CN111136288A

CN111136288A - Automatic cutter clamping device of numerical control lathe

Info

Publication number: CN111136288A
Application number: CN202010153187.4A
Authority: CN
Inventors: 不公告发明人
Original assignee: Guangzhou Jijun Machinery Technology Co Ltd
Current assignee: MAANSHAN CHENGHONG MACHINERY MANUFACTURING Co.,Ltd.
Priority date: 2020-03-06
Filing date: 2020-03-06
Publication date: 2020-05-12
Anticipated expiration: 2040-03-06
Also published as: CN111136288B

Abstract

The invention discloses an automatic cutter clamping device of a numerical control lathe, which comprises an installation cavity arranged in an installation box, wherein an angle rotating block is rotatably arranged on the bottom end wall of the installation cavity, a first bevel gear is fixedly arranged on the angle rotating block, a cutter box is fixedly arranged on the upper end surface of the angle rotating block, a cutter cavity is arranged in the cutter box, a left opening communicated with the left end wall of the cutter cavity is arranged on the left end surface of the installation box, and a rear opening and a right opening are respectively arranged on the rear end surface and the right end surface of the cutter box. The position of the cutter in the cutter cavity is determined, the verticality of the position of the cutter is guaranteed, the cutter is automatically clamped through clamping, the clamping error of an operator is avoided, the working efficiency is improved, and the angle can be automatically adjusted if the angle of the cutter is required to be adjusted.

Description

Automatic cutter clamping device of numerical control lathe

Technical Field

The invention relates to the technical field of mechanical cutters, in particular to an automatic cutter clamping device of a numerical control lathe.

Background

The mechanical cutter is also called as a cutting cutter and is widely applied to the procedures of cutting, crushing, planing, coating and the like of paper, rubber, plastics, leather, wood, textiles and metal. With the development of the mechanical manufacturing technology, particularly the numerical control machining technology, the positions of the installation of the cutter and the angle of the cutter directly influence the machining quality and the machining efficiency of the machined part, in order to ensure the machining quality of the part, improve the production efficiency and reduce the machining cost, the angle of the cutter needs to be determined during clamping, and the installation needs to be paid attention to in the process of clamping the cutter so as to prevent the damage caused by the excessive force application and the falling off of the hand. The technical problems are not obvious, and the technical problems and the beneficial effects are opposite.

Disclosure of Invention

Aiming at the technical defects, the invention provides an automatic clamping device for a cutter of a numerical control lathe, which can overcome the defects.

The invention relates to an automatic cutter clamping device of a numerical control lathe, which comprises an installation cavity arranged in an installation box, wherein an angle rotating block is rotationally arranged on the bottom end wall of the installation cavity, a first bevel gear is fixedly arranged on the angle rotating block, a cutter box is fixedly arranged on the upper end surface of the angle rotating block, a cutter cavity is arranged in the cutter box, a left opening communicated with the left end wall of the cutter cavity is arranged on the left end surface of the installation box, a rear opening and a right opening are respectively arranged on the rear end surface and the right end surface of the cutter box, a left thread sleeve and a right thread sleeve are respectively arranged on the left side and the right side in the upper end surface of the cutter box, a motor is fixedly arranged on the rear end wall of the installation cavity, the front end of the motor is in power connection with a first shaft, a second bevel gear is fixedly arranged on the first shaft, a rear groove is arranged in, the rear groove rear end wall is fixedly connected with a rear spring, the front end of the rear spring is fixedly connected with a first fixed block which slides in the rear groove, a rear spline sleeve connected with the first shaft through splines is installed in the first fixed block in a rotating mode, a third bevel gear located on the rear side of the first fixed block is installed on the rear spline sleeve in a fixed mode, a second shaft is installed in the left end wall of the installation cavity in a rotating mode, a fourth bevel gear meshed with the third bevel gear is installed on the second shaft in a fixed mode, a first belt pulley located on the left side of the first shaft is installed on the second shaft in a fixed mode, a fifth bevel gear located on the left side of the first belt pulley is installed on the second shaft in a fixed mode, and a clamping mechanism and an angle adjusting.

Preferably, clamping mechanism installs including rotating third axle in the installation cavity lower extreme wall, fixed mounting on the third axle with fifth bevel gear meshed's sixth bevel gear, it has the left cam that is located to go back fixed mounting on the third axle sixth bevel gear below, installation cavity left end wall fixed mounting has the second fixed block, slidable mounting has the third fixed block in the second fixed block, terminal surface fixed mounting has left push pedal before the third fixed block, be equipped with left recess in the third fixed block, left recess front end wall fixed connection left spring, left side spring rear end fixed connection be in the gliding fourth fixed block in the left recess, fourth fixed block rear end face fixed mounting with the inconsistent fifth fixed block of left cam.

Preferably, the clamping mechanism further comprises an upper groove arranged in the right end wall of the installation cavity, an upper electromagnet is fixedly mounted on the lower end wall of the upper groove, an upper spring is fixedly connected to the upper end wall of the upper groove, the lower end of the upper spring is fixedly connected with a sixth fixed block, an upper spline housing is mounted in the sixth fixed block in a rotating mode, a seventh fixed block is fixedly mounted on the lower end face of the sixth fixed block, an eighth fixed block is fixedly mounted on the lower end face of the seventh fixed block, a lower spline housing is mounted in the eighth fixed block in a rotating mode, a seventh bevel gear meshed with the second bevel gear is fixedly mounted on the lower spline housing and located below the eighth fixed block, a fourth shaft is connected with an inner spline of the lower spline housing, and a right cam is fixedly mounted on the fourth.

Preferably, clamping mechanism still includes fixed mounting and is in the ninth fixed block of installation cavity front end wall, slidable mounting has the tenth fixed block in the ninth fixed block, tenth fixed block left end face fixed mounting has right push pedal, be equipped with right recess in the tenth fixed block, right recess left end wall fixed connection right spring, right side spring right-hand member fixed connection be in gliding eleventh fixed block in the right recess, eleventh fixed block right end face fixed mounting have with the inconsistent twelfth fixed block of right cam, installation cavity upper end wall internal rotation install with go up spline housing splined connection's fifth axle, fixed mounting has the second belt pulley on the fifth axle, go up spline housing fixed mounting have be located sixth fixed block top can with second bevel gear's eighth bevel gear.

Preferably, clamping mechanism still installs including rotating sixth axle in the installation cavity up end, fixed mounting has the third belt pulley on the sixth axle, the third belt pulley with the second belt pulley passes through the upper belt and is connected, still fixed mounting has on the sixth axle to be located the clamp gear of third belt pulley below, the left thread cover with there are left thread axle and right thread axle in the right thread cover respectively threaded connection, the left thread axle with right thread axle up end respectively fixed mounting have with left drive gear and right drive gear that clamp gear meshed.

Preferably, the angle adjusting mechanism includes an angle rotating block rotatably mounted in the right end wall of the mounting cavity, a fourth belt pulley is fixedly mounted on the seventh shaft, the fourth belt pulley is connected with the first belt pulley through a lower belt, a lower groove is arranged in the bottom end wall of the mounting cavity, a lower electromagnet is fixedly mounted on the left end face of the lower groove, a lower spring is fixedly connected to the right end wall of the lower groove, a thirteenth fixed block is fixedly connected to the left end of the lower spring, a front spline housing connected with the seventh shaft spline is rotatably mounted in the thirteenth fixed block, and a ninth bevel gear which is located on the left side of the thirteenth fixed block and meshed with the first bevel gear is fixedly mounted on the front spline housing.

The beneficial effects are that: the device can ensure the verticality of the position of the cutter by determining the position of the cutter placed in the cutter cavity for the automatic clamping of the cutter on the numerically controlled lathe, automatically clamp the cutter through clamping, thus avoiding the clamping error of an operator and improving the working efficiency, and automatically adjusting the angle if the angle of the cutter is required to be adjusted, so that the operation of the lathe becomes simple and rapid.

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 view of an automatic tool clamping device of a numerically controlled lathe according to the present invention;

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

FIG. 3 is a schematic view of the embodiment of the present invention at B in FIG. 1;

FIG. 4 is a schematic view of the embodiment of the present invention at point C in FIG. 1.

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. 1-4, 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 an automatic cutter clamping device of a numerical control lathe, which comprises a mounting cavity 11 arranged in a mounting box 10, wherein an angle rotating block 43 is rotatably arranged on the bottom end wall of the mounting cavity 11, a first bevel gear 44 is fixedly arranged on the angle rotating block 43, a cutter box 12 is fixedly arranged on the upper end surface of the angle rotating block 43, a cutter cavity 14 is arranged in the cutter box 12, a left opening 13 communicated with the left end wall of the cutter cavity 14 is arranged on the left end surface of the mounting box 10, a rear opening 57 and a right opening 25 are respectively arranged on the rear end surface and the right end surface of the cutter box 12, a left threaded sleeve 16 and a right threaded sleeve 24 are respectively arranged on the left side and the right side in the upper end surface of the cutter box 12, a motor 50 is fixedly arranged on the rear end wall of the mounting cavity 11, the front end of the motor 50 is in power connection with a first shaft 49, a gear 74 is fixedly arranged on the first shaft 49, a rear, a rear electromagnet 56 is fixedly arranged on the front end wall of the rear groove 55, a rear spring 53 is fixedly connected on the rear end wall of the rear groove 55, the front end of the rear spring 53 is fixedly connected with a first fixing block 54 which is positioned in the rear groove 55 to slide, a rear spline housing 51 connected with the first shaft 49 in a spline mode is rotatably mounted in the first fixing block 54, a third bevel gear 52 positioned at the rear side of the first fixed block 54 is fixedly arranged on the rear spline housing 51, a second shaft 46 is rotatably mounted on the left end wall of the mounting cavity 11, a fourth bevel gear 48 meshed with the third bevel gear 52 is fixedly mounted on the second shaft 46, a first belt pulley 47 positioned on the left side of the first shaft 49 is fixedly arranged on the second shaft 46, a fifth bevel gear 45 positioned on the left side of the first belt pulley 47 is fixedly mounted on the second shaft 46, and a clamping mechanism 82 and an angle adjusting mechanism 83 are arranged in the mounting cavity 11.

Advantageously, the clamping mechanism 82 comprises a third shaft 67 rotatably mounted in the lower end wall of the mounting chamber 11, a sixth bevel gear 66 meshed with the fifth bevel gear 45 is fixedly mounted on the third shaft 67, a left cam 65 positioned below the sixth bevel gear 66 is fixedly arranged on the third shaft 67, a second fixed block 62 is fixedly arranged on the left end wall of the mounting cavity 11, a third fixed block 58 is slidably arranged in the second fixed block 62, a left push plate 59 is fixedly arranged on the front end surface of the third fixed block 58, a left groove 61 is arranged in the third fixed block 58, the front end wall of the left groove 61 is fixedly connected with a left spring 60, the rear end of the left spring 60 is fixedly connected with a fourth fixed block 63 which slides in the left groove 61, and a fifth fixed block 64 which is abutted against the left cam 65 is fixedly arranged on the rear end surface of the fourth fixed block 63.

Advantageously, said clamping means 82 also comprise an upper recess 29 provided in the right end wall of said mounting cavity 11, an upper electromagnet 30 is fixedly arranged on the lower end wall of the upper groove 29, an upper spring 28 is fixedly connected on the upper end wall of the upper groove 29, the lower end of the upper spring 28 is fixedly connected with a sixth fixed block 77, an upper spline housing 78 is rotatably mounted on the sixth fixed block 77, a seventh fixed block 80 is fixedly mounted on the lower end surface of the sixth fixed block 77, an eighth fixed block 76 is fixedly mounted on the lower end surface of the seventh fixed block 80, a lower spline housing 81 is rotatably mounted in the eighth fixed block 76, a seventh bevel gear 75 which is positioned below the eighth fixed block 76 and engaged with the second bevel gear 74 is fixedly mounted on the lower spline housing 81, spline connection has the fourth axle 32 in the spline housing 81 down, fixed mounting has right cam 31 on the fourth axle 32.

Advantageously, the clamping mechanism 82 further comprises a ninth fixing block 72 fixedly mounted on the front end wall of the mounting cavity 11, a tenth fixed block 71 is slidably mounted in the ninth fixed block 72, a right push plate 73 is fixedly mounted on the left end surface of the tenth fixed block 71, a right groove 69 is arranged in the tenth fixing block 71, the left end wall of the right groove 69 is fixedly connected with a right spring 68, the right end of the right spring 68 is fixedly connected with an eleventh fixed block 70 which slides in the right groove 69, a twelfth fixed block 33 abutting against the right cam 31 is fixedly mounted on the right end surface of the eleventh fixed block 70, a fifth shaft 27 in splined connection with the upper spline sleeve 78 is rotatably mounted on the upper end wall of the mounting cavity 11, the fifth shaft 27 is fixedly provided with a second belt pulley 26, and the upper spline housing 78 is fixedly provided with an eighth bevel gear 79 which is positioned above the sixth fixing block 77 and can be meshed with the second bevel gear 74.

Advantageously, the clamping mechanism 82 further comprises a sixth shaft 19 rotatably mounted in the upper end surface of the mounting cavity 11, a third belt pulley 20 is fixedly mounted on the sixth shaft 19, the third belt pulley 20 is connected with the second belt pulley 26 through an upper belt 22, a clamping gear 18 located below the third belt pulley 20 is further fixedly mounted on the sixth shaft 19, a left threaded shaft 15 and a right threaded shaft 23 are respectively and threadedly connected in the left threaded sleeve 16 and the right threaded sleeve 24, and a left driving gear 17 and a right driving gear 21 meshed with the clamping gear 18 are respectively and fixedly mounted on the upper end surfaces of the left threaded shaft 15 and the right threaded shaft 23.

Advantageously, the angle adjusting mechanism 83 includes an angle rotating block 43 rotatably mounted in the right end wall of the mounting cavity 11, a fourth belt pulley 35 is fixedly mounted on the seventh shaft 34, the fourth belt pulley 35 is connected with the first belt pulley 47 through a lower belt 36, a lower groove 39 is provided in the bottom end wall of the mounting cavity 11, a lower electromagnet 40 is fixedly mounted on the left end surface of the lower groove 39, the right end wall of the lower groove 39 is fixedly connected with a lower spring 37, the left end of the lower spring 37 is fixedly connected with a thirteenth fixing block 38, a front spline housing 41 splined to the seventh shaft 34 is rotatably mounted on the thirteenth fixing block 38, and a ninth bevel gear 42 capable of meshing with the first bevel gear 44 is fixedly mounted on the left side of the thirteenth fixing block 38 on the front spline housing 41.

In the initial state, the upper electromagnet 30 is not energized to make the upper spring 28 in the normal tension state to make the seventh bevel gear 75 in meshing transmission with the second bevel gear 74, the rear electromagnet 56 is not energized to make the rear spring 53 in the normal tension state to make the third bevel gear 52 in meshing transmission with the fourth bevel gear 48, the lower electromagnet 40 is not energized to make the lower spring 37 in the normal tension state, the left spring 60 in the normal tension state, and the right spring 68 in the normal tension state.

When the machine starts to work, a cutter is placed in the cutter cavity 14, the motor 50 is started to drive the first shaft 49 to rotate, the rear spline housing 51 and the second bevel gear 74 rotate, the rear spline housing 51 drives the third bevel gear 52 to be meshed with the fourth bevel gear 48 to rotate, the second shaft 46 rotates, the first belt pulley 47 rotates, the fifth bevel gear 45 is driven to be meshed with the sixth bevel gear 66 to rotate, the third shaft 67 rotates to drive the left cam 65 to rotate, the left cam 65 pushes the left push plate 59 out of the rear opening 57 to abut against the cutter, and different cutter widths can be adjusted through the left spring 60; when the second bevel gear 74 rotates, the lower spline housing 81 is driven to rotate by engaging the seventh bevel gear 75, so that the fourth shaft 32 rotates, the right cam 31 is driven to rotate, and the right push plate 73 is driven to move leftwards and abut against the bottom of the cutter through the right opening 25; when the left cam 65 and the right cam 31 abut against the tool, the rear electromagnet 56 is electrified to attract the first fixed block 54, so that the third bevel gear 52 is disengaged from the fourth bevel gear 48, and simultaneously the upper electromagnet 30 is electrified to attract the eighth fixed block 76, so that the seventh bevel gear 75 is disengaged from the second bevel gear 74, so that the eighth bevel gear 79 is in meshing transmission with the second bevel gear 74, the fifth shaft 27 is driven to rotate, the second pulley 26 is driven to rotate, the third pulley 20 is driven to rotate through the upper belt 22, the sixth shaft 19 is driven to rotate, the clamping gear 18 is driven to rotate, and the left driving gear 17 and the right driving gear 21 are meshed to rotate, so that the left threaded shaft 15 and the right threaded shaft 23 are in threaded rotation through the left threaded sleeve 16 and the right threaded sleeve 24, so that the left threaded shaft 15 and the right threaded shaft 23 clamp the tool; if the angle of the tool needs to be adjusted, the upper electromagnet 30 and the rear electromagnet 56 are powered off, so that the seventh bevel gear 75 and the second bevel gear 74 are in meshing transmission, the fourth bevel gear 48 and the third bevel gear 52 are in meshing transmission, the left cam 65 and the right cam 31 gradually return to the initial positions, in the process, the first belt pulley 47 passes through the lower belt 36, so that the fourth belt pulley 35 rotates, the seventh shaft 34 rotates, the front spline housing 41 rotates, the lower electromagnet 40 is powered on to attract the thirteenth fixing block 38, the ninth bevel gear 42 is meshed with the first bevel gear 44, so that the angle rotating block 43 rotates, and the tool box 12 is driven to rotate by the rotating angle. After completion the device returns to the initial position.

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. An automatic cutter clamping device of a numerical control lathe comprises an installation cavity arranged in an installation box, an angle rotating block is rotatably arranged on the bottom end wall of the installation cavity, a first bevel gear is fixedly arranged on the angle rotating block, a cutter box is fixedly arranged on the upper end surface of the angle rotating block, a cutter cavity is arranged in the cutter box, a left opening communicated with the left end wall of the cutter cavity is arranged on the left end surface of the installation box, a rear opening and a right opening are respectively arranged on the rear end surface and the right end surface of the cutter box, a left thread sleeve and a right thread sleeve are respectively arranged on the left side and the right side in the upper end surface of the cutter box, a motor is fixedly arranged on the rear end wall of the installation cavity, the front end of the motor is in power connection with a first shaft, a second bevel gear is fixedly arranged on the first shaft, a rear groove is arranged in the right end, the rear groove rear end wall is fixedly connected with a rear spring, the front end of the rear spring is fixedly connected with a first fixed block which slides in the rear groove, a rear spline sleeve connected with the first shaft through splines is installed in the first fixed block in a rotating mode, a third bevel gear located on the rear side of the first fixed block is installed on the rear spline sleeve in a fixed mode, a second shaft is installed in the left end wall of the installation cavity in a rotating mode, a fourth bevel gear meshed with the third bevel gear is installed on the second shaft in a fixed mode, a first belt pulley located on the left side of the first shaft is installed on the second shaft in a fixed mode, a fifth bevel gear located on the left side of the first belt pulley is installed on the second shaft in a fixed mode, and a clamping mechanism and an angle adjusting.

2. The automatic tool clamping device for the numerically controlled lathe according to claim 1, wherein: clamping mechanism installs including rotating third axle in the installation cavity lower extreme wall, fixed mounting on the third axle with fifth bevel gear meshed's sixth bevel gear, it has the left cam that is located to go back fixed mounting on the third axle sixth bevel gear below, installation cavity left end wall fixed mounting has the second fixed block, slidable mounting has the third fixed block in the second fixed block, terminal surface fixed mounting has left push pedal before the third fixed block, be equipped with left recess in the third fixed block, left recess front end wall fixed connection left spring, left side spring rear end fixed connection be in gliding fourth fixed block in the left recess, fourth fixed block rear end face fixed mounting have with the inconsistent fifth fixed block of left cam.

3. The automatic tool clamping device for the numerically controlled lathe according to claim 1, wherein: the clamping mechanism further comprises an upper groove arranged in the right end wall of the installation cavity, an upper electromagnet is fixedly mounted on the lower end wall of the upper groove, an upper spring is fixedly connected on the upper end wall of the upper groove, the lower end of the upper spring is fixedly connected with a sixth fixed block, an upper spline housing is mounted in the sixth fixed block in a rotating mode, a seventh fixed block is fixedly mounted on the lower end face of the sixth fixed block, an eighth fixed block is fixedly mounted on the lower end face of the seventh fixed block, a lower spline housing is rotatably mounted in the eighth fixed block, a seventh bevel gear which is located below the eighth fixed block and meshed with the second bevel gear is fixedly mounted on the lower spline housing, a fourth shaft is connected with the lower spline housing through an internal spline, and a right cam is fixedly mounted on the fourth.

4. The automatic tool clamping device for the numerically controlled lathe according to claim 1, wherein: clamping mechanism still includes fixed mounting and is in the ninth fixed block of installation cavity front end wall, slidable mounting has the tenth fixed block in the ninth fixed block, tenth fixed block left end face fixed mounting has right push pedal, be equipped with right recess in the tenth fixed block, right recess left end wall fixed connection right spring, right side spring right-hand member fixed connection be in gliding eleventh fixed block in the right side recess, eleventh fixed block right end face fixed mounting have with the inconsistent twelfth fixed block of right cam, installation cavity upper end wall internal rotation install with go up spline housing splined connection's fifth axle, fixed mounting has the second belt pulley on the fifth axle, it sheathes in fixed mounting to go up the spline has to be located sixth fixed block top can with second bevel gear engagement's eighth bevel gear.

5. The automatic tool clamping device for the numerically controlled lathe according to claim 1, wherein: clamping mechanism still installs including rotating sixth axle in the installation cavity up end, fixed mounting has the third belt pulley on the sixth axle, the third belt pulley with the second belt pulley passes through the upper belt and connects, it is located still fixed mounting on the sixth axle the tight gear of clamp of third belt pulley below, the left thread cover with there are left thread axle and right thread axle in the right thread cover respectively threaded connection, the left thread axle with right thread axle up end respectively fixed mounting have with tight gear engagement's left drive gear and right drive gear.

6. The automatic tool clamping device for the numerically controlled lathe according to claim 1, wherein: the angle adjusting mechanism is installed including rotating the angle turning piece in the installation cavity right-hand member wall, the epaxial fixed mounting of seventh has the fourth belt pulley, the fourth belt pulley with first belt pulley is connected through lower belt, be equipped with the low groove in the installation cavity bottom end wall, low groove left end face fixed mounting has down the electro-magnet, low groove right-hand member wall fixed connection lower spring, spring left end fixed connection thirteenth fixed block down, the thirteenth fixed block internal rotation install with seventh axle splined connection's preceding spline housing, fixed mounting has on the preceding spline housing be located thirteenth fixed block left side can with the ninth bevel gear of first bevel gear meshing.