematic perspective view of a cutter head and a manufacturing device for a blade that does not scratch an extruded surface.

In the figure: 1. an equipment housing; 2. a belt conveyor; 3. a first electric slide rail; 4. a cutter; 5. an alloy casting component; 501. a melt casting tank; 502. a diversion trench; 503. a mirror layer; 6. a first motor; 7. a clamping assembly; 701. a second electric slide rail; 702. a first multi-section hydraulic cylinder; 703. a connecting pin; 704. a connecting frame; 705. a cylinder; 706. a heavy chain; 8. installing a sleeve; 9. a left frame assembly; 901. a second multi-section hydraulic cylinder; 902. a left L rack; 903. a first electromagnet; 904. a second electromagnet; 905. a stay bar; 10. a right frame assembly; 1001. a right L-shaped frame; 1002. a third electromagnet; 1003. a spring; 1004. a guide bar; 1005. a loop bar; 11. an adjustment assembly; 1101. a threaded rod; 1102. a second motor; 1103. a threaded sleeve; 1104. a third electric slide rail; 1105. a spherical connecting block; 1106. a movable sleeve; 1107. a third motor; 1108. a grinding disc.

Detailed Description

As shown in fig. 1 to 5, the present invention provides a technical solution: a cutter head and a manufacturing device for extruding surface objects without scratching comprise an equipment shell 1 and an alloy casting component 5, wherein a belt conveyor 2 and a first electric slide rail 3 are sequentially arranged at the lower end inside the equipment shell 1 from left to right, a cutter 4 is arranged at the upper end of the belt conveyor 2, the alloy casting component 5 is arranged at the upper end of the first electric slide rail 3, the alloy casting component 5 comprises a casting groove 501, a diversion groove 502 and a mirror layer 503, the diversion grooves 502 are arranged at the left side and the right side of the casting groove 501, the mirror layer 503 is arranged inside the casting groove 501, the diversion groove 502 is symmetrical about the central axis of the casting groove 501, the mirror layer 503 is connected with the casting groove 501 in an embedding manner, a first motor 6 is arranged at the upper end of the equipment shell 1, a clamping component 7 and an installation sleeve 8 are sequentially arranged on the upper wall inside the equipment shell 1 from left to right, the lower end of the installation sleeve 8 is connected with a left frame component 9, a right frame component 10 is arranged on one side of the left frame component 9, and an adjusting component 11 is arranged at the lower end of the right frame component 10;

the concrete operation is as follows, mirror layer 503 is inlayed in casting groove 501, mirror layer 503 is smooth enough, thereby can make inside alloy solution have better smoothness after solidifying, make cutter 4 that equipment was processed smooth enough high, thereby can avoid cutter 4 to scrape flower product when using, simultaneously the left and right sides of casting groove 501 is provided with guiding gutter 502, can be to the unnecessary alloy drainage that flows out in casting groove 501, cutter 4 surface that processing was come out has sufficient smoothness, thereby make cutter 4 can not be to the surface scratch of extrusion in the use, thereby make this cutter 4 can better use in the processing of plastics, equipment casing 1 can protect equipment internals for equipment, band conveyer 2 can carry cutter 4, first electronic slide rail 3 can drive alloy casting subassembly 5 and move, first motor 6 can drive 8 rotation control left side frame subassemblies of installation cover 9 and carry out reverse polishing, and centre gripping subassembly 7 can be fixed a position 4 centre gripping of cutter, and left side frame subassembly 9, right side frame subassembly 10 and the cooperation of adjusting part 11 can polish processing to cutter 4.

As shown in fig. 1, the clamping assembly 7 includes a second electric slide rail 701, a first multi-section hydraulic cylinder 702, a connecting pin 703, a connecting frame 704, a cylinder 705 and a counterweight chain 706, the lower end of the second electric slide rail 701 is provided with the first multi-section hydraulic cylinder 702, the lower end of the first multi-section hydraulic cylinder 702 is connected with the connecting frame 704 through the connecting pin 703, the lower end of the connecting frame 704 is provided with the cylinder 705, the left and right sides of the connecting frame 704 are provided with the counterweight chain 706, the cylinder 705 and the counterweight chain 706 are symmetrical with respect to the central axis of the connecting frame 704, and the connecting frame 704 forms a movable structure with the first multi-section hydraulic cylinder 702 through the connecting pin 703;

the left side and the right side of the connecting frame 704 are provided with the heavy distribution chains 706, so that the connecting frame 704 which forms a rotating structure between the connecting pin 703 and the first multi-section hydraulic cylinder 702 is kept horizontal by means of the gravity of the heavy distribution chains 706, the cutter 4 clamped by the air cylinder 705 is in a vertical state, the equipment can conveniently perform casting alloy on the cutter 4, and the second electric slide rail 701 provides power for the movement of the first multi-section hydraulic cylinder 702.

As shown in fig. 3, the left frame assembly 9 includes a second multi-section hydraulic cylinder 901, a left L-frame 902, a first electromagnet 903, a second electromagnet 904 and a support bar 905, the lower end of the second multi-section hydraulic cylinder 901 is provided with the left L-frame 902, the right side of the left L-frame 902 is provided with the first electromagnet 903 and the support bar 905 in sequence from bottom to top, and the second electromagnet 904 is installed inside the left L-frame 902;

the support bar 905 can position and guide the movement of the right frame assembly 10, so that the left L frame 902 and the right L frame 1001 can keep relatively horizontal, the second multi-section hydraulic cylinder 901 can control the left L frame 902 to lift, the first electromagnet 903 can adsorb and fix the cutter 4, and the third electromagnet 1002 and the second electromagnet 904 can control the grinding disc 1108 to approach and leave the cutter 4 in a matching manner.

As shown in fig. 3, the right frame assembly 10 includes a right L-frame 1001, a third electromagnet 1002, a spring 1003, a guide rod 1004 and a loop bar 1005, the third electromagnet 1002 and the spring 1003 are sequentially arranged on the left side of the right L-frame 1001 from top to bottom, the loop bar 1005 is connected to one end of the spring 1003, the guide rods 1004 are arranged on the upper and lower sides of the loop bar 1005, the loop bar 1005 forms an elastic structure with the right L-frame 1001 through the spring 1003, and the loop bar 1005 forms a sliding structure with the right L-frame 1001 through the guide rod 1004;

the adjusting assembly 11 can be continuously pushed by means of the sleeve rod 1005 through an elastic telescopic structure formed by the guide rod 1004 and the spring 1003 with the right L-shaped frame 1001, so that the grinding disc 1108 can be in close contact with the cutter 4, the grinding disc 1108 can conveniently grind the cutter 4, and the grinding disc 1108 can be controlled to be close to and far away from the cutter 4 by the cooperation of the third electromagnet 1002 and the second electromagnet 904.

As shown in fig. 4, the adjusting assembly 11 includes a threaded rod 1101, a second motor 1102, a threaded sleeve 1103, a third electric sliding rail 1104, a spherical connecting block 1105, a movable sleeve 1106, a third motor 1107 and a grinding disc 1108, wherein the lower end of the threaded rod 1101 is connected with the second motor 1102, the outer part of the threaded rod 1101 is connected with the threaded sleeve 1103, the left side of the threaded sleeve 1103 is connected with the third electric sliding rail 1104, the left side of the third electric sliding rail 1104 is connected with the spherical connecting block 1105, the left side of the spherical connecting block 1105 is connected with the movable sleeve 1106, the movable sleeve 1106 is installed inside the movable sleeve 1106, the left side of the third motor 1107 is connected with the grinding disc 1108, the spherical connecting block 1105 is movably connected with the movable sleeve 1106, and the grinding disc 1108 forms a rotating structure through the third motor 1107 and the movable sleeve 1106;

through the movable structure who constitutes between movable sleeve 1106 and the spherical connecting block 1105 to can make movable sleeve 1106 carry out arbitrary angle and rotate, make the area of contact maximize of polishing dish 1108 and cutter 4 polish, second motor 1102 can drive the rotatory messenger screw thread cover 1103 of threaded rod 1101 and reciprocate, third electric slide 1104 can drive the back-and-forth movement of polishing dish 1108, swing joint between movable sleeve 1106 and the spherical connecting block 1105 is convenient for polishing dish 1108 and cutter 4 contact, third motor 1107 drives the rotation of polishing dish 1108 and carries out work.

The working principle is as follows: firstly, a cutter 4 is conveyed by a belt conveyor 2, then a connecting frame 704 is driven by a second electric sliding rail 701 and a first multi-section hydraulic cylinder 702 to be close to the cutter 4, then the cutter 4 is clamped by a cylinder 705, the left side and the right side of the connecting frame 704 are provided with a matching chain 706, the connecting frame 704 which forms a rotating structure with the first multi-section hydraulic cylinder 702 by a connecting pin 703 is kept horizontal by the gravity of the matching chain 706, so that the cutter 4 is in a vertical state, then a certain amount of alloy solution is manually filled into a casting groove 501, then the cutter 4 is put into the casting groove 501, the redundant alloy solution flows out along a diversion groove 502, a mirror layer 503 can enable the alloy solution to be smoother after being solidified, after the alloy solution is solidified, an alloy casting component 5 is driven by the first electric sliding rail 3 to move, and then a left frame component 9 is driven by a mounting sleeve 8 to descend, the first electromagnet 903 is made to adsorb the cutter 4, the cutter 4 is taken out of the alloy fusion casting component 5, the second electromagnet 904 and the third electromagnet 1002 generate heteropolar magnetism to attract each other, so that the right L rack 1001 and the left L rack 902 are butted together, the support rod 905 has a guiding function on the movement of the right L rack 1001, the second motor 1102 drives the threaded rod 1101 to rotate to enable the threaded sleeve 1103 to move up and down, the third electric sliding rail 1104 can drive the polishing disc 1108 to move back and forth, so that the polishing disc 1108 can move in all directions to polish the cutter 4, the movable connection between the movable sleeve 1106 and the spherical fusion casting block 1105 is convenient for the polishing disc 1108 to contact with the cutter 4, the third motor 1107 drives the polishing disc 1108 to rotate to work, the polishing disc 1108 can be in close contact with the cutter 4 by virtue of the sleeve rod and an elastic telescopic structure formed by the guide rod 1004 and the spring 1003 and the right L rack 1001, and the cutter 4 is put back into the alloy fusion casting component 5 after the equipment polishes one surface of the cutter 4, then, the first motor 6 drives the mounting sleeve 8 to rotate, so that the left frame component 9, the right frame component 10 and the adjusting component 11 polish the other side of the cutter 4, and then a worker takes down the polished cutter 4 to finish machining the cutter 4.

Claims (10)

1. The utility model provides a not fish tail and extrude tool bit and manufacturing installation of surperficial thing, its characterized in that, includes equipment casing (1) and alloy founding subassembly (5), the inside lower extreme of equipment casing (1) has set gradually band conveyer (2) and first electronic slide rail (3) from a left side to the right side, and the upper end of band conveyer (2) is provided with cutter (4), the upper end of first electronic slide rail (3) is provided with alloy founding subassembly (5), alloy founding subassembly (5) are including melt casting groove (501), guiding gutter (502) and mirror layer (503), and the left and right sides of melt casting groove (501) are provided with guiding gutter (502), the inside of melt casting groove (501) is provided with mirror layer (503).

2. A tool tip and manufacturing device for non-scratching extruded surfaces, according to claim 1, wherein the channels (502) are symmetrical about the central axis of the casting trough (501), and the mirror layer (503) is connected to the casting trough (501) by insert.

3. The cutter head and the manufacturing device for the extruded surface objects without scratching are characterized in that a first motor (6) is installed at the upper end of the equipment shell (1), a clamping assembly (7) and a mounting sleeve (8) are sequentially arranged on the inner upper wall of the equipment shell (1) from left to right, a left frame assembly (9) is connected to the lower end of the mounting sleeve (8), a right frame assembly (10) is installed on one side of the left frame assembly (9), and an adjusting assembly (11) is arranged at the lower end of the right frame assembly (10).

4. The cutter head and the manufacturing device which do not scratch extruded surface objects are characterized in that the clamping assembly (7) comprises a second electric sliding rail (701), a first multi-section hydraulic cylinder (702), a connecting pin (703), a connecting frame (704), a cylinder (705) and a counterweight chain (706), the first multi-section hydraulic cylinder (702) is installed at the lower end of the second electric sliding rail (701), the lower end of the first multi-section hydraulic cylinder (702) is connected with the connecting frame (704) through the connecting pin (703), the cylinder (705) is installed at the lower end of the connecting frame (704), and the counterweight chain (706) is arranged on the left side and the right side of the connecting frame (704).

5. A tool tip and manufacturing device for non-scratching extruded surface objects according to claim 4, wherein the cylinder (705) and the weight chain (706) are symmetrical about a central axis of the connecting frame (704), and the connecting frame (704) is movably connected with the first multi-section hydraulic cylinder (702) through the connecting pin (703).

6. The cutter head and the manufacturing device which do not scratch extruded surface objects are characterized in that the left frame assembly (9) comprises a second multi-section hydraulic cylinder (901), a left L frame (902), a first electromagnet (903), a second electromagnet (904) and a support rod (905), the lower end of the second multi-section hydraulic cylinder (901) is provided with the left L frame (902), the right side of the left L frame (902) is sequentially provided with the first electromagnet (903) and the support rod (905) from bottom to top, and the second electromagnet (904) is installed inside the left L frame (902).

7. The cutter head and the manufacturing device which do not scratch extruded surface objects are characterized in that the right frame assembly (10) comprises a right L-shaped frame (1001), a third electromagnet (1002), a spring (1003), a guide rod (1004) and a sleeve rod (1005), the third electromagnet (1002) and the spring (1003) are sequentially arranged on the left side of the right L-shaped frame (1001) from top to bottom, the sleeve rod (1005) is connected to one end of the spring (1003), and the guide rod (1004) is arranged on the upper side and the lower side of the sleeve rod (1005).

8. The cutter head and the manufacturing device for the extruded surface object without scratching are characterized in that the sleeve rod (1005) forms an elastic structure between the spring (1003) and the right L-shaped frame (1001), and the sleeve rod (1005) forms a sliding structure between the guide rod (1004) and the right L-shaped frame (1001).

9. The cutting head and manufacturing device for not scratching the extruded surface object according to claim 3, characterized in that the adjusting component (11) comprises a threaded rod (1101), a second motor (1102), a threaded sleeve (1103), a third electric sliding rail (1104), a spherical connecting block (1105), a movable sleeve (1106), a third motor (1107) and a grinding disc (1108), the lower end of the threaded rod (1101) is connected with a second motor (1102), the exterior of the threaded rod (1101) is connected with a threaded sleeve (1103), and the left side of the threaded sleeve (1103) is connected with a third electric sliding rail (1104), the left side of the third electric sliding rail (1104) is connected with a spherical connecting block (1105), and the left side of the spherical connecting block (1105) is connected with a movable sleeve (1106), a third motor (1107) is arranged inside the movable sleeve (1106), and the left side of the third motor (1107) is connected with a polishing disc (1108).

10. A tool tip and manufacturing device for non-scratching extruded surfaces according to claim 9, wherein the spherical connecting block (1105) is movably connected with the movable sleeve (1106), and the grinding disc (1108) forms a rotating structure with the movable sleeve (1106) through a third motor (1107).

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