CN111844472A

CN111844472A - Automatic equidistant cutting equipment for glass blocks

Info

Publication number: CN111844472A
Application number: CN202010688732.XA
Authority: CN
Inventors: 刘建华
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-07-16
Filing date: 2020-07-16
Publication date: 2020-10-30

Abstract

The invention relates to glass processing equipment, in particular to automatic equidistant cutting equipment for glass blocks. The technical problems of the invention are as follows: the automatic equidistant cutting equipment for the glass blocks is capable of avoiding the scratch of the manual hands by the glass, keeping the glass blocks straight and equal in cutting length in the cutting process. The technical implementation scheme of the invention is as follows: an automatic equidistant cutting device for glass blocks comprises a placing plate, wherein two sides of the placing plate are provided with placing wheels; the support, one side on placing the board is located to the support, and the support keeps away from and places board one side position department and be equipped with the mounting bracket, and the support is nearly placed board one side position department and is equipped with the support frame. According to the glass cutting device, the first belt transmission assembly drives the pushing plate to push the glass in a mode of placing the glass on the placing plate, and the diamond cutter cuts the glass, so that the glass does not need to be directly participated in the cutting process, and the glass is prevented from being scratched by manpower.

Description

Automatic equidistant cutting equipment for glass blocks

Technical Field

The invention relates to glass processing equipment, in particular to automatic equidistant cutting equipment for glass blocks.

Background

At present to glass add man-hour, there is a step to need to cut into the equal segment of length to a piece of glass to deal with large batch glassware production, but at present when cutting to glass add man-hour, a lot of adopt artifical handheld diamond sword to cut open glass, carry out the hammering at handheld hammer utensil to glass, make glass can be peeled off, but the artificial hand of the easy messenger of this mode of sampling is scratched, and in the in-process that uses diamond sword to cut open glass, even also be difficult to guarantee straight going on with the flat ruler, and can not make glass cut into isometric segment.

In view of the above disadvantages, there is a need to design an automatic equidistant cutting device for glass blocks, which can prevent the hand from being scratched by the glass, keep the hand straight during the cutting process, and have the same cutting length, so as to overcome the disadvantages of easy scratching of the hand during the glass cutting process, incapability of ensuring the hand straight during the cutting process, and difficulty in consistency of the cutting length.

Disclosure of Invention

In order to overcome the defects that the manual hand is easily scratched, the straightness cannot be ensured in the cutting process and the cutting length is difficult to be consistent in the existing glass cutting process, the technical problems of the invention are as follows: the automatic equidistant cutting equipment for the glass blocks is capable of avoiding the scratch of the manual hands by the glass, keeping the glass blocks straight and equal in cutting length in the cutting process.

The technical implementation scheme of the invention is as follows: an automatic equidistant cutting device for glass blocks comprises a placing plate, wherein two sides of the placing plate are provided with placing wheels; the bracket is arranged on one side of the placing plate, the position of the bracket, which is far away from the placing plate, is provided with the mounting bracket, and the position of the bracket, which is close to the placing plate, is provided with the support frame; the cutting device is arranged between the mounting frames and is used for cutting the glass; the transmission device is arranged between the mounting frames and is far away from one side of the placing plate, the transmission device is connected with the cutting device, and the transmission device is used for driving the equipment to work; and the propelling device is arranged between the support frames and is connected with the transmission device, and the propelling device is used for propelling the glass to advance.

Optionally, the cutting device comprises a first guide rail, the first guide rail is arranged between the mounting frames, a first guide sleeve is sleeved on the first guide rail, and a moving frame is arranged on the first guide sleeve; the connecting block is arranged on the moving frame at a position close to one side of the transmission device and is connected with the transmission device; the second guide sleeve is arranged on the movable frame at a position close to one side of the placing plate, a second guide rail is sleeved in the second guide sleeve, and a first fastening bolt is arranged on the second guide sleeve; and the diamond knife is arranged on the other side of the second guide rail, and the tool bit of the diamond knife faces the running direction of the diamond knife.

Optionally, the transmission device comprises supporting seats, the supporting seats are respectively arranged on two sides of the mounting frame, the supporting seats are rotatably connected with first rotating shafts, a first belt transmission assembly is arranged between the first rotating shafts, and the connecting block is connected with the first belt transmission assembly; the first toothed belt is arranged on the first belt transmission assembly and connected with the propelling device, and a servo motor is arranged on one side of the mounting frame and connected with a group of first rotating shafts.

Optionally, the propelling device comprises mounting plates, the mounting plates are respectively arranged on two sides of the support frame at a position close to one side of the placing plate, a third guide rail is arranged between the mounting plates, and a third guide sleeve is sleeved on the third guide rail; the pushing plate is arranged on the third guide sleeve at a position close to one side of the placing plate; the screw rod is rotatably arranged between the mounting plates, a nut is screwed on the screw rod, and the nut is connected with the third guide sleeve; the second rotating shaft is arranged at the position of one side of the screw rod, which is close to the first toothed belt; and the transmission mechanism is arranged between the second rotating shaft and the first toothed belt and is used for transmitting the mechanical energy of the first toothed belt to the second rotating shaft.

Optionally, the transmission mechanism comprises a connecting plate, the connecting plate is arranged on one side of the mounting frame, two groups of third rotating shafts are rotatably connected to the connecting plate, and a first ratchet brake is arranged between the third rotating shafts; a third rotating shaft on one side close to the first toothed belt is provided with a first circular gear, and the first circular gear and the first rack are positioned on the same plane; and the second belt transmission assembly is arranged between the other group of third rotating shafts and the second rotating shaft.

Optionally, the device further comprises a striking device, wherein the striking device comprises fixing seats, and the fixing seats are uniformly distributed on the support frame at positions far away from one side of the support frame; the fourth guide sleeves are all arranged on the fixed seat, fourth guide rails are sleeved on the fourth guide sleeves, elastic pieces are arranged between the fourth guide rails and the fourth guide sleeves, fixed frames are arranged on the fourth guide rails, hitting balls are arranged on the fixed frames at positions close to one side of the placing plate, the fixed frames are connected through connecting plates, and racks are arranged on the connecting plates at positions close to one side of the first belt transmission assembly; the fixed plate is arranged on one side of the mounting rack, two groups of fourth rotating shafts are rotatably arranged on the fixed plate, and a second ratchet backstop is arranged between the fourth rotating shafts; the second circular gear is arranged on the fourth rotating shaft at one side close to the rack and meshed with the rack; and the third circular gear is arranged on a fourth rotating shaft close to one side of the first belt transmission assembly, a second toothed belt is arranged at a position close to the third circular gear on the first belt transmission assembly, and the second toothed belt and the third circular gear are positioned on the same plane.

Optionally, the device further comprises a connecting seat, the connecting seat is arranged on two sides of the placing plate, fifth guide sleeves are arranged on the connecting seat, fifth guide rails are sleeved on the fifth guide sleeves, and second fastening bolts are arranged on the fifth guide sleeves; and the guide wheel is arranged on the fifth guide rail.

Optionally, the first and second belt drive assemblies are belt driven.

Optionally, the resilient member is a straight spring.

The invention has the following advantages: 1. according to the glass cutting device, the first belt transmission assembly drives the pushing plate to push the glass in a mode of placing the glass on the placing plate, and the diamond cutter cuts the glass, so that the glass does not need to be directly participated by manpower in the cutting process, the glass is prevented from being scratched by the manpower, and the length of the glass which is cut each time can be ensured to be consistent.

2. The glass cutting device has the advantages that the mode that the cutting completion glass is hit and peeled off by adopting the first belt transmission assembly to drive the hitting ball in the operation process can enable the glass to be stressed averagely in the separation process, and the glass breaking caused by uneven stress of the glass due to beating of the manual hammer is avoided.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a third perspective view of the present invention.

Fig. 4 is a perspective view of the stent portion of the present invention.

Fig. 5 is a schematic perspective view of the mounting bracket of the present invention.

Fig. 6 is a perspective view of a propulsion device according to the present invention.

Fig. 7 is a partial perspective view of a propulsion device according to the present invention.

Fig. 8 is a perspective view of a portion of the striking device of the present invention.

Fig. 9 is a perspective view of the guide wheel part of the present invention.

The meaning of the reference symbols in the figures: 1: placing plate, 2: placing wheel, 3: support, 4: mounting frame, 5: support frame, 6: cutting device, 7: transmission, 8: propulsion device, 61: first guide rail, 62: first guide bush, 63: moving rack, 64: connecting block, 65: second guide bush, 66: second guide rail, 67: first fastening bolt, 68: diamond blade, 71: support seat, 72: first rotating shaft, 73: first belt drive assembly, 74: first toothed belt, 75: servo motor, 81: mounting plate, 82: third guide rail, 83: third guide bush, 84: thrust plate, 85: screw rod, 86: nut, 87: second rotating shaft, 88: transmission mechanism, 881: connection plate, 882: third rotation shaft, 883: first ratchet backstop, 884: first circular gear, 885: second belt drive assembly, 9: striking device, 91: fixing base, 92: fourth guide bush, 93: fourth guide rail, 94: elastic member, 95: mount, 96: hitting ball, 97: connecting plate, 98: rack, 99: a fixing plate, 910: fourth rotation shaft, 911: second ratchet backstop, 912: second circular gear, 913: third circular gear, 914: second toothed belt, 10: connecting seat, 11: fifth guide bush, 12: fifth guide rail, 13: second fastening bolt, 14: a guide wheel.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings. It is only noted that the invention is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the invention.

Example 1

An automatic equidistance cutting equipment of glass piece, as shown in fig. 1-4, is including placing board 1, placing wheel 2, support 3, mounting bracket 4, support frame 5, cutting device 6, transmission 7 and advancing device 8, specifically is:

place 1 upside left and right sides of board and all be connected with and place wheel 2, place the right-hand front and back both sides of 1 upside of board and all be connected with support 3, be connected with mounting bracket 4 between the 3 upsides of support, support 3 left is connected with support frame 5, is equipped with cutting device 6 between the 4 downside of mounting bracket, is equipped with transmission 7 between the 4 upsides of mounting bracket, is equipped with advancing device 8 between support frame 5.

When glass is required to be cut, the glass can be placed on the placing plate 1, the placing wheel 2 supports the glass, the glass is positioned on the right side of the pushing device 8, the transmission device 7 can be started at the moment, the transmission device 7 drives the cutting device 6 to cut the glass, after the cutting device 6 cuts the glass, the transmission device 7 continues to drive the cutting device 6 to operate, the transmission device 7 starts to drive the pushing device 8 to operate at the moment, so that the pushing device 8 drives the glass to advance towards the right side, when the transmission device 7 operates to an end point, the transmission device 7 drives the cutting device 6 to reset, the transmission device 7 cannot drive the pushing device 8 to operate in the resetting process of the transmission device 7, when the resetting of the transmission device 7 is completed, the cutting device 6 also completes the resetting, at the moment, the transmission device 7 continues to operate, so that the cutting device 6 is driven to cut the glass after the advancing, the previously cut glass can be knocked off and the actuator 7 can be turned off when the glass is cut.

Example 2

An automatic equidistant cutting device for glass blocks is shown in fig. 5-7, wherein a cutting device 6 comprises a first guide rail 61, a first guide sleeve 62, a moving frame 63, a connecting block 64, a second guide sleeve 65, a second guide rail 66, a first fastening bolt 67 and a diamond knife 68, and specifically comprises:

be connected with first guide rail 61 between the mounting bracket 4, first guide rail 61 is last sliding connection has first guide pin bushing 62, be connected with on the first guide pin bushing 62 and remove frame 63, it is connected with connecting block 64 to remove the upside of frame 63, connecting block 64 is connected with transmission 7, it is connected with second guide pin bushing 65 to remove the middle part of frame 63, second guide pin bushing 65 internal sliding type is connected with second guide rail 66, be connected with first fastening bolt 67 on the second guide pin bushing 65, second guide rail 66 downside is connected with buddha's warrior attendant sword 68, the tool bit of buddha's warrior sword 68 is towards the rear.

In operation, the second guide rail 66 can be loosened by the first fastening bolt 67, the height of the second guide rail 66 is moved, so that the height of the diamond cutter 68 can be adjusted to be applied to glass with different thicknesses for cutting, and after the adjustment is completed, the first fastening bolt 67 can be rotated and fastened, so that the positions of the second guide sleeve 65 and the second guide rail 66 are fixed; when the transmission device 7 is operated, the transmission device 7 drives the connecting block 64 to move backward, so that the connecting block 64 drives the moving frame 63 to move backward, the moving frame 63 moves backward on the first guide rail 61 through the first guide sleeve 62, thereby moving the second guide rail 66 to the rear side, thereby moving the diamond blade 68 to the rear side to cut the glass, when the diamond knife 68 finishes the glass cutting, the transmission device 7 will continue to move to the back side, at this time, the transmission device 7 will drive the propelling device 8 to work, thereby pushing the glass to the right, after the glass pushing is finished, the transmission device 7 also starts to enter a reset state, so that the transmission device 7 drives the connecting block 64 and thus the diamond blade 68 to move to the front side, and the diamond blade 68 will not cut the glass because the direction of the cutting head is opposite to the moving direction.

The transmission device 7 comprises a support base 71, a first rotating shaft 72, a first belt transmission assembly 73, a first toothed belt 74 and a servo motor 75, and specifically comprises:

both sides all are connected with supporting seat 71 around the 4 upside of mounting bracket, and equal rotary type is connected with first pivot 72 on supporting seat 71, is connected with first area transmission assembly 73 between the first pivot 72, and connecting block 64 is connected at first area transmission assembly 73 downside, and first area transmission assembly 73 upside left is connected with first cingulum 74, and first cingulum 74 is connected with advancing device 8, and the right-hand servo motor 75 that is connected with of 4 front sides of mounting bracket, servo motor 75 is connected with the first pivot 72 of front side.

When the above embodiment is operated, the servo motor 75 may be started, the servo motor 75 drives the first rotating shaft 72 to rotate counterclockwise, the first rotating shaft 72 drives the first belt transmission assembly 73 to rotate counterclockwise, so that the first belt transmission assembly 73 drives the connecting block 64 to move backward, so as to drive the diamond cutter 68 to move backward to cut glass, when the diamond cutter 68 finishes cutting glass, the first belt transmission assembly 73 will continue to rotate counterclockwise, at this time, the first belt 74 will start to contact with the pushing device 8, so as to enable the first belt 74 to drive the pushing device 8 to work, when the first belt 74 runs to be disconnected from the pushing device 8, the pushing device 8 will stop working, at this time, the servo motor 75 will start to rotate reversely, so as to drive the first belt transmission assembly 73 to rotate clockwise, so as to drive the first belt 74 to move forward, at this time, the first toothed belt 74 does not drive the propelling device 8 to work, and the first belt transmission assembly 73 drives the connecting block 64 to move forward to reset.

The propelling device 8 comprises a mounting plate 81, a third guide rail 82, a third guide sleeve 83, a propelling plate 84, a screw rod 85, a nut 86, a second rotating shaft 87 and a transmission mechanism 88, and specifically comprises:

the left side and the right side of the lower side of the support frame 5 are connected with mounting plates 81, the front portion and the rear portion between the mounting plates 81 are connected with third guide rails 82, third guide sleeves 83 are connected between the third guide rails 82 in a sliding mode, the lower sides of the third guide sleeves 83 are connected with a propelling plate 84, a lead screw 85 is connected between the middle portions of the mounting plates 81 in a rotating mode, a nut 86 is screwed on the lead screw 85, the nut 86 is connected with the third guide sleeves 83, the right side of the lead screw 85 is connected with a second rotating shaft 87, and a transmission mechanism 88 is arranged between the second rotating shaft.

When the first toothed belt 74 contacts with the transmission mechanism 88, the first toothed belt 74 drives the transmission mechanism 88 to work, the transmission mechanism 88 drives the second rotating shaft 87 to rotate, the second rotating shaft 87 drives the screw rod 85 to rotate, so that the screw rod 85 drives the nut 86 to move rightwards, the nut 86 drives the third guide sleeve 83 to move rightwards, the pushing plate 84 is driven to move rightwards, and the glass is driven to move rightwards to move forwards.

The transmission mechanism 88 includes a connecting plate 881, a third rotating shaft 882, a first ratchet backstop 883, a first circular gear 884 and a second belt transmission component 885, and specifically:

The left side of the rear side of the mounting bracket 4 is connected with a connecting plate 881, the front side of the connecting plate 881 is rotatably connected with two third rotating shafts 882, a first ratchet backstop 883 is connected between the third rotating shafts 882, a first circular gear 884 is connected on the right third rotating shaft 882, the first circular gear 884 can be meshed with a first toothed belt 74, and a second belt transmission component 885 is connected between the left third rotating shaft 882 and the second rotating shaft 87.

When the first toothed belt 74 rotates counterclockwise to be engaged with the first circular gear 884, the first toothed belt 74 drives the first circular gear 884 to rotate, the first circular gear 884 enables the first ratchet brake 883 to work through the right third rotating shaft 882, so that the left third rotating shaft 882 drives the second rotating shaft 87 to rotate through the second belt transmission assembly 885, and the screw rod 85 is driven to rotate; when the first toothed belt 74 rotates clockwise to engage with the first circular gear 884, the first ratchet brake 883 will not drive the left third shaft 882 to rotate, and will not drive the lead screw 85 to rotate.

Example 3

On the basis of embodiment 2, as shown in fig. 8 to 9, the present invention further includes a striking device 9, where the striking device 9 includes a fixing seat 91, a fourth guide sleeve 92, a fourth guide rail 93, an elastic member 94, a fixing frame 95, a striking ball 96, a connecting plate 97, a rack 98, a fixing plate 99, a fourth rotating shaft 910, a second ratchet brake 911, a second circular gear 912, a third circular gear 913, and a second toothed belt 914, and specifically:

The right side of the upper side of the support 3 is provided with a striking device 9, the striking device 9 is connected with a first belt transmission component 73, the striking device 9 is used for striking and peeling cut glass, the right side of the upper side of the support 3 is connected with four groups of fixing seats 91, the fixing seats 91 are all connected with fourth guide sleeves 92, the fourth guide sleeves 92 are connected with fourth guide rails 93 in a sliding manner, elastic parts 94 are connected between the fourth guide rails 93 and the fourth guide sleeves 92, the right side of the fourth guide rails 93 is connected with a fixing frame 95, the lower sides of the fixing frames 95 are all connected with striking balls 96, connecting plates 97 are connected between the adjacent fixing frames 95, the left side of the middle connecting plate 97 is connected with a rack 98, the rear side of the mounting frame 4 is connected with a fixing plate 99, the front side of the fixing plate 99 is connected with two fourth rotating shafts 910 in a rotating manner, a second ratchet check device 911, the second circular gear 912 is engaged with the rack 98, the left fourth rotating shaft 910 is connected with a third circular gear 913, the right side of the upper side of the first belt transmission component 73 is connected with a second belt 914, and the second belt 914 is engaged with the third circular gear 913.

When the diamond cutter 68 finishes cutting the glass, and the pushing plate 84 pushes the glass, the pushing plate 84 pushes the cut glass to be located below the striking ball 96, and the first belt transmission assembly 73 drives the first toothed belt 74 to engage with the first circular gear 884, the pushing plate 84 also pushes the glass, at this time, the second toothed belt 914 also engages with the third circular gear 913, so that the third circular gear 913 drives the second circular gear 912 to rotate through the fourth rotating shaft 910 and the second ratchet brake 911, so that the second circular gear 912 drives the rack 98 to move upwards, the rack 98 moves upwards to drive the connecting plate 97 and the fixing frame 95 to move upwards to drive the striking ball 96 to move upwards, at this time, the elastic member 94 enters a stressed state, when the second toothed belt 914 disengages from the third circular gear 913, the elastic member 94 recovers from the stressed state, so as to drive the striking ball 96 to move downwards to finish cutting and strike the stable glass position, so that the glass is peeled off, at this time, the user can collect the peeled glass, when the first belt transmission assembly 73 is rotated clockwise to reset, the second toothed belt 914 drives the third circular gear 913 to rotate reversely, and at this time, the fourth rotating shaft 910 will not drive the second circular gear 912 to rotate through the second ratchet wheel backstop 911.

Still including connecting seat 10, fifth guide pin bushing 11, fifth guide rail 12, second fastening bolt 13 and leading wheel 14, specifically do:

the front side and the rear side of the upper side of the middle part of the placing plate 1 are both connected with connecting seats 10, the connecting seats 10 are both connected with fifth guide sleeves 11, the fifth guide sleeves 11 are internally connected with fifth guide rails 12 in a sliding manner, the fifth guide sleeves 11 are connected with second fastening bolts 13 in a threaded manner, and the upper sides of the fifth guide rails 12 are connected with guide wheels 14.

In operation, when the glass is placed on the placing wheel 2 on the placing plate 1, the height of the guide wheel 14 can be adjusted through the fifth guide sleeve 11 and the fifth guide rail 12, so that the guide wheel 14 is in contact with the upper side of the glass, and then the second fastening bolt 13 is rotated to fix the height of the guide wheel 14, so that the glass has stability in the process of moving.

Further illustrating, the first belt drive assembly 73 and the second belt drive assembly 885 are belt drives.

Further, the elastic member 94 is a straight spring.

Although the present invention has been described in detail with reference to the above embodiments, it will be apparent to those skilled in the art from this disclosure that various changes or modifications can be made herein without departing from the principles and spirit of the invention as defined by the appended claims. Therefore, the detailed description of the embodiments of the present disclosure is to be construed as merely illustrative, and not limitative of the remainder of the disclosure, but rather to limit the scope of the disclosure to the full extent set forth in the appended claims.

Claims

1. An automatic equidistance cutting equipment of glass piece, characterized by including:

the device comprises a placing plate (1), wherein placing wheels (2) are arranged on two sides of the placing plate (1);

the support (3) is arranged on one side of the placing plate (1), an installation frame (4) is arranged at the position of one side of the support (3) far away from the placing plate (1), and a support frame (5) is arranged at the position of one side of the support (3) near the placing plate (1);

the cutting device (6) is arranged between the mounting frames (4), and the cutting device (6) is used for cutting glass;

the transmission device (7) is arranged between the mounting frames (4) and far away from one side of the placing plate (1), the transmission device (7) is connected with the cutting device (6), and the transmission device (7) is used for driving the equipment to work;

and the propelling device (8) is arranged between the support frames (5), the propelling device (8) is connected with the transmission device (7), and the propelling device (8) is used for propelling the glass to advance.

2. An automatic equidistant cutting device for glass panes according to claim 1, characterized in that the cutting means (6) comprise:

the first guide rail (61) is arranged between the mounting frames (4), a first guide sleeve (62) is sleeved on the first guide rail (61), and a moving frame (63) is arranged on the first guide sleeve (62);

The connecting block (64) is arranged on the moving frame (63) at a position close to one side of the transmission device (7), and the connecting block (64) is connected with the transmission device (7);

the second guide sleeve (65), the second guide sleeve (65) is arranged on the moving frame (63) at a position close to one side of the placing plate (1), a second guide rail (66) is sleeved in the second guide sleeve (65), and a first fastening bolt (67) is arranged on the second guide sleeve (65);

and the diamond knife (68), the diamond knife (68) is arranged on the other side of the second guide rail (66), and the tool bit of the diamond knife (68) faces the running direction of the diamond knife.

3. An automatic equidistant cutting device for glass panes according to claim 2, characterized in that the transmission means (7) comprise:

the supporting seats (71), the supporting seats (71) are respectively arranged on two sides of the mounting frame (4), the supporting seats (71) are respectively rotatably connected with first rotating shafts (72), a first belt transmission assembly (73) is arranged between the first rotating shafts (72), and the connecting block (64) is connected with the first belt transmission assembly (73);

first cingulum (74), on first cingulum (74) were located first area transmission unit (73), first cingulum (74) were connected with advancing device (8), and mounting bracket (4) one side is equipped with servo motor (75), and servo motor (75) are connected with a set of first pivot (72).

4. An automatic equidistant cutting device for glass panes according to claim 3, characterized in that the pushing means (8) comprise:

the mounting plates (81) are respectively arranged at two sides of the position, close to one side of the placing plate (1), of the support frame (5), third guide rails (82) are arranged between the mounting plates (81), and third guide sleeves (83) are sleeved on the third guide rails (82);

the pushing plate (84), the pushing plate (84) is arranged on the third guide sleeve (83) at a position close to one side of the placing plate (1);

the screw rod (85), the screw rod (85) is rotatably arranged between the mounting plates (81), a nut (86) is screwed on the screw rod (85), and the nut (86) is connected with the third guide sleeve (83);

the second rotating shaft (87), the second rotating shaft (87) is arranged at one side of the screw rod (85) close to the first toothed belt (74);

and the transmission mechanism (88) is arranged between the second rotating shaft (87) and the first toothed belt (74), and the transmission mechanism (88) is used for transmitting the mechanical energy of the first toothed belt (74) to the second rotating shaft (87).

5. An automatic apparatus for the equidistant cutting of glass panes according to claim 4, characterized in that the transmission means (88) comprise:

The connecting plate (881) is arranged on one side of the mounting frame (4), two groups of third rotating shafts (882) are rotatably connected to the connecting plate (881), and a first ratchet backstop (883) is arranged between the third rotating shafts (882);

a first circular gear (884) is arranged on a third rotating shaft (882) close to one side of the first toothed belt (74), and the first circular gear (884) and the first rack (98) are positioned on the same plane;

a second belt transmission component (885), wherein the second belt transmission component (885) is arranged between the other group of the third rotating shafts (882) and the second rotating shaft (87).

6. An automatic isometric cutting apparatus for glass panes, according to claim 5, further comprising a striking device (9), the striking device (9) comprising:

the fixing seats (91), the fixing seats (91) are uniformly distributed on the side position of the support (3) far away from the support frame (5);

the fourth guide sleeves (92), the fourth guide sleeves (92) are all arranged on the fixed seat (91), the fourth guide sleeves (92) are all sleeved with fourth guide rails (93), elastic pieces (94) are arranged between the fourth guide rails (93) and the fourth guide sleeves (92), the fourth guide rails (93) are provided with fixed frames (95), striking balls (96) are arranged on the fixed frames (95) at positions close to one side of the placing plate (1), the fixed frames (95) are connected through connecting plates (97), and racks (98) are arranged on the connecting plates (97) at positions close to one side of the first belt transmission assembly (73);

The fixing plate (99), the fixing plate (99) is arranged on one side of the mounting frame (4), two groups of fourth rotating shafts (910) are rotatably arranged on the fixing plate (99), and a second ratchet wheel backstop (911) is arranged between the fourth rotating shafts (910);

the second circular gear (912) is arranged on the fourth rotating shaft (910) close to one side of the rack (98), and the second circular gear (912) is meshed with the rack (98);

the third circular gear (913), the third circular gear (913) is located on the fourth rotating shaft (910) near one side of the first belt transmission assembly (73), and a second toothed belt (914) is arranged on the first belt transmission assembly (73) near the third circular gear (913), and the second toothed belt (914) and the third circular gear (913) are located on the same plane.

7. An automated isometric cutting apparatus for glass panes in accordance with claim 6 further comprising:

the connecting seats (10) are arranged on two sides of the placing plate (1), fifth guide sleeves (11) are arranged on the connecting seats (10), fifth guide rails (12) are sleeved on the fifth guide sleeves (11), and second fastening bolts (13) are arranged on the fifth guide sleeves (11);

and the guide wheel (14), the guide wheel (14) is arranged on the fifth guide rail (12).

8. An automated block glass cutting apparatus as claimed in claim 7 wherein the first belt drive assembly (73) and the second belt drive assembly (885) are belt driven.

9. An automated block glass cutting apparatus as claimed in claim 8 wherein the resilient member (94) is a straight spring.