CN212043929U

CN212043929U - Carbide cutter grinding device

Info

Publication number: CN212043929U
Application number: CN202020536444.8U
Authority: CN
Inventors: 王英武; 谢运锋; 周旋露
Original assignee: Heyuan Yingguang Carbide Co ltd
Current assignee: Heyuan Yingguang Carbide Co ltd
Priority date: 2020-04-13
Filing date: 2020-04-13
Publication date: 2020-12-01
Anticipated expiration: 2030-04-13

Abstract

The utility model discloses a carbide cutter coping device, charging tray, feeding agencies, chain convey pressing mechanism, subassembly and a plurality of groups cutter coping subassembly on frame, vibration, chain convey pressing mechanism includes portal frame, conveyer belt drive subassembly, first sprocket subassembly, second sprocket subassembly and spring buffering subassembly, cutter coping subassembly includes mounting bracket, returning face plate, motor, grinding roller and arc board. The utility model discloses place the cutter in piles in the charging tray on the vibration, the charging tray can arrange the cutter with the transport on the vibration, feeding agencies can adsorb the cutter to first sprocket assembly in, second sprocket assembly can carry out the pressfitting to the cutter, cutter coping subassembly can polish to the cutter and polish, the subassembly of unloading can lift the cutter of polishing well off, realize receiving the material automatically, whole coping process collects the material, carry, the pressfitting, coping and unloading process in an organic whole, degree of automation is high, improve the coping machining efficiency of cutter greatly.

Description

Carbide cutter grinding device

Technical Field

The utility model relates to a cutter coping device field especially relates to a carbide cutter coping device.

Background

The hard alloy is an alloy material made of hard compound of refractory metal and binding metal by powder metallurgy process. The hard alloy has the excellent performances of high hardness, wear resistance, good strength and toughness, heat resistance, corrosion resistance and the like. Cemented carbide is widely used as a tool material, such as turning tools, milling cutters, planing tools, drill bits, boring tools and the like, for cutting cast iron, nonferrous metals, plastics, chemical fibers, graphite, glass, stone and common steel, and also for cutting refractory steel, stainless steel, high manganese steel, tool steel and other materials which are difficult to process.

In the prior art, the hard alloy can be processed into a cutter for use so as to cut and process other metal hard materials, and the cutter needs to be repaired in the production process of the hard alloy cutter so as to achieve the effects of deburring and polishing. In the market, the tool is generally repaired by fixing the tool by using the tool and then repairing the tool by using a repairing roller on the tool. Therefore, the grinding machining efficiency is low, certain dangerousness is realized, and the labor cost is increased.

Accordingly, the prior art is deficient and needs improvement.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem that will solve is: the hard alloy cutter grinding device is automatic, convenient to operate, high in grinding efficiency and capable of automatically collecting cutters.

The technical scheme of the utility model as follows: a hard alloy cutter grinding device comprises a rack, a vibration feeding tray, a material taking mechanism, a chain type conveying pressing mechanism, a discharging assembly and a plurality of cutter grinding assemblies, wherein the vibration feeding tray is arranged on the right side of the rack;

the chain type conveying pressing mechanism comprises a portal frame, a conveying belt driving assembly, a first chain wheel assembly, a second chain wheel assembly and a spring buffer assembly, wherein the portal frame is arranged on the rear side of the frame, the first chain wheel assembly is arranged in the portal frame, the second chain wheel assembly is positioned above the first chain wheel assembly, the spring buffer assembly is connected with the second chain wheel assembly, and the conveying belt driving assembly is simultaneously connected with the first chain wheel assembly and the second chain wheel assembly;

the cutter coping subassembly includes mounting bracket, returning face plate, motor, grinding roller, arc board and locking screw, the mounting bracket is located in the frame, the returning face plate is articulated with the mounting bracket top, the motor is located on the returning face plate, the output shaft and the grinding roller of motor are connected, the arc board side is connected with the mounting bracket, be equipped with the arc wall on the arc board, the returning face plate side is equipped with the slider, the slider is located in the arc wall, locking screw passes the arc wall and is connected with the slider.

According to the technical scheme, in the carbide tool grinding device, the first chain wheel assembly comprises a first driving chain wheel, a first driven chain wheel, a first chain and a plurality of tool fixing blocks, the first driving chain wheel is connected with the driving assembly of the driving belt, the first driving chain wheel is connected with the first driven chain wheel through the first chain, and the first chain is provided with the tool fixing blocks along the circumferential direction at equal intervals.

By adopting the technical scheme, in the carbide tool grinding device, the second chain wheel component comprises a second driving chain wheel, a second driven chain wheel, a second chain and a plurality of tool pressing blocks, the second driving chain wheel is connected with the driving component of the driving belt, the second driving chain wheel is connected with the second driven chain wheel through the second chain, and the second chain is provided with the tool pressing blocks along the circumferential direction at equal intervals.

By adopting the technical scheme, in the hard alloy cutter grinding device, the spring buffer assembly comprises a fixed plate, a movable plate, a connecting screw rod, two guide rods and two buffer springs, the fixed plate is connected with the portal frame, the movable plate is positioned below the fixed plate, the fixed plate is fixedly connected with the movable plate through the connecting screw rod, the top ends of the guide rods are respectively connected with two sides of the fixed plate, two sides of the movable plate are sleeved on the guide rods, the buffer springs are respectively arranged between the fixed plate and the movable plate, and the movable plate is respectively connected with the second driving chain wheel and the second driven chain wheel.

By adopting the technical scheme, in the hard alloy cutter grinding device, the conveyor belt driving assembly comprises a driving motor, a first belt wheel, a second belt wheel, a third belt wheel, a fourth belt wheel and a conveyor belt, the first belt wheel is connected with an output shaft of the driving motor, the second belt wheel is coaxially connected with a first driving sprocket, the third belt wheel is coaxially connected with a second driving sprocket, the fourth belt wheel is connected with a fixed plate, the first belt wheel, the second belt wheel and the fourth belt wheel are respectively arranged on an inner ring of the conveyor belt, and the third belt wheel is abutted against an outer ring of the conveyor belt.

By adopting the technical scheme, in the hard alloy cutter grinding device, the material taking mechanism comprises a cross frame, a guide rod cylinder, a slide rail, a slide block and an adsorption cylinder, the cross frame is arranged at the side end of the portal frame, the guide rod cylinder is arranged at the side end of the cross frame, the slide rail is arranged on the cross frame, the slide block is arranged on the slide rail, the adsorption cylinder is connected with the slide block, and a push rod of the guide rod cylinder is connected with the adsorption cylinder.

By adopting the technical scheme, in the hard alloy cutter grinding device, the discharging component comprises a discharging block and a collecting box, the collecting box is arranged below the first chain, the discharging block is arranged in the collecting box, and the top of the discharging block is tightly attached to the first chain.

By adopting the technical scheme, in the hard alloy cutter grinding device, the material taking mechanism further comprises two buffers, and the buffers are arranged on two sides of the sliding rail.

By adopting the technical scheme, the utility model discloses put the cutter pile in the vibration charging tray, the vibration charging tray can arrange the cutter and carry, feeding agencies can adsorb the cutter to first sprocket assembly in, second sprocket assembly can carry out the pressfitting to the cutter, cutter coping subassembly can polish the cutter and polish, the subassembly of unloading can lift off the cutter that polishes, realize automatic material collecting, whole coping process collects material loading, transport, pressfitting, coping and unloading process in an organic whole, degree of automation is high, the coping machining efficiency of cutter is greatly improved; the cutter grinding assembly can adjust the grinding angle according to the actual condition, and is practical and convenient; the spring buffer component can prevent the cutter pressing block from abrading the surface of the cutter in the pressing process; the whole structure is stable, the processing and grinding efficiency is high, the operation is simple and convenient, and the grinding device can be popularized and used.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a schematic structural view of the material taking mechanism of the present invention;

FIG. 3 is a schematic view of the front structure of the chain conveying press-fit mechanism of the present invention;

fig. 4 is a schematic view of the back structure of the chain conveying press-fit mechanism of the present invention;

fig. 5 is a schematic structural view of the cutter grinding assembly of the present invention.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

As shown in fig. 1, the hard alloy cutter grinding device comprises a frame 1, a vibrating feeding tray 2, a material taking mechanism 3, a chain type conveying pressing mechanism 4, a discharging assembly 5 and a plurality of cutter grinding assemblies 6, wherein the vibrating feeding tray 2 is arranged on the right side of the frame 1, the chain type conveying pressing mechanism 4 is arranged on the rear side of the vibrating feeding tray 2, the material taking mechanism 3 is arranged between the vibrating feeding tray 2 and the chain type conveying pressing mechanism 4, the cutter grinding assemblies 6 are respectively arranged on the front side of the chain type conveying pressing mechanism 4, and the discharging assembly 5 is arranged below the chain type conveying pressing mechanism 4. In this embodiment, a user can place the cutters in a pile in the vibrating feeding tray 2, the vibrating feeding tray 2 can arrange and convey the cutters, the material taking mechanism 3 can adsorb the cutters to the chain type conveying pressing mechanism 4, and the chain type conveying pressing mechanism 4 can press and convey the cutters; the cutter grinding assembly 6 can polish and grind the cutter, the discharging assembly 5 can discharge the ground cutter, automatic material collection is achieved, the whole grinding process integrates the processes of feeding, conveying, pressing, grinding and discharging, the automation degree is high, and the grinding processing efficiency of the cutter is greatly improved.

As shown in fig. 1 and fig. 2, the material taking mechanism 3 further includes a cross frame 31, a guide rod cylinder 32, a slide rail 33, a slider 34, and an adsorption cylinder 35, the cross frame 31 is disposed at a side end of a portal frame 44, the guide rod cylinder 32 is disposed at a side end of the cross frame 31, the slide rail 33 is disposed on the cross frame 31, the slider 34 is disposed on the slide rail 33, the adsorption cylinder 35 is connected to the slider 33, and a push rod of the guide rod cylinder 32 is connected to the adsorption cylinder 35. In this embodiment, the vibrating feeding tray 2 can arrange and convey the stacked cutters, and the material taking mechanism 3 can adsorb the cutters from the vibrating feeding tray 2 to the chain type conveying and pressing mechanism 4. Specifically, adsorb cylinder 35 and slider 34 and be connected, can realize controlling on slide rail 33 and move, when the inside shrink of guide arm cylinder 32, drive adsorb cylinder 35 and move left, adsorb cylinder 35 and adsorb the cutter, then guide arm cylinder 32 outwards promotes, drives adsorb cylinder 35 and move right, adsorbs cylinder 35 and places the cutter in chain convey pressing mechanism 4. It should be noted that the vibrating feeding tray 2 is used as a prior art that has been disclosed, and the present embodiment does not give any redundant details on the internal structure and the working principle of the vibrating feeding tray 2.

As shown in fig. 2, further, the material taking mechanism 3 further includes two buffers 36, and the buffers 36 are disposed on two sides of the slide rail 33. In this embodiment, the buffer 36 is provided to prevent the adsorption cylinder 35 from moving out of the slide rail 33.

As shown in fig. 3 and 4, the chain conveying and stitching mechanism 4 includes a portal frame 44, a conveyor belt driving assembly 45, a first sprocket assembly 41, a second sprocket assembly 42 and a spring buffer assembly 43, the portal frame 44 is disposed at the rear side of the rack 1, the first sprocket assembly 41 is disposed in the portal frame 44, the second sprocket assembly 42 is disposed above the first sprocket assembly 41, the spring buffer assembly 43 is connected with the second sprocket assembly 42, and the conveyor belt driving assembly 45 is connected with the first sprocket assembly 41 and the second sprocket assembly 42 at the same time. In this embodiment, the conveyor belt driving assembly 45 can drive the first sprocket assembly 41 to rotate counterclockwise, and the conveyor belt driving assembly 45 can drive the second sprocket assembly 42 to rotate clockwise; the first sprocket assembly 41 can convey the cutter, the second sprocket assembly 42 can press the cutter on the first sprocket assembly 41, and the spring buffer assembly 43 can provide a buffer pressing effect for the second sprocket assembly 42.

As shown in fig. 3 and 4, the first sprocket assembly 41 further includes a first driving sprocket 411, a first driven sprocket 412, a first chain 413 and a plurality of cutter fixing blocks 414, the first driving sprocket 411 is connected to the driving assembly 45, the first driving sprocket 411 is connected to the first driven sprocket 412 through the first chain 413, and the cutter fixing blocks 414 are equidistantly disposed on the first chain 413 along the circumferential direction. In this embodiment, extracting mechanism 3 can adsorb the cutter in cutter fixed block 414, and a cutter can be placed to each cutter fixed block 414, under the conveying effect of first chain 413, can carry simultaneously a plurality of cutters, improves the conveying efficiency of cutter.

As shown in fig. 3 and 4, the second sprocket assembly 42 further includes a second driving sprocket 421, a second driven sprocket 422, a second chain 423 and a plurality of cutter pressing blocks 424, the second driving sprocket 421 is connected to the driving assembly 45, the second driving sprocket 421 is connected to the second driven sprocket 422 through the second chain 423, and the second chain 423 is provided with the cutter pressing blocks 424 at equal intervals along the circumferential direction. In this embodiment, the tool pressing block 424 may be attached to the tool fixing block 414, so as to press the tool on the tool fixing block 414, so that the tool sharpening assembly 6 polishes and polishes the tool. Note that the length of the second chain 423 is smaller than the length of the first chain 413.

As shown in fig. 3 and 4, the spring buffer assembly 43 further includes a fixed plate 431, a movable plate 432, a connecting screw 433, two guide rods 434 and two buffer springs 435, the fixed plate 431 is connected to the gantry 44, the movable plate 432 is located below the fixed plate 431, the fixed plate 431 is fixedly connected to the movable plate 432 through the connecting screw 433, the top end of each guide rod 434 is respectively connected to two sides of the fixed plate 431, two sides of the movable plate 432 are sleeved on the guide rods 434, the buffer springs 435 are respectively disposed between the fixed plate 431 and the movable plate 432, and the movable plate 432 is respectively connected to the second driving sprocket 421 and the second driven sprocket 422. In this embodiment, the connecting screw 433 is further sleeved with two locking nuts 4330, the movable plate 432 is located between the two locking nuts 4330, and the height of the movable plate 432 is smaller than the distance between the two locking nuts 4330. Spring-damper assembly 43 is provided to prevent tool press 424 from abrading the tool surfaces during the pressing process. Specifically, under the action of the buffer spring 435, the movable plate 432 has a downward acting force, so that the second sprocket assembly 42 can press the cutter on the first sprocket assembly 41, and during the pressing process, the movable plate 432 can overcome the elastic force of the buffer spring 435 and move upward in the connecting screw 433, thereby preventing the tool surface from being worn due to an excessive pressing force. The guide rod 434 is provided to increase the stability of the moving of the movable plate 432.

As shown in fig. 3 and 4, the belt driving unit 45 further includes a driving motor (not shown), a first pulley 451, a second pulley 452, a third pulley 453, a fourth pulley 454, and a belt 455, the first pulley 451 is connected to an output shaft of the driving motor, the second pulley 452 is coaxially connected to the first driving sprocket 411, the third pulley 453 is coaxially connected to the second driving sprocket 421, the fourth pulley 454 is connected to the fixing plate 431, the first pulley 451, the second pulley 452, and the fourth pulley 454 are respectively provided on an inner ring of the belt 455, and the third pulley 453 is in contact with an outer ring of the belt 455. In this embodiment, the driving motor can drive the transmission belt 455 to rotate, and since the first belt wheel 451, the second belt wheel 452, and the fourth belt wheel 454 are respectively disposed at the inner ring of the transmission belt 455, the driving motor can drive the first chain wheel mechanism 41 to rotate counterclockwise; the third pulley 453 abuts against the outer ring of the belt 455, and the driving motor drives the second sprocket mechanism 42 clockwise. Thus, the first chain wheel mechanism 41 and the second chain wheel mechanism 42 are respectively arranged in opposite directions, so that the stability of tool pressing can be improved.

As shown in fig. 5, the tool sharpening assembly 6 includes a mounting frame 61, a turning plate 62, a motor 63, a grinding roller 64, an arc plate 65 and a locking screw (not shown), the mounting frame 61 is disposed on the frame 1, the turning plate 62 is hinged to the top of the mounting frame 61, the motor 63 is disposed on the turning plate 62, an output shaft of the motor 63 is connected to the grinding roller 64, a side end of the arc plate 65 is connected to the mounting frame 61, an arc groove 650 is disposed on the arc plate 65, a sliding block 620 is disposed on a side end of the turning plate 62, the sliding block 620 is disposed in the arc groove 650, and the locking screw passes through the arc groove 650 and is connected to the sliding block 620. In this embodiment, the number of the tool sharpening assemblies 6 is three, that is, a user can simultaneously sharpen and polish three tools. Specifically, the motor 63 can control the grinding roller 64 to rotate at a high speed so as to grind and polish the cutters on the chain type conveying and pressing mechanism 4. The user also can adjust the angle between grinding roller 64 and the cutter according to actual conditions, and is specific, adjusts the locking screw that loosens, rotatory returning face plate 62, makes slider 620 remove in arc groove 650, then screw up the locking screw can, the regulation mode is simple and convenient.

As shown in fig. 3, further, the discharging assembly 5 includes a discharging block 51 and a collecting box 52, the collecting box 52 is disposed below the first chain 413, the discharging block 51 is disposed in the collecting box 52, and the top of the discharging block 51 is attached to the first chain 413. In this embodiment, after the cutter ground polishing through cutter coping subassembly 6, the piece 51 top of unloading can with the cutter butt to scrape the cutter and fall to collecting box 52 in, realize receiving material automatically, simple and convenient.

The above description is only exemplary of the present invention and should not be construed as limiting the present invention, and any modifications, equivalents and improvements made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims

1. The utility model provides a carbide cutter grinding device which characterized in that: the automatic grinding and polishing machine comprises a rack, a vibrating feeding tray, a material taking mechanism, a chain type conveying pressing mechanism, a discharging assembly and a plurality of cutter grinding assemblies, wherein the vibrating feeding tray is arranged on the right side of the rack;

2. The carbide tool sharpening device according to claim 1, wherein: first sprocket subassembly is including first drive sprocket, first driven sprocket, first chain and a plurality of cutter fixed block, first drive sprocket is connected with drive belt drive assembly, first drive sprocket is connected with first driven sprocket through first chain, first chain is equipped with the cutter fixed block along the circumferencial direction equidistance.

3. The carbide tool sharpening device according to claim 2, wherein: the second sprocket subassembly is including second drive sprocket, second driven sprocket, second chain and a plurality of cutter briquetting, the second drive sprocket is connected with drive belt drive assembly, the second drive sprocket passes through the second chain and is connected with second driven sprocket, the second chain is equipped with the cutter briquetting along the circumferencial direction equidistance.

4. The carbide tool sharpening device according to claim 3, wherein: the spring buffer assembly comprises a fixed plate, a movable plate, a connecting screw rod, two guide rods and two buffer springs, the fixed plate is connected with the portal frame, the movable plate is located below the fixed plate, the fixed plate is fixedly connected with the movable plate through the connecting screw rod, the top ends of the guide rods are respectively connected with two sides of the fixed plate, two sides of the movable plate are sleeved on the guide rods, the buffer springs are respectively arranged between the fixed plate and the movable plate, and the movable plate is respectively connected with a second driving chain wheel and a second driven chain wheel.

5. The carbide tool sharpening device according to claim 4, wherein: the conveying belt driving assembly comprises a driving motor, a first belt wheel, a second belt wheel, a third belt wheel, a fourth belt wheel and a conveying belt, the first belt wheel is connected with an output shaft of the driving motor, the second belt wheel is coaxially connected with a first driving chain wheel, the third belt wheel is coaxially connected with a second driving chain wheel, the fourth belt wheel is connected with a fixed plate, the first belt wheel, the second belt wheel and the fourth belt wheel are respectively arranged on the inner ring of the conveying belt, and the third belt wheel is abutted to the outer ring of the conveying belt.

6. The carbide tool sharpening device according to claim 1, wherein: the material taking mechanism comprises a cross frame, a guide rod air cylinder, a slide rail, a slide block and an adsorption air cylinder, wherein the cross frame is arranged at the side end of the portal frame, the guide rod air cylinder is arranged at the side end of the cross frame, the slide rail is arranged on the cross frame, the slide block is arranged on the slide rail, the adsorption air cylinder is connected with the slide block, and a push rod of the guide rod air cylinder is connected with the adsorption air cylinder.

7. The carbide tool sharpening device according to claim 2, wherein: the discharging assembly comprises a discharging block and a collecting box, the collecting box is arranged below the first chain, the discharging block is arranged in the collecting box, and the top of the discharging block is attached to the first chain.

8. The carbide tool sharpening device according to claim 6, wherein: the material taking mechanism further comprises two buffers, and the buffers are arranged on two sides of the sliding rail.