CN113306807A - Equidistance cutting mechanism for industrial production - Google Patents

Abstract

The invention discloses an equidistant cutting mechanism for industrial production, which comprises a toothed belt, a guide cylinder, an adjusting mechanism, a limiting sliding plate, a guide mechanism, a positioning support plate, a positioning sliding plate, a transmission mechanism, a guide sliding rail, a turnover clamping plate, a limiting clamping seat, a connecting motor, a transmission rotating shaft, a limiting clamping plate, a turbine sleeve shaft and a transmission mechanism, wherein the positioning sliding plate for supporting is clamped on the upper end surface of the guide sliding rail in a sliding manner. When the equal-length cutting is carried out on the industrial raw materials, the turbine sleeve shaft can drive the adjusting mechanism to rotate through the toothed belt, so that the adjusting mechanism can drive the guide mechanism to move up and down circularly, and meanwhile, the turbine sleeve shaft can drive the positioning sliding plate to move back and forth circularly on the upper part of the guide sliding rail through the transmission mechanism, so that the guide mechanism can be matched with the positioning sliding plate, the uniform and accurate equal-length cutting operation can be carried out on the industrial raw materials, and the subsequent efficiency of packaging or reproducing the industrial raw materials is improved.

Description

Equidistance cutting mechanism for industrial production

Technical Field

The invention relates to the technical field of industrial equipment, in particular to an equidistant cutting mechanism for industrial production.

Background

After industrial product production is accomplished, many products are because length is longer, consequently after production is accomplished, can not carry out direct package, still need to carry out cutting processing once more to the product, can pack and transportation operation afterwards, can make things convenient for the follow-up packing and transportation operation that carries on fast to the product of cutting into to longer product, but current product equidistance cuts out the mechanism, it circulates the efficiency of cutting out the branch to the raw materials and exists not enoughly, current cutting out mechanism most all is fixed knot structure simultaneously, make current cutting out mechanism can not cut out the different length of raw materials as required and carry out the adaptability regulation and control, and then the adaptability of device has been reduced.

Disclosure of Invention

The invention aims to provide an equidistant cutting mechanism for industrial production, which aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: an equidistance cutting mechanism for industrial production comprises a toothed belt, a guide cylinder, an adjusting mechanism, a limiting sliding plate, a guide mechanism, a positioning support plate, a positioning sliding plate, a transmission mechanism, a guide slide rail, a turning clamping plate, a limiting clamping seat, a connecting motor, a transmission rotating shaft, a limiting clamping plate, a turbine sleeve shaft and a transmission mechanism,

the upper end face of the guide slide rail is slidably clamped with a positioning slide plate for supporting, a positioning support plate is fixedly arranged on the upper end face of the positioning slide plate, a limiting slide plate is fixedly arranged on one end of the side end face of the positioning support plate, which is far away from the positioning slide plate, a limiting clamp seat is fixedly arranged on the upper end face of the guide slide rail, which is close to the end, a connecting motor is fixedly arranged on the center of the rear end face of the limiting clamp seat, a transmission rotating shaft for guiding is fixedly connected to the center of the front end face of the connecting motor, a limiting clamp plate is fixedly arranged on the outer end face of the transmission rotating shaft, a turbine sleeve shaft is slidably clamped on the outer end face of the transmission rotating shaft through the limiting clamp plate, the turbine sleeve shaft is rotatably clamped on the inner end face of the positioning slide plate, a transmission mechanism is rotatably clamped on the position of the side end face of the positioning slide plate, and an overturning clamp plate is rotatably clamped on the outer end face of the transmission mechanism, the transmission mechanism is rotationally clamped with the outside of the limiting clamping seat through a turnover clamping plate, the transmission mechanism is rotationally clamped on the bottom end surface of the positioning support plate, the turbine sleeve shaft is meshed with the transmission mechanism to be rotationally connected, a guide cylinder for guiding is fixedly arranged at the center of the upper end surface of the positioning support plate, an adjusting mechanism is rotationally clamped at the center of the lower end surface of the positioning support plate, the transmission mechanism is rotationally connected with the adjusting mechanism through a toothed belt, and the guide mechanism is slidably clamped on the inner end surface of the adjusting mechanism through the guide cylinder,

drive mechanism includes spacing card axle, fixed turbine and second belt pulley, the lower terminal surface center department fixed mounting of spacing card axle has the fixed turbine that is used for the transmission, and is located the bottom end face center department fixed mounting of fixed turbine has the second belt pulley.

Preferably, adjustment mechanism includes direction chuck, spacing commentaries on classics board, first belt pulley, spacing snap ring, spicing axle and bracing piece, the lower terminal surface center department fixed mounting of spacing commentaries on classics board has the direction chuck that is used for the support, and is located the lower terminal surface center department fixed mounting of direction chuck has and is used for driven first belt pulley, the even equidistance fixedly connected with four groups of bracing pieces that are used for the support of lower terminal surface of first belt pulley, and is located the bottom face fixedly connected with spacing snap ring of bracing piece, the interior terminal surface center department fixed mounting of spacing snap ring has the spicing axle.

Preferably, the guiding mechanism comprises a cutting tool, a positioning sliding shaft, guiding sliding blocks and supporting sliding grooves, four groups of guiding sliding blocks used for limiting are fixedly connected to the top of the side end face of the positioning sliding shaft at equal intervals, the supporting sliding grooves are formed in the outer end face of the positioning sliding shaft, and the cutting tool used for cutting is fixedly installed on the bottom end face of the positioning sliding shaft.

Preferably, drive mechanism is including connecting the knee lever, location turbine and grafting pivot, a side end center department fixed mounting of location turbine has the connection knee lever that is used for the direction, and is located another side end center department fixed mounting of location turbine has the grafting pivot.

Preferably, the turbine sleeve shaft comprises a worm casing, a limiting sleeve and a supporting sliding groove, the side end faces of the limiting sleeve are symmetrically and fixedly connected to the worm casing, the supporting sliding groove is formed in the outer portion of the worm casing and the outer portion of the limiting sleeve, the supporting sliding groove is matched with the limiting clamping plate, the turbine sleeve shaft is matched with the limiting clamping plate through the supporting sliding groove and then is in sliding clamping connection with the outer portion of the transmission rotating shaft, and the supporting sleeve is in fit connection with the inner wall of the positioning sliding plate.

Preferably, a rotating shaft groove is formed in the position, close to the center, of the side end face of the positioning sliding plate, the transmission mechanism is matched with the rotating shaft groove through an inserting rotating shaft and then is rotatably clamped on the side end face of the positioning sliding plate, and the lower end face of the turbine sleeve shaft is meshed with the positioning turbine to be rotatably connected.

Preferably, the lower end face of the positioning support plate is provided with a clamping groove right opposite to the guide cylinder, the clamping groove and the cross section of the limiting rotating plate are arranged in a T shape, and the adjusting mechanism rotates and is clamped on the bottom end face of the positioning support plate through the clamping groove.

Preferably, the diameter of the plug shaft is the same as the width of the supporting chute, the adjusting mechanism is matched with the supporting chute through the plug shaft and then is in sliding clamping connection with the guide mechanism, and the guide mechanism is in sliding clamping connection with the inner end face of the guide cylinder through the guide sliding block.

Preferably, the turnover clamping plate comprises a limiting clamping head, a guiding sliding rod, a positioning plug, a hexagonal clamping plate and a bidirectional screw rod, the side end face of the bidirectional screw rod is in threaded sliding connection with the limiting clamping head and the positioning plug, the guiding sliding rod is symmetrically and slidably clamped between the limiting clamping head and the positioning plug, and the hexagonal clamping plate is fixedly mounted at the center of the outer end face of the bidirectional screw rod

Preferably, the overturning clamping plate is rotatably clamped with the limiting clamping seat through a limiting clamping head of the limiting clamping head, and the overturning clamping plate is rotatably clamped with the connecting curved rod through a positioning plug.

Compared with the prior art, the invention has the following beneficial effects:

1. when the equal-length cutting is carried out on the industrial raw materials, the turbine sleeve shaft can drive the adjusting mechanism to rotate through the toothed belt, so that the adjusting mechanism can drive the guide mechanism to move up and down circularly, and meanwhile, the turbine sleeve shaft can drive the positioning sliding plate to move back and forth circularly on the upper part of the guide sliding rail through the transmission mechanism, so that the guide mechanism can be matched with the positioning sliding plate, the uniform and accurate equal-length cutting operation can be carried out on the industrial raw materials, and the subsequent efficiency of packaging or reproducing the industrial raw materials is improved.

2. According to the invention, the turbine sleeve shaft is arranged and can simultaneously drive the transmission mechanism and the adjusting mechanism, so that the positioning sliding plate can be conveniently driven to move back and forth in the follow-up process, the guide mechanism can be driven to cut up and down, the utilization efficiency of power is improved, and the efficiency of cutting industrial raw materials in the follow-up process is also improved.

3. According to the invention, through the arrangement of the turnover clamping plate, a user can adjust the specific length of the turnover clamping plate, so that the length of the equidistant cutting raw materials can be freely adjusted by subsequent workers according to requirements, and the adaptability of the device is improved to the greatest extent.

Drawings

FIG. 1 is a schematic view of the main structure of the present invention;

FIG. 2 is a side view of the body of the present invention;

FIG. 3 is an enlarged view of a portion of the subject of the present invention at I;

FIG. 4 is a schematic view of the adjusting mechanism of the present invention;

FIG. 5 is a schematic view of the structure of the guiding mechanism of the present invention;

FIG. 6 is a schematic view of the transmission mechanism of the present invention;

FIG. 7 is a schematic view of the transmission mechanism of the present invention;

FIG. 8 is a schematic structural view of a second embodiment of the turnover clamping plate of the present invention;

fig. 9 is a diagram illustrating a second embodiment of the main body of the present invention.

In the figure: 1-toothed belt, 2-guide cylinder, 3-adjusting mechanism, 4-limit sliding plate, 5-guide mechanism, 6-positioning support plate, 7-positioning sliding plate, 8-transmission mechanism, 9-guide sliding rail, 10-turnover clamping plate, 11-limit clamping seat, 12-connecting motor, 13-transmission rotating shaft, 14-limit clamping plate, 15-turbine sleeve shaft, 16-transmission mechanism, 31-guide clamping disc, 32-limit rotating plate, 33-first belt pulley, 34-limit clamping ring, 35-plug shaft, 36-supporting rod, 51-cutting tool, 52-positioning sliding shaft, 53-guide sliding block, 54-supporting sliding groove, 81-connecting curved rod, 82-positioning turbine, 83-plug rotating shaft, 161-limiting clamping shaft, 162-fixed turbine, 163-second belt pulley, 101-limiting clamping head, 102-guiding sliding rod, 103-positioning plug, 104-hexagonal clamping plate and 105-bidirectional screw rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, an embodiment of the present invention is shown: an equidistance cutting mechanism for industrial production comprises a toothed belt 1, a guide cylinder 2, an adjusting mechanism 3, a limiting sliding plate 4, a guide mechanism 5, a positioning support plate 6, a positioning sliding plate 7, a transmission mechanism 8, a guide sliding rail 9, a turnover clamping plate 10, a limiting clamping seat 11, a connecting motor 12, a transmission rotating shaft 13, a limiting clamping plate 14, a turbine sleeve shaft 15 and a transmission mechanism 16,

a positioning slide plate 7 for supporting is slidably clamped on the upper end face of the guide slide rail 9, a positioning support plate 6 is fixedly arranged on the upper end face of the positioning slide plate 7, a limiting slide plate 4 is fixedly arranged on one end of the side end face of the positioning support plate 6, which is far away from the positioning slide plate 7, a limiting clamp seat 11 is fixedly arranged on the upper end face of the guide slide rail 9, which is close to the end head, a connecting motor 12 is fixedly arranged on the center of the rear end face of the limiting clamp seat 11, a transmission rotating shaft 13 for guiding is fixedly connected on the center of the front end face of the connecting motor 12, a limiting clamp plate 14 is fixedly arranged on the outer end face of the transmission rotating shaft 13, a turbine sleeve shaft 15 is slidably clamped on the outer end face of the transmission rotating shaft 13 through the limiting clamp plate 14, the turbine sleeve shaft 15 is rotatably clamped on the inner end face of the positioning slide plate 7, a transmission mechanism 8 is rotatably clamped on the side end face of the positioning slide plate 7, and an overturning clamp plate 10 is rotatably clamped on the outer end face of the transmission mechanism 8, the transmission mechanism 8 is rotationally clamped with the outside of the limiting clamping seat 11 through the overturning clamping plate 10, the transmission mechanism 16 is rotationally clamped on the bottom end surface of the positioning support plate 6, the turbine sleeve shaft 15 is meshed with the transmission mechanism 16 to be rotationally connected, the center of the upper end surface of the positioning support plate 6 is fixedly provided with a guide cylinder 2 for guiding, the center of the lower end surface of the positioning support plate 6 is rotationally clamped with an adjusting mechanism 3, the transmission mechanism 16 is rotationally connected with the adjusting mechanism 3 through a toothed belt 1, the inner end surface of the adjusting mechanism 3 is slidably clamped with a guide mechanism 5 through the guide cylinder 2,

the transmission mechanism 16 includes a limit clamp shaft 161, a fixed turbine 162 and a second belt pulley 163, the center of the lower end surface of the limit clamp shaft 161 is fixedly provided with the fixed turbine 162 for transmission, and the center of the bottom end surface of the fixed turbine 162 is fixedly provided with the second belt pulley 163.

Adjustment mechanism 3 includes direction chuck 31, spacing commentaries on classics board 32, first belt pulley 33, spacing snap ring 34, grafting axle 35 and bracing piece 36, the lower terminal surface center department fixed mounting of spacing commentaries on classics board 32 has direction chuck 31 that is used for supporting, and the lower terminal surface center department fixed mounting who is located direction chuck 31 has a first belt pulley 33 that is used for the transmission, the even equidistance fixedly connected with four groups of bracing pieces 36 that are used for supporting of lower terminal surface of first belt pulley 33, and be located the bottom face fixedly connected with spacing snap ring 34 of bracing piece 36, the interior terminal surface center department fixed mounting of spacing snap ring 34 has grafting axle 35.

The guide mechanism 5 comprises a cutting tool 51, a positioning slide shaft 52, guide sliding blocks 53 and support sliding grooves 54, four groups of guide sliding blocks 53 for limiting are uniformly and fixedly connected to the top of the side end face of the positioning slide shaft 52 at equal intervals, the support sliding grooves 54 are formed in the outer end face of the positioning slide shaft 52, and the cutting tool 51 for cutting is fixedly mounted on the bottom end face of the positioning slide shaft 52.

The transmission mechanism 8 comprises a connecting curved rod 81, a positioning worm wheel 82 and an insertion rotating shaft 83, wherein the connecting curved rod 81 for guiding is fixedly installed at the center of one side end of the positioning worm wheel 82, and the insertion rotating shaft 83 is fixedly installed at the center of the other side end of the positioning worm wheel 82.

The turbine sleeve shaft 15 comprises a worm casing, a side end face is symmetrically and fixedly connected with a limiting sleeve of the worm casing, and a supporting sliding groove is formed in the outer portion of the worm casing and the limiting sleeve, the supporting sliding groove is matched with the limiting clamping plate 14, the turbine sleeve shaft 15 is matched with the limiting clamping plate 14 through the supporting sliding groove and then is in sliding clamping connection with the outer portion of the transmission rotating shaft 13, the supporting sleeve is in laminating connection with the inner wall of the positioning sliding plate 7, the limiting sleeve can be laminated with the inner wall of the positioning sliding plate 7, therefore, when the subsequent positioning sliding plate 7 is convenient to displace, the turbine sleeve shaft 15 can be kept stationary inside the positioning sliding plate 7, the subsequent transmission stability is improved, the supporting sliding groove can guarantee that the limiting clamping plate 14 drives the turbine sleeve shaft 15 to rotate, and the subsequent turbine sleeve shaft 15 can be convenient to slide outside the transmission rotating shaft 13.

The side end face of location slide 7 is close to center department and has seted up the pivot groove, and drive mechanism 8 through grafting pivot 83 and pivot groove looks adaptation and then rotate the joint at the side end face of location slide 7, the lower terminal surface of turbine sleeve axle 15 meshes with location turbine 82 and rotates and be connected, the pivot groove can effectively improve the stability at location slide 7 lateral part at follow-up drive mechanism 8, the bottom of turbine sleeve axle 15 can be through location turbine 82 for drive mechanism 8 transmits sufficient power simultaneously, make things convenient for follow-up drive location slide 7 to carry out the round trip displacement of circulation.

The lower terminal surface of location extension board 6 is just having seted up the joint groove to 2 departments of guide cylinder, and the joint groove all is the T setting that appears with spacing commentaries on classics board 32's cross section, and adjustment mechanism 3 passes through the joint groove and then rotates the joint at the bottom face of location extension board 6, and the joint groove can provide sufficient spacing basis for spacing commentaries on classics board 32 to improve follow-up adjustment mechanism 3 and moving the stability of connecting in the bottom of location extension board 6.

The diameter of spiale 35 is the same with the width that supports spout 54, and adjustment mechanism 3 through spiale 35 with support spout 54 looks adaptation and then with guiding mechanism 5 joint that slides, guiding mechanism 5 is through direction slider 53 and then the slip joint at the interior terminal surface of guide cylinder 2, because direction slider 53 is closed setting, and then make when spacing snap ring 34 rotates, spiale 35 can be along the inside orbit of direction slider 53, and then drive guiding mechanism 5 through direction slider 53 and carry out the round trip displacement of circulating in adjustment mechanism 3's inside, thereby make things convenient for the follow-up circulation to carry out the equidistant circulation cutting operation to the raw materials, the follow-up precision of cutting that carries on has improved.

As shown in fig. 8-9, a second embodiment of the flipping card 10 of the present invention is different from the first embodiment in that: the turnover clamping plate 10 comprises a limiting clamping head 101, a guide sliding rod 102, a positioning plug 103, a hexagonal clamping plate 104 and a bidirectional screw rod 105, the side end face of the bidirectional screw rod 105 is in threaded sliding connection with the limiting clamping head 101 and the positioning plug 103, the guide sliding rod 102 is symmetrically and slidably clamped between the limiting clamping head 101 and the positioning plug 103, the hexagonal clamping plate 104 is fixedly installed at the center of the outer end face of the bidirectional screw rod 105, when in adjustment, a user can rotate the hexagonal clamping plate 104 through an external tool, at the moment, the limiting clamping head 101 and the positioning plug 103 are limited by the guide sliding rod 102 and move inwards or outwards along the radial direction of the bidirectional screw rod 105, so that the relative position of the positioning support plate 6 relative to the guide sliding rail 9 is adjusted, thereby facilitating subsequent cutting of raw materials with different lengths, providing an enough limiting base, further improving the adaptability of the device, the turnover clamping plate 10 is rotationally clamped with the limiting clamping seat 11 through the limiting clamping head 101, and the turnover clamping plate 10 is rotationally clamped with the connecting curved rod 81 through the positioning plug 103, so that the stability of subsequent connection can be effectively improved.

The working principle is as follows: as shown in fig. 1-3, when in use, the external feeding mechanism can be positioned at one side of the guide rail 9 by a user, so as to facilitate the subsequent rapid supply of the raw material, thereby facilitating the subsequent equal-length cutting operation of the raw material, and the device can be positioned at the upper part of the external conveying mechanism by the user, thereby facilitating the subsequent rapid conveying operation of the cut raw material, and further improving the subsequent cutting and conveying efficiency of the raw material,

as shown in fig. 1, 4 and 5, when the device is used, a user can start the connection motor 12 through the external control mechanism, at this time, the connection motor 12 can drive the front transmission shaft 13 to rotate, so that the transmission shaft 13 can drive the turbine sleeve shaft 15 to rotate through the limiting clamping plate 14 when rotating, meanwhile, while the turbine sleeve shaft 15 rotates, the bottom of the turbine sleeve shaft 15 can drive the connection curved rod 81 to rotate through the positioning turbine 82, and simultaneously, the side of the turbine sleeve shaft 15 can drive the toothed belt 1 to rotate through the transmission mechanism 16,

as shown in fig. 1 and fig. 6, when the turbine sleeve shaft 15 drives the connecting curved rod 81 to rotate through the positioning worm 82, the connecting curved rod 81 can rotate circumferentially outside the positioning worm 82, and at the same time, because the connecting curved rod 81 is rotationally clamped with the turnover clamping plate 10, the connecting curved rod 81 can drive the transmission mechanism 8 to move back and forth under the limit of the turnover clamping plate 10, so that the transmission mechanism 8 can drive the limit sliding plate 4 and the positioning sliding plate 7 to move back and forth on the upper portion of the guide sliding rail 9, thereby facilitating the subsequent rapid equidistant cutting operation of the supplied raw materials,

as shown in fig. 1, 3, 4 and 5, when the drive mechanism 16 rotates the toothed belt 1, at this time, the toothed belt 1 can drive the adjusting mechanism 3 to rotate at the bottom of the positioning sliding plate 7 through the first belt pulley 33, meanwhile, the upper part of the guide mechanism 5 is in sliding clamping connection with the guide cylinder 2 through the guide slide block 53, thereby enabling the guide mechanism 5 to perform vertical up-and-down displacement only inside the guide cylinder 2 and the adjusting mechanism 3, when the toothed belt 1 drives the whole adjusting mechanism 3 to rotate through the first belt pulley 33, the inserting shaft 35 inside the limiting snap ring 34 can be limited inside the supporting chute 54 at the moment, and then when the adjusting mechanism 3 rotates, the plug-in shaft 35 can drive the guiding mechanism 5 to move up and down circularly inside the guiding cylinder 2 and the adjusting mechanism 3 through the supporting chute 54, thereby facilitating the subsequent quick cutting operation of the raw materials.

When the turning clamp plate 10 is superposed with the connecting curved rod 81 during cutting, the limiting sliding plate 4 and the positioning sliding plate 7 are displaced to the forefront part, the cutting tool 51 at the bottom of the guide mechanism 5 can accurately cut the raw material, and when the turning clamp plate 10 is horizontal to the connecting curved rod 81, the limiting sliding plate 4 and the positioning sliding plate 7 are displaced to the rearmost part, and the cutting tool 51 is positioned at the highest position, so that the follow-up forward cutting is facilitated, and the accuracy of the follow-up equidistant cutting is improved,

if the raw materials with different lengths at the position needing to be cut are required to be cut, when the adjustment is carried out, a user can rotate the hexagonal clamping plate 104 through an external tool, at the moment, the limiting clamping head 101 and the positioning plug 103 are limited by the guide sliding rod 102 and move inwards or outwards along the radial direction of the bidirectional screw rod 105, so that the relative position of the positioning support plate 6 relative to the guide sliding rail 9 is adjusted, the subsequent cutting of the raw materials with different lengths is facilitated, a sufficient limiting foundation is provided, and the adaptability of the device is improved.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides an equidistance cutting mechanism for industrial production which characterized in that: comprises a toothed belt (1), a guide cylinder (2), an adjusting mechanism (3), a limiting sliding plate (4), a guide mechanism (5), a positioning support plate (6), a positioning sliding plate (7), a transmission mechanism (8), a guide sliding rail (9), a turnover clamping plate (10), a limiting clamping seat (11), a connecting motor (12), a transmission rotating shaft (13), a limiting clamping plate (14), a turbine sleeve shaft (15) and a transmission mechanism (16),

a positioning sliding plate (7) for supporting is slidably clamped on the upper end face of the guide sliding rail (9), a positioning support plate (6) is fixedly arranged on the upper end face of the positioning sliding plate (7), a limiting sliding plate (4) is fixedly arranged at one end, deviating from the positioning sliding plate (7), of the side end face of the positioning support plate (6), a limiting clamping seat (11) is fixedly arranged at the position, close to the end head, of the upper end face of the guide sliding rail (9), a connecting motor (12) is fixedly arranged at the center of the rear end face of the limiting clamping seat (11), a transmission rotating shaft (13) for guiding is fixedly connected at the center of the front end face of the connecting motor (12), a limiting clamping plate (14) is fixedly arranged on the outer end face of the transmission rotating shaft (13), and a turbine sleeve shaft (15) is slidably clamped on the outer end face of the transmission rotating shaft (13) through the limiting clamping plate (14), the turbine sleeve shaft (15) is rotatably clamped on the inner end face of the positioning sliding plate (7), the side end face of the positioning sliding plate (7) is rotatably clamped with a transmission mechanism (8) at a position close to the center, the outer end face of the transmission mechanism (8) is rotatably clamped with a turnover clamping plate (10), the transmission mechanism (8) is rotatably clamped with the outer part of the limiting clamping seat (11) through the turnover clamping plate (10), the bottom end face of the positioning support plate (6) is rotatably clamped with a transmission mechanism (16), the turbine sleeve shaft (15) is in meshing rotating connection with the transmission mechanism (16), the center of the upper end face of the positioning support plate (6) is fixedly provided with a guide cylinder (2) for guiding, the center of the lower end face of the positioning support plate (6) is rotatably clamped with an adjusting mechanism (3), and the transmission mechanism (16) and the adjusting mechanism (3) are rotatably connected through a belt (1), a guide mechanism (5) is slidably clamped on the inner end surface of the adjusting mechanism (3) through a guide cylinder (2),

drive mechanism (16) include spacing calorie of axle (161), fixed turbine (162) and second belt pulley (163), the lower terminal surface center department fixed mounting of spacing calorie of axle (161) has fixed turbine (162) that are used for the transmission, and is located the bottom end face center department fixed mounting of fixed turbine (162) has second belt pulley (163).

2. The equidistant cutting mechanism for industrial production according to claim 1, characterized in that: adjustment mechanism (3) are including direction chuck (31), spacing commentaries on classics board (32), first belt pulley (33), spacing snap ring (34), grafting axle (35) and bracing piece (36), the lower terminal surface center department fixed mounting of spacing commentaries on classics board (32) has direction chuck (31) that are used for the support, and is located the lower terminal surface center department fixed mounting of direction chuck (31) has and is used for driven first belt pulley (33), the even equidistance fixedly connected with four groups of bracing pieces (36) that are used for the support of lower terminal surface of first belt pulley (33), and is located the spacing snap ring of bottom face fixedly connected with (34) of bracing piece (36), the interior terminal surface center department fixed mounting of spacing snap ring (34) has grafting axle (35).

3. The equidistant cutting mechanism for industrial production according to claim 2, characterized in that: guiding mechanism (5) are including cutting tool (51), location slide shaft (52), direction slider (53) and support spout (54), the even equidistance fixedly connected with four groups of direction slider (53) that are used for spacingly of the side end face top of location slide shaft (52), and are located support spout (54) have been seted up to the outer terminal surface of location slide shaft (52), the bottom end face fixed mounting of location slide shaft (52) has cutting tool (51) that are used for the sanction to divide.

4. The equidistant cutting mechanism for industrial production according to claim 3, characterized in that: drive mechanism (8) are including connecting curved bar (81), location turbine (82) and grafting pivot (83), a side end center department fixed mounting of location turbine (82) has connection curved bar (81) that are used for the direction, and is located another side end center department fixed mounting of location turbine (82) has grafting pivot (83).

5. The equidistant cutting mechanism for industrial production according to claim 4, characterized in that: turbine sleeve axle (15) include worm casing, side end face symmetry fixed connection at the spacing sleeve of worm casing and set up the support spout in worm casing and spacing sleeve outside, support spout and spacing cardboard (14) looks adaptation, just turbine sleeve axle (15) are through supporting spout and spacing cardboard (14) looks adaptation and then the outside of slip joint in transmission pivot (13), the support sleeve is laminated with the inner wall of location slide (7) and is connected.

6. The equidistant cutting mechanism for industrial production according to claim 5, characterized in that: the side end face of the positioning sliding plate (7) is provided with a rotating shaft groove close to the center, the transmission mechanism (8) is matched with the rotating shaft groove through an inserting rotating shaft (83) and then is rotatably clamped on the side end face of the positioning sliding plate (7), and the lower end face of the turbine sleeve shaft (15) is meshed with the positioning turbine (82) to be rotatably connected.

7. The equidistant cutting mechanism for industrial production according to claim 4, characterized in that: the lower end face of the positioning support plate (6) is provided with a clamping groove right opposite to the guide cylinder (2), the clamping groove and the cross section of the limiting rotating plate (32) are arranged in a T shape, and the adjusting mechanism (3) rotates through the clamping groove and is clamped on the bottom end face of the positioning support plate (6).

8. The equidistant cutting mechanism for industrial production according to claim 7, characterized in that: the diameter of the plug-in shaft (35) is the same as the width of the supporting sliding groove (54), the adjusting mechanism (3) is matched with the supporting sliding groove (54) through the plug-in shaft (35) and then is in sliding clamping connection with the guide mechanism (5), and the guide mechanism (5) is in sliding clamping connection with the inner end face of the guide cylinder (2) through the guide sliding block (53).

9. The equidistant cutting mechanism for industrial production according to claim 4, characterized in that: the novel guide screw rod structure is characterized in that the guide screw rod structure (10) comprises a limiting clamping head (101), a guide sliding rod (102), a positioning plug (103), a hexagonal clamping plate (104) and a bidirectional screw rod (105), the side end face of the bidirectional screw rod (105) is in threaded sliding connection with the limiting clamping head (101) and the positioning plug (103), the guide sliding rod (102) is symmetrically and slidably clamped between the limiting clamping head (101) and the positioning plug (103), and the hexagonal clamping plate (104) is fixedly mounted at the center of the outer end face of the bidirectional screw rod (105).

10. The equidistant cutting mechanism for industrial production according to claim 9, characterized in that: the turnover clamping plate (10) is rotatably clamped with the limiting clamping seat (11) through a limiting clamping head (101) of the limiting clamping head, and the turnover clamping plate (10) is rotatably clamped with the connecting curved rod (81) through a positioning plug (103).

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