CN113426881B - Stamping device for producing high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool - Google Patents

Abstract

The invention discloses a stamping device for producing a high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool, which comprises a bearing plate, a positioning assembly and a stamping structure, wherein the bearing plate is fixedly connected with a rack, the positioning assembly is vertically fixed on the top surface of the bearing plate, the stamping structure is horizontally arranged right above the positioning assembly, and two ends of the stamping structure are vertically fixed on the top surface of the bearing plate through an installation frame. The positioning device can be used for positioning when the rough blank of the hard alloy glass cutter is punched, the stability and the precision in punching are ensured, and meanwhile, the residual scraps in punching are cleaned, so that the later-stage processing is facilitated.

Description

Stamping device for producing high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool

Technical Field

The invention relates to the technical field of hard alloy glass cutter drilling tools, in particular to a stamping device for producing a high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool.

Background

The glass cutter refers to a tool for cutting glass, the part of the glass cutter used for cutting is usually made of diamond or alloy material with hardness larger than that of the glass, a tool bit is generally connected with a drilling tool, power is transmitted by the drilling tool, the existing glass cutter is made of hard alloy, the hard alloy is made of hard compound of refractory metal and bonding metal through a powder metallurgy process, and the existing hard alloy mainly comprises the working procedures of preparing, forming, sintering and the like.

The punching device is needed to be used for the existing rough blank of the hard alloy glass cutter, the rough blank is punched, but the existing rough blank of the hard alloy glass cutter lacks a positioning and clamping device when being punched, the rough blank of the hard alloy glass cutter is easy to deviate when being punched, so that the punching precision is reduced, and meanwhile, waste materials in a hole cannot be timely cleaned when being punched at the later stage, so that the processing and the use of the next procedure are influenced.

Therefore, the punching device for producing the high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool is needed, can be positioned when the rough blank of the hard alloy glass cutter is punched, ensures the stability and the precision when the hole is punched, simultaneously cleans the residual scraps in the punching, and is convenient for later processing.

Disclosure of Invention

The invention aims to provide a punching device for producing a high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool, and aims to solve the problems that a positioning and clamping device is lacked when the existing hard alloy glass cutter rough blank is punched, the hard alloy glass cutter rough blank is easy to deviate during punching, so that the punching precision is reduced, and meanwhile, waste materials in holes cannot be cleaned in time during later punching, so that the processing and use of the next process are influenced.

The invention is realized in the following way:

the utility model provides a stamping device of high tough high wear-resisting carbide glass cutter drilling tool of production, includes the loading board, loading board and frame fixed connection still include locating component and stamping structure, and locating component is vertical to be fixed on the top surface of loading board, and the level is provided with stamping structure directly over locating component, and the stamping structure both ends are passed through the mounting bracket and are vertically fixed on the top surface of loading board.

Further, locating component includes supporting component, pressure and holds subassembly and clearance subassembly, and the supporting component is vertical to be installed on the top surface of loading board, and the clearance subassembly is vertical to be installed at the top of supporting component, and the subassembly is held to vertical pressure being provided with directly over the top of supporting component.

Further, the supporting component comprises a support, the support is fixed on the top surface of the bearing plate through a fixing screw at the bottom, screw barrels are vertically arranged on two sides of the top surface of the support in a penetrating mode, adjusting screw rods are arranged in the screw barrels in a penetrating mode through vertical threads, a connecting frame is arranged in the middle of the top surface of the support in a penetrating mode and fixed downwards, two inserting columns are symmetrically and vertically arranged on two sides of the top surface of the support in a symmetrical mode, a return spring is sleeved on each inserting column vertically, and the bottom end of the return spring is fixed on the top surface of the support.

Further, the pressing and holding assembly comprises a lifting frame, the lifting frame is horizontally arranged right above the support, a limiting groove block is fixed in the middle of the top surface of the lifting frame, a limiting insertion block is inserted in the limiting groove block, the middle of the limiting insertion block is communicated with a punched hole, and the top end of the inner portion of the limiting groove block penetrates through the lifting frame and is punched hole.

Furthermore, all vertically on the both sides terminal surface of crane be fixed with down the frame, vertically on the top surface of pushing down the frame be fixed with down the air cylinder, the output of pushing down the air cylinder runs through down the frame and fixes on the top surface of spacing inserted block, vertically on the top surface of spacing inserted block be fixed with down the pressure spring, the top of pushing down the spring is fixed on the bottom surface of pushing down the frame.

Furthermore, inserting cylinders are vertically and symmetrically fixed on two sides of the bottom surface of the lifting frame and are matched with inserting columns on the support in an inserting mode, the bottom surface of the support is fixed to the top end of the return spring, bearing support columns are vertically fixed on the bottom surface of the lifting frame and are connected with multiple top pipes of the adjusting screw in a rotating and matching mode.

Further, the clearance subassembly includes driving motor, a pivot section of thick bamboo and electric telescopic handle, driving motor is vertical to be fixed on the bottom surface of linking the frame, a pivot section of thick bamboo rotates to run through and installs on the bottom surface of linking the frame, the vertical setting of electric telescopic handle is on the top surface of linking the frame, driving motor's output runs through a pivot section of thick bamboo and electric telescopic handle's bottom mounting, electric telescopic handle's the vertical double-screw bolt that is fixed with in top, electric telescopic handle's top is provided with the clearance steel brush, clearance steel brush thread bush establishes on the double-screw bolt.

Further, vertical symmetry level is provided with two slide bars between stamping structure's the mounting bracket, and the level is provided with the screw rod between two slide bars, two slide bars and adjacent mounting bracket fixed connection, and the screw rod both ends are rotated through the bearing and are run through the mounting bracket, and mounting bracket one side level is fixed with translation motor, and translation motor's output and adjacent screw rod pivot are connected, and the level is provided with the removal case under screw rod and the slide bar.

Furthermore, two sliding sleeves and a threaded cylinder are horizontally fixed on the top surface of the movable box, the sliding sleeves and the threaded cylinder on the movable box are respectively connected with the sliding rod and the screw in a matched mode, and a punching mechanism is vertically installed inside the movable box.

Compared with the prior art, the invention has the beneficial effects that: when the punching device for producing the high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool is used for punching a hard alloy glass cutter rough blank, firstly, according to the thickness requirement of the hard alloy glass cutter rough blank in use, the adjusting screw rod on the support of the support component is rotated, the support pressing and supporting component moves upwards in the vertical direction, so that the distance between the pressing and supporting component and the punching structure is adjusted, the punching requirement of the hard alloy glass cutter rough blank with different thicknesses is met, then the lower pressing air cylinder on the upper pressing frame and the lower pressing frame of the lifting frame of the pressing and supporting component is started, the limiting insertion block is lifted upwards to be pulled out from the limiting groove block, the hard alloy glass cutter rough blank is placed in the limiting groove block, then the lower pressing air cylinder on the lower pressing frame is started to downwards enable the limiting insertion block to be inserted into the limiting groove block, then the translation motor on the mounting frame in the punching structure is started to drive the screw rod to rotate, the driving moving box drives the punching mechanism to move right above the pressing component, then the punching mechanism is started to enable a punching head to penetrate through the punched holes of the limiting insert block and the limiting groove block to punch the rough blank of the hard alloy glass cutter, then the electric telescopic rod is started to move upwards to drive the cleaning steel brush to be inserted into the punched holes of the limiting insert block and the limiting groove block, the driving motor is started to drive the cleaning steel brush to rotate to scrub and remove burrs and waste materials from the rough blank of the hard alloy glass cutter, so that the rough blank of the hard alloy glass cutter can be positioned during punching, the stability and the precision during punching are ensured, meanwhile, the residual scrap in the punched holes are cleaned, the later-stage processing is facilitated, the defects that a positioning clamping device is lacked during punching the existing rough blank of the hard alloy glass cutter are overcome, the rough blank of the hard alloy glass cutter is easy to deviate during punching, the punching precision is reduced, and meanwhile, the waste materials in the holes cannot be cleaned in time during the later-stage punching are overcome, thereby affecting the processing and use of the next process.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic diagram of the overall structure of a stamping device for producing a high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool;

FIG. 2 is an exploded view of a stamping device for producing a high strength, high toughness and high wear resistance cemented carbide glass cutter drilling tool;

FIG. 3 is an exploded view of an embodiment of a positioning assembly for a stamping device for producing a high strength, high wear resistant cemented carbide glass cutting tool;

FIG. 4 is an exploded view of an embodiment of a support assembly for a press device for producing a high strength, high wear resistant cemented carbide glass cutting tool;

FIG. 5 is an exploded view of the cleaning assembly of an embodiment of a stamping apparatus for producing a high strength, high wear resistant cemented carbide glass cutting tool;

FIG. 6 is an exploded view of a press holding assembly of an embodiment of a press apparatus for producing a high strength, high wear resistant cemented carbide glass cutting tool;

FIG. 7 is a schematic structural diagram of a lifting frame in an embodiment of a punching device for producing a high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool;

fig. 8 is an exploded view of the stamping structure in an embodiment of a stamping device for producing a high-toughness and high-wear-resistance cemented carbide glass cutting tool.

In the figure: 1. a carrier plate; 2. a positioning assembly; 21. a support assembly; 211. branch; 212. a set screw; 213. a screw cylinder; 214. adjusting the screw rod; 215. inserting a column; 216. a return spring; 217. connecting a frame; 22. a pressing component; 221. a lifting frame; 222. a limiting groove block; 223. pressing down the frame; 224. pressing down the air cylinder; 225. limiting the inserting block; 226. pressing down the spring; 227. inserting a cylinder; 228. a bearing support; 23. cleaning the assembly; 231. a drive motor; 232. a shaft barrel; 233. an electric telescopic rod; 234. a stud; 235. cleaning the steel brush; 3. stamping a structure; 31. a mounting frame; 32. a slide bar; 33. a screw; 34. a mobile box; 35. a translation motor; 36. and (7) a stamping mechanism.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention. Thus, the following detailed description of the embodiments of the present invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

Referring to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7 and fig. 8, a stamping device for producing a high-strength, high-toughness and high-wear-resistance cemented carbide glass cutter drilling tool comprises a bearing plate 1, wherein the bearing plate 1 is fixedly connected with a rack, the stamping device further comprises a positioning assembly 2 and a stamping structure 3, the positioning assembly 2 is vertically fixed on the top surface of the bearing plate 1, the stamping structure 3 is horizontally arranged right above the positioning assembly 2, and two ends of the stamping structure 3 are vertically fixed on the top surface of the bearing plate 1 through a mounting frame 31.

When the punching device for producing the high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool is used for punching a hard alloy glass cutter rough blank, firstly, according to the thickness requirement of the hard alloy glass cutter rough blank in use, the adjusting screw 214 on the support 211 of the support component 21 is rotated, the support and press component 22 is vertically supported to move upwards, so that the distance between the press component 22 and the punching structure 3 is adjusted, the punching requirement of the hard alloy glass cutter rough blank with different thicknesses is met, then, the lower pressing air cylinders 224 on the upper and lower pressing frames 223 of the press component 22 lifting frame 221 are started to lift upwards to pull out the limit inserting blocks 225 from the limit groove blocks 222, the hard alloy glass cutter rough blank is placed in the limit groove blocks 222, then the lower pressing air cylinders 224 on the lower pressing frames 223 are started to downwards to insert the limit inserting blocks 225 into the limit groove blocks 222, then, the translation motor 35 on the mounting frame 31 in the punching structure 3 is started, the screw 33 is driven to rotate, the movable box 34 is driven to drive the punching mechanism 36 to move right above the pressing component 22, then the punching mechanism 36 is started to enable a punching head to penetrate through the punched holes of the limiting insertion block 225 and the limiting groove block 222, the rough blank of the hard alloy glass cutter is punched, the electric telescopic rod 233 is started to move upwards to drive the cleaning steel brush 235 to be inserted into the punched holes of the limiting insertion block 225 and the limiting groove block 222, and the driving motor 231 is started to drive the cleaning steel brush 235 to rotate to scrub and remove burrs and waste materials from the rough blank of the hard alloy glass cutter, so that the rough blank of the hard alloy glass cutter can be positioned when being punched, the stability and the precision during punching are ensured, meanwhile, the waste scraps remained in the punching are cleaned, and the later-stage processing is facilitated.

Referring to fig. 3, the positioning assembly 2 includes a supporting assembly 21, a pressing assembly 22 and a cleaning assembly 23, the supporting assembly 21 is vertically installed on the top surface of the bearing plate 1, the cleaning assembly 23 is vertically installed on the top of the supporting assembly 21, and the pressing assembly 22 is vertically arranged right above the top of the supporting assembly 21.

And then vertically install on the top surface of loading board 1 through supporting component 21, cleaning assembly 23 is vertically installed at supporting component 21's top, and the vertical pressure that is provided with directly over supporting component 21 holds subassembly 22 to the convenient thickness demand according to carbide glass sword rough blank adjusts the interval of holding subassembly 22 apart from stamping structure 3, then utilizes cleaning assembly 23 to clear up the sweeps in punching a hole to carbide glass sword rough blank.

Referring to fig. 4, the supporting assembly 21 includes a bracket 211, the bracket 211 is fixed on the top surface of the supporting plate 1 by a fixing screw 212 at the bottom, both sides of the top surface of the bracket 211 are vertically penetrated and fixed with a screw cylinder 213, each vertical thread in the screw cylinder 213 is penetrated and installed with an adjusting screw 214, the middle part of the top surface of the bracket 211 is penetrated and fixed with a connecting frame 217 downwards, both sides of the top surface of the bracket 211 are symmetrically and vertically fixed with two inserting posts 215, a restoring spring 216 is vertically sleeved on the inserting posts 215, and the bottom end of the restoring spring 216 is fixed on the top surface of the bracket 211.

And then fix on the top surface of loading board 1 through the set screw 212 of bottom through support 211, the equal vertical through-going in top surface both sides of support 211 is fixed with barrel 213, equal vertical screw thread runs through and installs adjusting screw 214 in the barrel 213, through rotating adjusting screw 214 on the barrel 213 in the support 211 of supporting component 21, support pressure support subassembly 22 upward movement in the vertical direction, thereby adjust and press the interval between the subassembly 22 and the stamping structure 3, the top surface middle part of support 211 is run through and is fixed with even frame 217 downwards, the equal symmetrical vertical two posts 215 that are fixed with in top surface both sides of support 211, the vertical cover that is equipped with on the post 215 inserts is returned spring 216, the bottom mounting of returned spring 216 is on the top surface of support 211, thereby be convenient for vertical direction support connection supporting component 21 and pressure support subassembly 22.

Referring to fig. 6, the pressing and holding assembly 22 includes a lifting frame 221, the lifting frame 221 is horizontally disposed right above the support 211, a limit slot block 222 is fixed at the middle of the top surface of the lifting frame 221, a limit insert block 225 is inserted into the limit slot block 222, a through hole is formed in the middle of the limit insert block 225, and a through hole is formed in the top end of the limit slot block 222 through the lifting frame 221.

And then set up directly over support 211 through crane 221 level, crane 221's top surface middle part is fixed with spacing groove block 222, spacing inserted block 225 has been pegged graft in spacing groove block 222, place carbide glass cutter rough blank in spacing groove block 222, compress tightly carbide glass cutter rough blank through spacing inserted block 225 and guarantee the stability of carbide glass cutter rough blank when punching a hole, spacing inserted block 225 middle part is link up and has been seted up and has been punched a hole, spacing groove block 222 inside top runs through crane 221 and has seted up the rice that punches a hole from the er head of punching a hole of being convenient for through punching a hole to carbide glass cutter rough blank.

Referring to fig. 3 and 6, the two side end surfaces of the lifting frame 221 are vertically fixed with a lower pressing frame 223, the top surface of the lower pressing frame 223 is vertically fixed with a lower pressing cylinder 224, the output end of the lower pressing cylinder 224 penetrates through the lower pressing frame 223 and is fixed on the top surface of the limiting insertion block 225, the top surface of the limiting insertion block 225 is vertically fixed with a lower pressing spring 226, and the top end of the lower pressing spring 226 is fixed on the bottom surface of the lower pressing frame 223.

And then all vertically be fixed with down the pressure frame 223 on the both sides terminal surface through crane 221, vertically be fixed with down the air cylinder 224 on the top surface of down the pressure frame 223, the output that down the air cylinder 224 runs through down the pressure frame 223 and fixes on the top surface of spacing inserted block 225, vertically be fixed with down the spring 226 on the top surface of spacing inserted block 225, the top of down the spring 226 is fixed on the bottom surface of pushing down the frame 223, thereby make things convenient for the later stage to go up and down spacing inserted block 225 and extract from spacing groove block 222, place carbide glass cutter rough blank.

Referring to fig. 3, 6 and 7, the insertion cylinders 227 are vertically and symmetrically fixed on both sides of the bottom surface of the lifting frame 221, the insertion cylinders 227 are inserted and matched with the insertion posts 215 on the support 211, the bottom surface of the support 211 is fixed with the top end of the return spring 216, the bearing support posts 228 are vertically fixed on the bottom surface of the lifting frame 221, and the bearing support posts 228 are connected with the top pipes of the adjusting screw 214 in a rotating and matching manner.

And then both sides of the bottom surface of the lifting frame 221 are vertically and symmetrically fixed with inserting cylinders 227, the inserting cylinders 227 are in inserting and matching with the inserting columns 215 on the support 211, so that the support component 21 and the pressing and holding component 22 can be conveniently guided in the vertical direction, the bottom surface of the support 211 is fixed with the top end of the return spring 216, the bottom surface of the lifting frame 221 is vertically fixed with a bearing support column 228, the bearing support column 228 is in rotating and matching connection with a plurality of pipes on the top of the adjusting screw rod 214, and the distance between the adjusting support component 21 and the pressing and holding component 22 can be vertically supported.

Referring to fig. 5, the cleaning assembly 23 includes a driving motor 231, a rotating shaft tube 232 and an electric telescopic rod 233, the driving motor 231 is vertically fixed on the bottom surface of the connecting frame 217, the rotating shaft tube 232 is rotatably installed on the bottom surface of the connecting frame 217 in a penetrating manner, the electric telescopic rod 233 is vertically arranged on the top surface of the connecting frame 217, an output end of the driving motor 231 penetrates through the rotating shaft tube 232 and is fixed to the bottom end of the electric telescopic rod 233, a stud 234 is vertically fixed to the top end of the electric telescopic rod 233, a cleaning steel brush 235 is arranged at the top end of the electric telescopic rod 233, and the cleaning steel brush 235 is screwed on the stud 234.

And then fix on the bottom surface of linking 217 through driving motor 231 is vertical, a pivot section of thick bamboo 232 rotates to run through and installs on the bottom surface of linking 217, the vertical setting of electric telescopic handle 233 is on the top surface of linking 217, driving motor 231's output runs through a pivot section of thick bamboo 232 and electric telescopic handle 233's bottom mounting, the vertical double-screw bolt 234 that is fixed with in top of electric telescopic handle 233, electric telescopic handle 233's top is provided with clearance steel brush 235, clearance steel brush 235 threaded sleeve is established on double-screw bolt 234, be convenient for disassemble and change, start driving motor 231 and drive clearance steel brush 235 and rotate and scrub deburring and waste material to carbide glass sword rough blank.

Referring to fig. 8, two slide bars 32 are vertically, symmetrically and horizontally arranged between the mounting frames 31 of the stamping structure 3, a screw 33 is horizontally arranged between the two slide bars 32, the two slide bars 32 are fixedly connected with the adjacent mounting frames 31, two ends of the screw 33 rotate through the mounting frames 31 through bearings, a translation motor 35 is horizontally fixed on one side of the mounting frame 31, an output end of the translation motor 35 is connected with a rotating shaft of the adjacent screw 33, and a moving box 34 is horizontally arranged under the screw 33 and the slide bars 32.

Furthermore, two slide bars 32 are horizontally arranged between the mounting frames 31 of the stamping structure 3 in a vertical symmetrical manner, a screw 33 is horizontally arranged between the two slide bars 32, the two slide bars 32 are fixedly connected with the adjacent mounting frames 31, two ends of the screw 33 rotate through the mounting frames 31 through bearings, a translation motor 35 is horizontally fixed on one side of the mounting frames 31, the output end of the translation motor 35 is connected with the rotating shaft of the adjacent screw 33, a moving box 34 is horizontally arranged under the screw 33 and the slide bars 32, so that the translation motor 35 on the mounting frames 31 in the stamping structure 3 is started, the screw 33 is driven to rotate, the moving box 34 is driven to drive the stamping mechanism 36 to move to the position right above the pressing component 22, then the stamping mechanism 36 is started to enable a stamping head to penetrate through the punched holes of the limiting insert blocks 225 and the limiting groove blocks 222, and the blank of the hard alloy glass cutter is punched.

Referring to fig. 8, two sliding sleeves and two threaded cylinders are horizontally fixed on the top surface of the moving box 34, the sliding sleeves and the threaded cylinders on the moving box 34 are respectively connected with the sliding rods 32 and the threaded rods 33 in a matching manner, and a punching mechanism 36 is vertically installed inside the moving box 34.

And then through being fixed with two sliding sleeve and screw thread section of thick bamboos on the top surface level of removal case 34, sliding sleeve and the screw thread section of thick bamboo on the removal case 34 are connected with slide bar 32 and screw rod 33 cooperation respectively, and the inside vertical punching press mechanism 36 of installing of removal case 34 is convenient for cooperate slide bar 32 and screw rod 33 to carry out horizontal adjustment.

The working principle is as follows: when the punching device for producing the high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool is used for punching a hard alloy glass cutter rough blank, firstly, according to the thickness requirement of the hard alloy glass cutter rough blank in use, the adjusting screw 214 on the support 211 of the support component 21 is rotated, the support and press component 22 moves upwards in the vertical direction, so that the distance between the press component 22 and the punching structure 3 is adjusted, the punching requirement of the hard alloy glass cutter rough blank with different thicknesses is met, then the lower pressing air cylinder 224 on the upper pressing frame 223 and the lower pressing frame 223 of the lifting frame 221 of the press component 22 is started, the upward lifting is carried out, the limit insert block 225 is pulled out from the limit groove block 222, the hard alloy glass cutter rough blank is placed in the limit groove block 222, then a downward pressing cylinder 224 on a downward pressing frame 223 is started to downwards enable a limiting insert 225 to be inserted into a limiting groove block 222, then a translation motor 35 on a mounting frame 31 in the punching structure 3 is started to drive a screw 33 to rotate, a moving box 34 is driven to drive a punching mechanism 36 to move to a position right above a pressing holding assembly 22, then the punching mechanism 36 is started to enable a punching head to penetrate through punched holes of the limiting insert 225 and the limiting groove block 222 to punch holes of the hard alloy glass cutter rough blank, then an electric telescopic rod 233 is started to move upwards to drive a cleaning steel brush 235 to be inserted into the punched holes of the limiting insert 225 and the limiting groove block 222, and a driving motor 231 is started to drive the cleaning steel brush 235 to rotate to scrub the hard alloy glass cutter rough blank to remove burrs and waste materials.

The device obtained through the design can basically meet the requirement that the device can be positioned when a rough blank of the hard alloy glass cutter is punched, the stability and the precision during punching are ensured, meanwhile, the residual scraps in punching are cleaned, and the use of the punching device for producing the high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool in the later processing is convenient.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes may be made to the present invention by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (4)

1. The utility model provides a stamping device of high tough high wear-resisting carbide glass cutter drilling tool of production, includes loading board (1), loading board (1) and frame fixed connection, its characterized in that: the stamping device is characterized by further comprising a positioning assembly (2) and a stamping structure (3), wherein the positioning assembly (2) is vertically fixed on the top surface of the bearing plate (1), the stamping structure (3) is horizontally arranged right above the positioning assembly (2), and two ends of the stamping structure (3) are vertically fixed on the top surface of the bearing plate (1) through mounting frames (31);

the positioning assembly (2) comprises a supporting assembly (21), a pressing assembly (22) and a cleaning assembly (23), the supporting assembly (21) is vertically installed on the top surface of the bearing plate (1), the cleaning assembly (23) is vertically installed on the top of the supporting assembly (21), and the pressing assembly (22) is vertically arranged right above the top of the supporting assembly (21);

the supporting component (21) comprises a support (211), the support (211) is fixed on the top surface of the bearing plate (1) through a fixing screw (212) at the bottom, both sides of the top surface of the support (211) are vertically penetrated and fixed with screw barrels (213), adjusting screws (214) are vertically threaded in the screw barrels (213) in a penetrating manner, a connecting frame (217) is downwards penetrated and fixed in the middle of the top surface of the support (211), two inserting columns (215) are symmetrically and vertically fixed on both sides of the top surface of the support (211), a return spring (216) is vertically sleeved on each inserting column (215), and the bottom end of each return spring (216) is fixed on the top surface of the support (211);

the pressing and holding assembly (22) comprises a lifting frame (221), the lifting frame (221) is horizontally arranged right above the support (211), a limiting groove block (222) is fixed in the middle of the top surface of the lifting frame (221), a limiting insertion block (225) is inserted into the limiting groove block (222), a through hole is formed in the middle of the limiting insertion block (225) in a penetrating mode, and a through hole is formed in the top end of the inner portion of the limiting groove block (222) in a penetrating mode through the lifting frame (221);

the two side end faces of the lifting frame (221) are vertically fixed with lower pressing frames (223), the top faces of the lower pressing frames (223) are vertically fixed with lower pressing cylinders (224), the output ends of the lower pressing cylinders (224) penetrate through the lower pressing frames (223) and are fixed on the top faces of the limiting insertion blocks (225), the top faces of the limiting insertion blocks (225) are vertically fixed with lower pressing springs (226), and the top ends of the lower pressing springs (226) are fixed on the bottom faces of the lower pressing frames (223);

the equal vertical symmetry in bottom surface both sides of crane (221) is fixed with inserts a section of thick bamboo (227), insert a section of thick bamboo (227) with insert post (215) grafting cooperation on support (211), the bottom surface of support (211) with it is fixed to reply spring (216) top, vertically on the bottom surface of crane (221) be fixed with bearing pillar (228), bearing pillar (228) with the top normal running fit of adjusting screw (214) is connected.

2. The stamping device for producing the high-strength high-toughness high-wear-resistance hard alloy glass cutter drilling tool as claimed in claim 1, wherein the cleaning assembly (23) comprises a driving motor (231), a rotating shaft barrel (232) and an electric telescopic rod (233), the driving motor (231) is vertically fixed on the bottom surface of the connecting frame (217), the rotating shaft barrel (232) is rotatably installed on the bottom surface of the connecting frame (217) in a penetrating mode, the electric telescopic rod (233) is vertically arranged on the top surface of the connecting frame (217), the output end of the driving motor (231) penetrates through the rotating shaft barrel (232) and is fixed to the bottom end of the electric telescopic rod (233), a stud (234) is vertically fixed to the top end of the electric telescopic rod (233), a cleaning steel brush (235) is arranged at the top end of the electric telescopic rod (233), and the cleaning steel brush (235) is threaded on the stud (234).

3. The stamping device for producing the high-strength, high-toughness and high-wear-resistance hard alloy glass cutter drilling tool as claimed in claim 1, wherein two sliding rods (32) are horizontally and vertically arranged between the mounting frames (31) of the stamping structure (3), a screw (33) is horizontally arranged between the two sliding rods (32), the two sliding rods (32) are fixedly connected with the adjacent mounting frames (31), two ends of the screw (33) penetrate through the mounting frames (31) through bearings in a rotating mode, a translation motor (35) is horizontally fixed on one side of the mounting frames (31), the output end of the translation motor (35) is connected with the rotating shaft of the adjacent screw (33), and a moving box (34) is horizontally arranged under the screw (33) and the sliding rods (32).

4. The stamping device for producing the high-strength high-toughness high-wear-resistance hard alloy glass cutter drilling tool as claimed in claim 3, wherein two sliding sleeves and a threaded cylinder are horizontally fixed on the top surface of the moving box (34), the sliding sleeves and the threaded cylinder on the moving box (34) are respectively matched and connected with the sliding rod (32) and the screw rod (33), and the stamping mechanism (36) is vertically installed inside the moving box (34).

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