CN111085904B

CN111085904B - Be used for drilling machine cutter grinding device

Info

Publication number: CN111085904B
Application number: CN202010131980.4A
Authority: CN
Inventors: 不公告发明人
Original assignee: Woyang County Xinyuan Foam Sandwich Panel Co Ltd
Current assignee: Woyang County Xinyuan foam sandwich panel Co., Ltd.
Priority date: 2020-02-29
Filing date: 2020-02-29
Publication date: 2020-12-04
Anticipated expiration: 2040-02-29
Also published as: CN111085904A

Abstract

The invention discloses a grinding device for a drilling machine cutter, which comprises an outer shell, wherein a translation cavity is arranged in the outer shell, a supporting block is arranged in the right end wall of the translation cavity in a sliding manner, a first rack is fixedly arranged on the left side of the supporting block, a rotating cavity is arranged at the left side of the first rack, a moving component is arranged in the rotating cavity, a fixed block is arranged above the supporting block in a sliding manner, the right end of the fixed block is provided with a clamping block in a sliding way, the right side of the translation cavity is provided with a right transmission cavity, the device has compact structure and safer grinding tools, can reduce operation workman's danger coefficient, this device can be arranged in miniature processing factory, and this device can polish to the inclined plane of cutter through toper sanding block, and circular sanding block can polish to the edge of cutter, and clamping components can press from both sides tightly the polishing to the cutter that all kinds of diameter sizes are different.

Description

Be used for drilling machine cutter grinding device

Technical Field

The invention relates to the technical field of cutters, in particular to a grinding device for a cutter of a drilling machine.

Background

I have polished many factories to the cutter of machining master directly on expose outside high-speed rotatory polishing block go on polish, many master and master are very high and skilled in operation oneself, often directly use high-speed pivoted polishing block to polish, and the danger coefficient is very high, and especially many little factories are because of the cost reason, and the utensil of polishing the cutter is exactly a high-speed pivoted polishing block.

Many teachers may still have a controlled risk factor for sanding, but some newborns who have just entered the factory may experience some accidents for their performance and success, and therefore a less expensive and safer tool sanding apparatus is needed for operator safety.

Disclosure of Invention

Aiming at the technical defects, the invention provides a grinding device for a drill press cutter, which can overcome the defects.

The grinding device for the cutter of the drilling machine comprises an outer shell, wherein a translation cavity is arranged in the outer shell, a supporting block is arranged on the right end wall of the translation cavity in a sliding mode, a first rack is fixedly arranged on the left side of the supporting block, a rotating cavity is arranged on the left side of the first rack, a moving assembly is arranged in the rotating cavity, a fixed block is arranged above the supporting block in a sliding mode, a clamping block is arranged on the right end of the fixed block in a sliding mode, and a right transmission cavity is arranged on the right side of the translation cavity;

the upper end of the right transmission cavity is provided with a right polishing block in a sliding installation manner, the right end of the right polishing block is fixedly provided with a rotating block, a transmission assembly is arranged in the right transmission cavity, a gear cavity is arranged in the right polishing block, the left side of the gear cavity is provided with a connecting cavity, the left end face of the right polishing block is fixedly provided with a front polishing block, the front polishing block is internally provided with a connecting cavity, a polishing assembly is arranged in the connecting cavity, a rear connecting cavity is arranged in the clamping block, the front side of the rear connecting cavity is provided with an upper rack cavity, a clamping cavity is arranged above the upper rack cavity, and a clamping assembly is arranged in the clamping cavity;

go up rack chamber front side and be equipped with the pulley chamber, link up the chamber before pulley chamber front side is equipped with, it is equipped with back clamping part to link up the intracavity after, it is equipped with preceding clamping part to link up the intracavity before.

Preferably, the moving assembly includes a first gear located in the rotating cavity and engaged with the first rack gear and the first rack gear, the first gear is fixedly mounted on the first shaft, the front end and the rear end of the first shaft are respectively rotatably mounted in the front end wall and the rear end wall of the rotating cavity, a second helical gear fixedly mounted on the first shaft is arranged at the rear side of the first gear, a third helical gear engaged with the second helical gear is arranged at the left side of the second helical gear, the third helical gear is fixedly mounted on the second shaft, the second shaft is rotatably mounted in the left end wall of the rotating cavity and extends out of the left end surface of the outer shell and is fixedly mounted with a rotating handle, a left transmission cavity is arranged in the supporting block, a translation motor is fixedly mounted in the front end wall of the left transmission cavity, a third shaft is dynamically connected with the rear end of the translation motor, and a fourth belt pulley is fixedly mounted on the third shaft, the fourth belt pulley top is equipped with the fifth belt pulley, the fifth belt pulley with be equipped with the connecting belt between the fourth belt pulley, fifth belt pulley fixed mounting is equipped with the fourth axle, fifth belt pulley rear side is equipped with fixed mounting in the fourth epaxial sixth gear, the gear rack meshing connection of sixth gear top is equipped with the second rack, second rack fixed mounting be in the lower terminal wall of fixed block, fixed block slidable mounting be in the upper end wall of supporting shoe.

Preferably, the transmission assembly comprises a semicircular rotating block positioned below the rotating block, the lower end surface of the rotating block is slidably mounted in the upper end wall of the semicircular rotating block, the left end of the semicircular rotating block is fixedly mounted on a fifth shaft, the lower end of the fifth shaft is rotatably mounted in the lower end wall of the right transmission cavity, a lower clamping groove is arranged in the semicircular rotating block, a spring is fixedly mounted in the lower end wall of the lower clamping groove, a magnet slidably mounted in the lower clamping groove is fixedly mounted above the spring, a seventh helical gear rotatably mounted on the fifth shaft is arranged above the semicircular rotating block, an upper clamping groove positioned above the magnet is arranged in the lower end surface of the seventh helical gear, an electromagnet is fixedly mounted on the upper end wall of the upper clamping groove, and a fixed supporting block fixedly mounted on the fifth shaft is arranged above the seventh helical gear, and a right polishing block and the front polishing block are arranged above the fixed supporting block in a sliding manner.

Preferably, a seventh helical gear is arranged above the seventh helical gear in a meshing connection mode, the eighth helical gear is fixedly mounted on a sixth shaft, the right end of the sixth shaft is rotatably mounted in the right end wall of the gear cavity, a ninth helical gear is arranged above the eighth helical gear in a meshing connection mode, the ninth helical gear is fixedly mounted on the seventh shaft, a polishing motor located in the right end wall of the gear cavity is arranged on the right side of the seventh shaft, the right end of the seventh shaft is dynamically connected to the left side of the polishing motor, the seventh shaft is rotatably mounted between the connecting cavity and the gear cavity, and a tenth helical gear fixedly mounted on the seventh shaft is arranged in the connecting cavity.

Preferably, the grinding assembly comprises an eleventh bevel gear positioned at the left side of the tenth bevel gear and in gear engagement therewith, the eleventh bevel gear is fixedly arranged on an eighth shaft, the front end of the eighth shaft is respectively and rotatably arranged in the front end wall and the rear end wall of the connecting cavity, a twelfth belt pulley fixedly arranged on the eighth shaft is arranged at the front side of the eleventh bevel gear, a thirteenth belt pulley is arranged at the left side of the twelfth belt pulley, the thirteenth belt pulley is connected with the twelfth belt pulley through a connecting belt, the thirteenth belt pulley is fixedly arranged on the ninth shaft, the front end of the ninth shaft is respectively and rotatably arranged in the front end wall and the rear end wall of the connecting cavity, the rear side of the thirteenth belt pulley is provided with a circular grinding block which is positioned outside the rear end surface of the front grinding block and is fixedly arranged on the ninth shaft, and a conical polishing block extending to the seventh shaft outside the left end face of the right polishing block is fixedly arranged on the left side of the tenth helical gear.

Preferably, the clamping assembly comprises a tenth shaft rotatably mounted in the upper end wall of the clamping cavity, the tenth shaft extends out of the upper end surface of the clamping block and is fixedly mounted with a clamping rotating block, the tenth shaft extends into the clamping cavity and is fixedly mounted with a fourteenth helical gear, a fifteenth helical gear is arranged at the rear end of the fourteenth helical gear in a meshing connection manner, the fifteenth helical gear is fixedly mounted on the tenth shaft, the rear end of the tenth shaft is rotatably mounted in the rear end wall of the clamping cavity, a sixteenth belt pulley fixedly mounted on the eleventh shaft is arranged at the front side of the fifteenth helical gear, a seventeenth belt pulley located in the belt pulley cavity is arranged below the sixteenth belt pulley, the seventeenth belt pulley is connected with the sixteenth belt pulley by a transmission belt, and the belt pulley cavity is fixedly mounted on the twelfth shaft, the twelfth shaft is rotatably installed between the rear connecting cavity and the front connecting cavity and penetrates through the upper rack cavity and the belt pulley cavity, an eighteenth gear fixedly installed on the twelfth shaft is arranged in the upper rack cavity, a third rack is meshed and connected with a rack on the left side of the eighteenth gear, an upper sliding clamping block is fixedly installed at the lower end of the third rack, and the third rack is slidably installed in the left end wall of the upper rack cavity.

Preferably, a rear clamping component is arranged in the rear joining cavity, the rear clamping component comprises a nineteenth helical gear fixedly arranged in the rear joining cavity and fixedly mounted on the twelfth shaft, a second helical gear is arranged below the nineteenth helical gear in a meshed connection manner, the second helical gear is fixedly mounted on an eighth shaft, a lower rack cavity is arranged at the lower side of the rear joining cavity, the eighth shaft is rotatably mounted between the rear joining cavity and the lower rack cavity, a twenty-first gear is fixedly mounted in the lower rack cavity in an extending manner of the eighth shaft, a fourth rack is arranged at the left side of the twenty-first gear in a meshed connection manner, the left end of the fourth rack is slidably mounted in the right end wall of the lower rack cavity, a lower sliding clamping block is fixedly mounted at the rear end of the fourth rack, and the front clamping component in the front joining cavity and the rear clamping component in the rear joining cavity are symmetrical along the central line of the upper rack cavity, the upper sliding clamping block, the lower sliding clamping block in the front clamping part and the lower sliding clamping block in the rear clamping part form an annular circle to clamp a tool to be polished.

The beneficial effects are that: this device compact structure, grinding cutter is safer, can reduce operation workman's danger coefficient, and this device can be arranged in miniature processing factory, and this device can polish to the inclined plane of cutter through the toper sanding block, and circular sanding block can polish to the edge of cutter, and clamping components can press from both sides tightly the polishing to the cutter that all kinds of diameter sizes are different.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic view of A-A of FIG. 1 according to an embodiment of the present invention;

FIG. 3 is a schematic view of B-B in FIG. 2 according to an embodiment of the present invention;

FIG. 4 is a schematic view of C-C in FIG. 1 according to an embodiment of the present invention;

FIG. 5 is a schematic view of D-D in FIG. 1 according to an embodiment of the present invention.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

The invention will now be described in detail with reference to fig. 1-5, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to a grinding device for a drill press cutter, which comprises an outer shell 47, wherein a translation cavity 41 is arranged in the outer shell 47, a supporting block 40 is arranged in the right end wall of the translation cavity 41 in a sliding manner, a first rack 42 is fixedly arranged on the left side of the supporting block 40, a rotation cavity 50 is arranged on the left side of the first rack 42, a moving component is arranged in the rotation cavity 50, a fixed block 55 is arranged above the supporting block 40 in a sliding manner, a clamping block 56 is arranged on the right end of the fixed block 55 in a sliding manner, a right transmission cavity 23 is arranged on the right side of the translation cavity 41, a right grinding block 16 is arranged at the upper end of the right transmission cavity 23 in a sliding manner, a rotating block 22 is fixedly arranged on the right end of the right grinding block 16, a transmission component is arranged in the right transmission cavity 23, a gear cavity 20 is arranged in the right grinding block 16, a connecting cavity 57 is arranged on the left side of, preceding polishing block 12 is equipped with in and connects chamber 57, it is equipped with the subassembly of polishing to connect the intracavity 57, it links up chamber 65 after being equipped with in the clamp block 56, it is equipped with rack chamber 68 to link up the chamber 65 front side after, it is equipped with and presss from both sides tight chamber 74 to go up rack chamber 68 top, it is equipped with clamping components in pressing from both sides tight chamber 74, it is equipped with belt pulley chamber 78 to go up rack chamber 68 front side, belt pulley chamber 78 front side is equipped with preceding linking chamber 79, it is equipped with back clamping part in the chamber 65 to link up after, preceding clamping part that is equipped with in linking chamber 79.

Advantageously, the moving assembly comprises a first gear 45 located in the rotating cavity 50 and in gear-rack meshing engagement with the first rack 42, the first gear 45 is fixedly mounted on a first shaft 43, front and rear ends of the first shaft 43 are respectively rotatably mounted in front and rear end walls of the rotating cavity 50, a second helical gear 44 fixedly mounted on the first shaft 43 is arranged on a rear side of the first gear 45, a third helical gear 49 in gear meshing engagement is arranged on a left side of the second helical gear 44, the third helical gear 49 is fixedly mounted on a second shaft 48, the second shaft 48 is rotatably mounted in a left end wall of the rotating cavity 50 and extends out of a left end surface of the outer housing 47 and is fixedly mounted with a rotating handle 46, a left transmission cavity 39 is arranged in the supporting block 40, a translation motor 86 is fixedly mounted in a front end wall of the left transmission cavity 39, a rear end of the translation motor 86 is dynamically connected with a third shaft 37, fixed mounting is equipped with fourth belt pulley 38 on third axle 37, fourth belt pulley 38 top is equipped with fifth belt pulley 52, fifth belt pulley 52 with be equipped with between the fourth belt pulley 38 and connect belt 36, fifth belt pulley 52 fixed mounting is equipped with fourth axle 53, fifth belt pulley 52 rear side is equipped with fixed mounting and is in sixth gear 51 on the fourth axle 53, sixth gear 51 top rack and pinion meshing is connected and is equipped with second rack 54, second rack 54 fixed mounting is in the lower terminal wall of fixed block 55, fixed block 55 slidable mounting be in the upper end wall of supporting shoe 40.

Beneficially, the transmission assembly includes a semicircular rotating block 32 located below the rotating block 22, the lower end surface of the rotating block 22 is slidably mounted in the upper end wall of the semicircular rotating block 32, the left end of the semicircular rotating block 32 is fixedly mounted on a fifth shaft 35, the lower end of the fifth shaft 35 is rotatably mounted in the lower end wall of the right transmission cavity 23, a lower clamping groove 33 is arranged in the semicircular rotating block 32, a spring 34 is fixedly mounted in the lower end wall of the lower clamping groove 33, a magnet 31 slidably mounted in the lower clamping groove 33 is fixedly mounted above the spring 34, a seventh helical gear 28 rotatably mounted on the fifth shaft 35 is arranged above the semicircular rotating block 32, an upper clamping groove 30 located above the magnet 31 is arranged in the lower end surface of the seventh helical gear 28, an electromagnet 29 is fixedly mounted on the upper end wall of the upper clamping groove 30, and a fixed support block 24 fixedly mounted on the fifth shaft 35 is arranged above the seventh helical gear 28, and a right polishing block 16 and the front polishing block 12 are slidably arranged above the fixed supporting block 24.

Advantageously, an eighth helical gear 25 is arranged above the seventh helical gear 28 in a gear meshing connection, the eighth helical gear 25 is fixedly mounted on a sixth shaft 27, the right end of the sixth shaft 27 is rotatably mounted in the right end wall of the gear cavity 20, a ninth helical gear 19 is arranged above the eighth helical gear 25 in a gear meshing connection, the ninth helical gear 19 is fixedly mounted on the seventh shaft 15, a polishing motor 26 located in the right end wall of the gear cavity 20 is arranged on the right side of the seventh shaft 15, the right end of the seventh shaft 15 is arranged on the left side of the polishing motor 26 in a power connection manner, the seventh shaft 15 is rotatably mounted between the connecting cavity 57 and the gear cavity 20, and a tenth helical gear 18 fixedly mounted on the seventh shaft 15 is arranged in the connecting cavity 57.

Advantageously, the grinding assembly comprises an eleventh bevel gear 60 located at the left side of the tenth bevel gear 18 and in gear engagement therewith, the eleventh bevel gear 60 is fixedly mounted on an eighth shaft 61, the front end of the eighth shaft 61 is rotatably mounted in the front and rear end walls of the connecting cavity 57, the front side of the eleventh bevel gear 60 is provided with a twelfth belt pulley 59 fixedly mounted on the eighth shaft 61, the left side of the twelfth belt pulley 59 is provided with a thirteenth belt pulley 11, the thirteenth belt pulley 11 and the twelfth belt pulley 59 are connected by a connecting belt 58, the thirteenth belt pulley 11 is fixedly mounted on a ninth shaft 10, the front end of the ninth shaft 10 is rotatably mounted in the front and rear end walls of the connecting cavity 57, the rear side of the thirteenth belt pulley 11 is provided with a circular grinding block 13 located outside the rear end surface of the front grinding block 12 and fixedly mounted on the ninth shaft 10, and a conical grinding block 14 on a seventh shaft 15 extending out of the left end face of the right grinding block 16 is fixedly arranged at the left side of the tenth helical gear 18.

Advantageously, the clamping assembly comprises a tenth shaft 73 rotatably mounted in the upper end wall of the clamping cavity 74, the tenth shaft 73 extends out of the upper end surface of the clamping block 56 and is fixedly mounted with a clamping rotating block 72, the tenth shaft 73 extends into the clamping cavity 74 and is fixedly mounted with a fourteenth helical gear 71, a rear end of the fourteenth helical gear 71 is in gear engagement connection with a fifteenth helical gear 70, the fifteenth helical gear 70 is fixedly mounted on an eleventh shaft 69, a rear end of the tenth shaft 69 is rotatably mounted in the rear end wall of the clamping cavity 74, a front side of the fifteenth helical gear 70 is provided with a sixteenth pulley 75 fixedly mounted on the eleventh shaft 69, a seventeenth pulley 77 located in the pulley cavity 78 is arranged below the sixteenth pulley 75, the seventeenth pulley 77 is connected with the sixteenth pulley 75 by a transmission belt 76, pulley chamber 78 fixed mounting is on twelfth axle 63, twelfth axle 63 rotates to be installed link up the chamber 65 in the back with link up between the chamber 79 before and pass go up rack chamber 68 with pulley chamber 78, be equipped with fixed mounting in going up rack chamber 68 eighteenth gear 66 on the twelfth axle 63, gear rack meshing connection on the left side of eighteenth gear 66 is equipped with third rack 67, third rack 67 lower extreme fixed mounting is equipped with upper sliding clamp piece 80, third rack 67 slidable mounting be in the left end wall in last rack chamber 68.

Advantageously, a rear clamping component is arranged in the rear engagement cavity 65, the rear clamping component includes a nineteenth helical gear 64 fixedly arranged in the rear engagement cavity 65 and fixedly mounted on the twelfth shaft 63, a second helical gear 62 is arranged below the nineteenth helical gear 64 in a gear meshing connection manner, the second helical gear 62 is fixedly mounted on an eighth shaft 61, a lower rack cavity 84 is arranged below the rear engagement cavity 65, the eighth shaft 61 is rotatably mounted between the rear engagement cavity 65 and the lower rack cavity 84, a twenty-first gear 85 is fixedly mounted in the lower rack cavity 84 by extending the eighth shaft 61, a fourth rack 83 is arranged on the left side of the twenty-first gear 85 in a gear meshing connection manner, the left end of the fourth rack 83 is slidably mounted in the right end wall of the lower rack cavity 84, a lower sliding clamping block 82 is fixedly mounted on the rear end of the fourth rack 83, the front clamping part in the front joining cavity 79 and the rear clamping part in the rear joining cavity 65 are symmetrical along the central line of the upper rack cavity 68, and the upper sliding clamping block 80, the lower sliding clamping block 82 in the front clamping part and the lower sliding clamping block 82 in the rear clamping part form an annular circle to clamp a tool to be polished.

When the work is started:

1. placing a tool to be ground in three annular circles in the upper sliding clamping block 80, the lower sliding clamping block 82 in the front clamping component and the lower sliding clamping block 82 in the rear clamping component, then rotating the clamping rotating block 72, rotating the clamping rotating block 72 to drive the tenth shaft 73 to rotate, rotating the tenth shaft 73 to drive the fourteenth helical gear 71 to rotate, rotating the fourteenth helical gear 71 to drive the fifteenth helical gear 70 to rotate, rotating the fifteenth helical gear 70 to drive the eleventh shaft 69 to rotate, rotating the tenth shaft 69 to drive the sixteenth belt pulley 75 to rotate, rotating the sixteenth belt pulley 75 to drive the seventeenth belt pulley 77 to rotate through the transmission belt 76, rotating the seventeenth belt pulley 77 to drive the twelfth shaft 63 to rotate, the twelfth shaft 63 rotates to drive the nineteenth bevel gear 64 and the eighteenth gear 66 to rotate, the eighteenth gear 66 rotates to drive the third rack 67 to move downwards, the nineteenth bevel gear 64 rotates to drive the twentieth bevel gear 62 to rotate, the twentieth bevel gear 62 rotates to drive the eighth shaft 61 to rotate, the eighth shaft 61 rotates to drive the twenty-first gear 85 to rotate, and the twenty-first gear 85 rotates to drive the fourth rack 83 to move towards the middle between the upper sliding clamping block 80 and the two symmetrical lower sliding clamping blocks 82, so as to clamp the tool to be polished.

2. Then, the translation motor 86 is activated, the translation motor 86 rotates the third shaft 37, the third shaft 37 rotates to rotate the fourth belt pulley 38, the fourth belt pulley 38 rotates to rotate the fifth belt pulley 52 through the connecting belt 36, the fifth belt pulley 52 rotates to rotate the fourth shaft 53, the fourth shaft 53 rotates to rotate the sixth gear 51, the sixth gear 51 rotates to move the second rack 54 to the right, and the second rack 54 moves to the right to move the fixing block 55 and the clamping block 56 to the right.

3. Meanwhile, the rotating handle 46 is manually rotated, the rotating handle 46 drives the second shaft 48 to rotate, the second shaft 48 rotates to drive the third bevel gear 49 to rotate, the third bevel gear 49 rotates to drive the second bevel gear 44 to rotate, the second bevel gear 44 rotates to drive the first shaft 43 to rotate, the first shaft 43 rotates to drive the first gear 45 to rotate, the first gear 45 rotates to drive the first rack 42 to move upwards, the first rack 42 moves upwards to drive the supporting block 40 to move upwards, the supporting block 40 moves upwards to drive the fixing block 55 and the clamping block 56 to move upwards, and when the clamping block 56 moves to a proper position, the rotating handle 46 stops rotating and the translation motor 86 is turned off.

4. Then the polishing motor 26 is started, the polishing motor 26 drives the seventh shaft 15 to rotate, the seventh shaft 15 rotates to drive the conical polishing block 14, the tenth helical gear 18 and the ninth helical gear 19 to rotate, the ninth helical gear 19 rotates to drive the eighth helical gear 25 to rotate, the eighth helical gear 25 rotates to drive the seventh helical gear 28 to rotate, the conical polishing block 14 rotates to polish the cutter, then the rotating handle 46 is slowly rotated to polish the cutter, and after the inclined plane is polished.

5. The electromagnet 29 is controlled to be electrified, the electromagnet 29 is electrified to generate magnetic force to adsorb the magnet 31 to move upwards, the magnet 31 moves upwards to stretch the spring 34 and enable the magnet 31 to be clamped in the upper clamping groove 30, so that the seventh bevel gear 28 rotates and simultaneously drives the semicircular rotating block 32 to rotate, the semicircular rotating block 32 rotates through the rotating block 22 to enable the magnet 31 to rotate rightwards by ninety degrees, the front polishing block 12 moves to the original position of the right polishing block 16, then the electromagnet 29 is controlled to be powered off, and the magnet 31 moves downwards under the resilience force of the spring 34.

6. Meanwhile, the rotation of the tenth bevel gear 18 will drive the rotation of the eleventh bevel gear 60, the rotation of the eleventh bevel gear 60 will drive the rotation of the eighth shaft 61, the rotation of the eighth shaft 61 will drive the rotation of the twelfth belt pulley 59, the rotation of the twelfth belt pulley 59 will drive the rotation of the thirteenth belt pulley 11 through the connecting belt 58, the rotation of the thirteenth belt pulley 11 will drive the rotation of the ninth shaft 10, the rotation of the ninth shaft 10 will drive the rotation of the circular polishing block 13, the rotation of the circular polishing block 13 will polish the tool, after polishing, the polishing motor 26 will be turned off, then the translation motor 86 will be turned back to drive the fixed block 55 to move left, after the fixed block 55 returns to the initial position, then the translation motor 86 will be turned off, and the rotation handle 46 will be turned back to move the fixed block 55 back to the initial position, the clamping rotor 72 is then rotated in the opposite direction, and the upper sliding clamping block 80 is then released from the two lower sliding clamping blocks 82, and the tool is removed, thereby resetting the device.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims

1. The utility model provides a be used for drilling machine cutter grinding device, includes the shell body, its characterized in that: a translation cavity is formed in the outer shell, a supporting block is arranged on the right end wall of the translation cavity in a sliding mode, a first rack is fixedly arranged on the left side of the supporting block, a rotation cavity is formed in the left side of the first rack, a moving assembly is arranged in the rotation cavity, a fixed block is arranged above the supporting block in a sliding mode, a clamping block is arranged on the right end of the fixed block in a sliding mode, and a right transmission cavity is formed in the right side of the translation cavity;

a belt pulley cavity is arranged on the front side of the upper rack cavity, a front connecting cavity is arranged on the front side of the belt pulley cavity, a rear clamping component is arranged in the rear connecting cavity, and a front clamping component is arranged in the front connecting cavity;

the moving assembly comprises a first gear which is positioned in the rotating cavity and is meshed and connected with the first rack gear and the first rack gear, the first gear is fixedly arranged on a first shaft, the front end and the rear end of the first shaft are respectively rotatably arranged in the front end wall and the rear end wall of the rotating cavity, a second helical gear fixedly arranged on the first shaft is arranged on the rear side of the first gear, a third helical gear in meshed connection with the gear is arranged on the left side of the second helical gear, the third helical gear is fixedly arranged on a second shaft, the second shaft is rotatably arranged in the left end wall of the rotating cavity and extends out of the left end surface of the outer shell and is fixedly provided with a rotating handle, a left transmission cavity is arranged in the supporting block, a translation motor is fixedly arranged in the front end wall of the left transmission cavity, the rear end of the translation motor is dynamically connected with a third shaft, and a fourth belt pulley is fixedly, a fifth belt pulley is arranged above the fourth belt pulley, a connecting belt is arranged between the fifth belt pulley and the fourth belt pulley, a fourth shaft is fixedly arranged on the fifth belt pulley, a sixth gear fixedly arranged on the fourth shaft is arranged on the rear side of the fifth belt pulley, a second rack is arranged above the sixth gear in a gear-rack meshing connection mode, the second rack is fixedly arranged in the lower end wall of the fixed block, and the fixed block is slidably arranged in the upper end wall of the supporting block;

the transmission assembly comprises a semicircular rotating block positioned below the rotating block, the lower end surface of the rotating block is slidably arranged in the upper end wall of the semicircular rotating block, the left end of the semicircular rotating block is fixedly arranged on a fifth shaft, the lower end of the fifth shaft is rotatably arranged in the lower end wall of the right transmission cavity, a lower clamping groove is arranged in the semicircular rotating block, a spring is fixedly arranged in the lower end wall of the lower clamping groove, a magnet which is slidably arranged in the lower clamping groove is fixedly arranged above the spring, a seventh helical gear which is rotatably arranged on the fifth shaft is arranged above the semicircular rotating block, an upper clamping groove positioned above the magnet is arranged in the lower end face of the seventh bevel gear, an electromagnet is fixedly arranged on the upper end wall of the upper clamping groove, a fixed supporting block fixedly arranged on the fifth shaft is arranged above the seventh helical gear, and a right polishing block and the front polishing block are arranged above the fixed supporting block in a sliding manner;

an eighth helical gear is arranged above the seventh helical gear in a meshed connection mode, the eighth helical gear is fixedly installed on a sixth shaft, the right end of the sixth shaft is rotatably installed in the right end wall of the gear cavity, a ninth helical gear is arranged above the eighth helical gear in a meshed connection mode, the ninth helical gear is fixedly installed on the seventh shaft, a polishing motor located in the right end wall of the gear cavity is arranged on the right side of the seventh shaft, the right end of the seventh shaft is dynamically connected to the left side of the polishing motor, the seventh shaft is rotatably installed between the connecting cavity and the gear cavity, and a tenth helical gear fixedly installed on the seventh shaft is arranged in the connecting cavity;

the grinding component comprises an eleventh bevel gear which is positioned at the left side of the tenth bevel gear and is in gear engagement connection with the tenth bevel gear, the eleventh bevel gear is fixedly arranged on an eighth shaft, the front end of the eighth shaft is respectively and rotatably arranged in the front end wall and the rear end wall of the connecting cavity, a twelfth belt pulley fixedly arranged on the eighth shaft is arranged at the front side of the eleventh bevel gear, a thirteenth belt pulley is arranged at the left side of the twelfth belt pulley, the thirteenth belt pulley is connected with the twelfth belt pulley through a connecting belt, the thirteenth belt pulley is fixedly arranged on the ninth shaft, the front end of the ninth shaft is respectively and rotatably arranged in the front end wall and the rear end wall of the connecting cavity, the rear side of the thirteenth belt pulley is provided with a circular grinding block which is positioned outside the rear end surface of the front grinding block and is fixedly arranged on the ninth shaft, a conical polishing block on a seventh shaft extending out of the left end face of the right polishing block is fixedly arranged on the left side of the tenth helical gear;

the clamping assembly comprises a tenth shaft which is rotatably arranged in the upper end wall of the clamping cavity, the tenth shaft extends out of the upper end face of the clamping block and is fixedly provided with a clamping rotating block, the tenth shaft extends into the clamping cavity and is fixedly provided with a fourteenth helical gear, a fifteenth helical gear is arranged at the rear end of the fourteenth helical gear in a meshed connection manner, the fifteenth helical gear is fixedly arranged on the tenth shaft, the rear end of the eleventh shaft is rotatably arranged in the rear end wall of the clamping cavity, a sixteenth belt pulley fixedly arranged on the eleventh shaft is arranged on the front side of the fifteenth helical gear, a seventeenth belt pulley positioned in the belt pulley cavity is arranged below the sixteenth belt pulley, the seventeenth belt pulley and the sixteenth belt pulley are connected by a transmission belt, a belt pulley cavity is fixedly arranged on the twelfth shaft, the twelfth shaft is rotatably arranged between the rear connecting cavity and the front connecting cavity and penetrates through the upper gear The upper rack cavity is internally provided with an eighteenth gear fixedly arranged on the twelfth shaft, a left gear and a rack of the eighteenth gear are meshed and connected with a third rack, the lower end of the third rack is fixedly provided with an upper sliding clamping block, and the third rack is slidably arranged in the left end wall of the upper rack cavity;

a rear clamping component is arranged in the rear connecting cavity, the rear clamping component comprises a nineteenth helical gear fixedly arranged in the rear connecting cavity and fixedly installed on the twelfth shaft, a twenty-helical gear is arranged below the nineteenth helical gear in a meshed connection mode, the twenty-helical gear is fixedly installed on an eighth shaft, a lower rack cavity is arranged on the lower side of the rear connecting cavity, the eighth shaft is rotatably installed between the rear connecting cavity and the lower rack cavity, a twenty-first gear is fixedly installed in the lower rack cavity in an extending mode, a fourth rack is arranged on the left side of the twenty-first gear in a meshed connection mode, the left end of the fourth rack is slidably installed in the right end wall of the lower rack cavity, a lower sliding clamping block is fixedly installed on the rear end of the fourth rack, the front clamping component in the front connecting cavity is symmetrically connected with the rear clamping component in the rear cavity along the central line of the upper rack cavity, the upper sliding clamping block, the lower sliding clamping block in the front clamping part and the lower sliding clamping block in the rear clamping part form an annular circle to clamp a tool to be polished.