CN212888287U - Brick installation mechanism of numerical control lathe cutting machine - Google Patents

Brick installation mechanism of numerical control lathe cutting machine Download PDF

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Publication number
CN212888287U
CN212888287U CN202021013709.2U CN202021013709U CN212888287U CN 212888287 U CN212888287 U CN 212888287U CN 202021013709 U CN202021013709 U CN 202021013709U CN 212888287 U CN212888287 U CN 212888287U
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CN
China
Prior art keywords
rotating rod
sliding
empty groove
rack
hole
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Expired - Fee Related
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CN202021013709.2U
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Chinese (zh)
Inventor
石小传
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Qidong Jingqi Machinery Co ltd
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Qidong Jingqi Machinery Co ltd
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Priority to CN202021013709.2U priority Critical patent/CN212888287U/en
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Publication of CN212888287U publication Critical patent/CN212888287U/en
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Abstract

The utility model belongs to the technical field of cutting machines, in particular to a brick mounting mechanism of a numerical control lathe cutting machine, aiming at the problem that the brick is not convenient to be fixed in the brick cutting process of the prior numerical control lathe cutting machine, the utility model provides a scheme which comprises a workbench, two symmetrical upright posts are fixedly arranged at the top of the workbench, a motor is fixedly arranged at one side of each upright post, a first through hole is arranged on each upright post, a first rotating rod is rotationally arranged in the first through hole, a saw blade is fixedly sleeved on each first rotating rod, a rectangular block is fixedly arranged at the top of the workbench, a first chute is arranged at the top of each rectangular block, a first slide block is slidably arranged in each first chute, a first empty groove is arranged in each rectangular block, a first rack is fixedly arranged in each first empty groove, a second empty groove is arranged at one side of each first slide block, the brick can be conveniently fixed in the brick cutting process of the numerical control lathe cutting machine, simple structure and convenient use.

Description

Brick installation mechanism of numerical control lathe cutting machine
Technical Field
The utility model relates to a cutting machine technical field especially relates to a brick installation mechanism of numerical control lathe cutting machine.
Background
The traditional cutting machine serving as a cutting tool has a wide application range, can be used for cutting a plurality of metal or nonmetal materials, and is fast and convenient to cut.
In the prior art, a numerical control lathe cutting machine is inconvenient for fixing bricks in the brick cutting process, and therefore a brick mounting mechanism of the numerical control lathe cutting machine is provided for solving the problems.
SUMMERY OF THE UTILITY MODEL
The utility model aims at solving the shortcoming of fixed brick of being not convenient for of numerical control lathe cutting machine at the in-process of cutting brick, and the brick installation mechanism of a numerical control lathe cutting machine who provides.
In order to achieve the above purpose, the utility model adopts the following technical scheme:
a brick mounting mechanism of a numerical control lathe cutting machine comprises a workbench, wherein two symmetrical stand columns are fixedly mounted at the top of the workbench, a motor is fixedly mounted on one side of each stand column, a first through hole is formed in each stand column, a first rotating rod is rotatably mounted in each first through hole, a saw blade is fixedly sleeved on each first rotating rod, a rectangular block is fixedly mounted at the top of the workbench, a first sliding groove is formed in the top of each rectangular block, a first sliding block is slidably mounted in each first sliding groove, a first hollow groove is formed in each rectangular block, a first rack is fixedly mounted in each first hollow groove, a second hollow groove is formed in one side of each first sliding block, a second through hole is formed in the side wall of each first sliding groove, each second through hole is communicated with the first hollow groove and the second hollow groove, and a second rotating rod is rotatably mounted in each second through hole;
a third empty groove is formed in the top of the workbench, an air cylinder is fixedly installed in the third empty groove, a third through hole is formed in the inner wall of the bottom of the first sliding groove and communicated with the third empty groove, an output shaft of the air cylinder is fixedly connected with the bottom of the first sliding block, a fixing plate is fixedly installed at the top of the first sliding block, two symmetrical second sliding grooves are formed in the top of the fixing plate, a second sliding block is installed in each of the two second sliding grooves in a sliding mode, a fourth empty groove is formed in the fixing plate, a fourth through hole is formed in the side wall of each fourth sliding groove and communicated with the two second sliding grooves, a second rack and a third rack are installed in the two fourth through holes in a sliding mode, one end of each of the second rack and the third rack is fixedly connected with one side of each of the two second sliding blocks, a fifth through hole is formed in the bottom of the fourth empty groove and communicated with the second empty groove, a third rotating rod is installed in the fifth, and a second bevel gear is fixedly arranged at one end of the third rotating rod, which is positioned in the second empty groove.
Preferably, first bearings are fixedly mounted on one sides of the two stand columns, inner rings of the two first bearings are fixedly connected with the outer sides of the first rotating rods, second bearings are fixedly mounted on the side walls of the second empty grooves, inner rings of the second bearings are fixedly connected with the outer sides of the second rotating rods, third bearings are fixedly mounted on the inner walls of the bottoms of the fourth empty grooves, and inner rings of the third bearings are fixedly connected with the outer sides of the third rotating rods.
Preferably, one end of the second rotating rod, which is located in the first empty groove, is fixedly provided with a first gear, the first gear is meshed with the first rack, a first bevel gear is fixedly sleeved on the second rotating rod, and the first bevel gear is meshed with the second bevel gear.
Preferably, one end of the third rotating rod, which is located in the fourth empty groove, is fixedly provided with a second gear, and the second gear is meshed with the second rack and the third rack.
Preferably, the one end of two springs of the equal fixedly connected with symmetry in one side that two second sliders are close to each other, the other end fixedly connected with fixed block of two springs has all seted up the guide way on two second sliders, equal slidable mounting has the guide bar in the guide way, the one end of two guide bars respectively with one side fixed connection of two fixed blocks.
Compared with the prior art, the utility model has the advantages of:
1. this scheme can be through opening the cylinder, and then first rack makes first gear revolve, and first bevel gear drives second bevel gear, and the second gear drives second rack and third rack removal to brick can be fixed to two fixed blocks.
2. This scheme can be through opening the motor, and then the motor drives first bull stick and rotates, and first bull stick drives the saw bit and rotates to the saw bit can cut the brick.
The utility model discloses can be at the convenient fixed brick of in-process of cutting the brick of numerical control lathe cutting machine, simple structure, convenient to use.
Drawings
Fig. 1 is a schematic structural diagram of a brick mounting mechanism of a numerically controlled lathe cutting machine according to the present invention;
fig. 2 is an enlarged schematic structural diagram of a portion a of a brick mounting mechanism diagram 1 of a numerically controlled lathe cutting machine according to the present invention;
FIG. 3 is an enlarged schematic structural view of a portion B of a brick mounting mechanism diagram 1 of the numerical control lathe cutting machine according to the present invention;
fig. 4 is a schematic structural diagram of the second rack and the third rack of the brick mounting mechanism and the second gear of the numerical control lathe cutting machine according to the present invention.
In the figure: 1 workbench, 2 columns, 3 motors, 4 first rotating rods, 5 saw blades, 6 air cylinders, 7 rectangular blocks, 8 first sliding blocks, 9 fixing plates, 10 second sliding blocks, 11 springs, 12 fixing blocks, 13 first racks, 14 second rotating rods, 15 first gears, 16 first bevel gears, 17 second bevel gears, 18 third rotating rods, 19 second racks, 20 second gears, 21 third racks and 22 guide rods.
Detailed Description
The technical solutions in the embodiments will be described clearly and completely with reference to the drawings in the embodiments, and it is obvious that the described embodiments are only a part of the embodiments, but not all embodiments.
Example one
Referring to fig. 1-4, a brick mounting mechanism of a numerical control lathe cutting machine comprises a workbench 1, wherein two symmetrical upright posts 2 are fixedly mounted at the top of the workbench 1, a motor 3 is fixedly mounted at one side of each upright post 2, a first through hole is formed in each upright post 2, a first rotating rod 4 is rotatably mounted in each first through hole, a saw blade 5 is fixedly sleeved on each first rotating rod 4, a rectangular block 7 is fixedly mounted at the top of the workbench 1, a first sliding groove is formed in the top of each rectangular block 7, a first sliding block 8 is slidably mounted in each first sliding groove, a first hollow groove is formed in each rectangular block 7, a first rack 13 is fixedly mounted in each first hollow groove, a second hollow groove is formed in one side of each first sliding block 8, a second through hole is formed in the side wall of each first sliding groove, each second through hole is communicated with the first hollow groove and the second hollow groove, and a second rotating rod 14 is rotatably mounted in;
the top of the workbench 1 is provided with a third empty groove, an air cylinder 6 is fixedly arranged in the third empty groove, the inner wall of the bottom of the first sliding groove is provided with a third through hole which is communicated with the third empty groove, an output shaft of the air cylinder 6 is fixedly connected with the bottom of the first sliding block 8, the top of the first sliding block 8 is fixedly provided with a fixing plate 9, the top of the fixing plate 9 is provided with two symmetrical second sliding grooves, the two second sliding grooves are internally and slidably provided with second sliding blocks 10, the fixing plate 9 is internally provided with a fourth empty groove, the side wall of the fourth sliding groove is provided with a fourth through hole which is respectively communicated with the two second sliding grooves, a second rack 19 and a third rack 21 are respectively and slidably arranged in the two fourth through holes, one end of the second rack 19 and one end of the third rack 21 are respectively and fixedly connected with one side of the two second sliding blocks 10, the bottom of the fourth empty groove is provided with a fifth through hole which is communicated with the second, a third rotating rod 18 is rotatably arranged in the fifth through hole, and a second bevel gear 17 is fixedly arranged at one end of the third rotating rod 18 positioned in the second empty groove.
In this embodiment, first bearings are fixedly mounted on one sides of the two columns 2, inner rings of the two first bearings are fixedly connected with the outer side of the first rotating rod 4, a second bearing is fixedly mounted on the side wall of the second empty groove, an inner ring of the second bearing is fixedly connected with the outer side of the second rotating rod 14, a third bearing is fixedly mounted on the inner wall of the bottom of the fourth empty groove, and an inner ring of the third bearing is fixedly connected with the outer side of the third rotating rod 18.
In this embodiment, a first gear 15 is fixedly installed at one end of the second rotating rod 14 located in the first empty slot, the first gear 15 is engaged with the first rack 13, a first bevel gear 16 is fixedly sleeved on the second rotating rod 14, and the first bevel gear 16 is engaged with the second bevel gear 17.
In this embodiment, a second gear 20 is fixedly installed at one end of the third rotating rod 18 located in the fourth empty slot, and the second gear 20 is meshed with the second rack 19 and the third rack 21.
In this embodiment, two second sliders 10 are close to each other the equal fixedly connected with in one side one end of two springs 11 of symmetry, and two springs 11's the other end fixedly connected with fixed block 12 have all been seted up the guide way on two second sliders 10, and equal slidable mounting has guide bar 22 in the guide way, two guide bar 22's one end respectively with one side fixed connection of two fixed blocks 12.
Example two
Referring to fig. 1-4, a brick mounting mechanism of a numerical control lathe cutting machine comprises a workbench 1, two symmetrical upright posts 2 are fixedly mounted at the top of the workbench 1 through welding, a motor 3 is fixedly mounted at one side of each upright post 2 through welding, a first through hole is formed in each upright post 2, a first rotating rod 4 is rotatably mounted in each first through hole, a saw blade 5 is sleeved on each first rotating rod 4 through welding, a rectangular block 7 is fixedly mounted at the top of the workbench 1 through welding, a first sliding groove is formed in the top of each rectangular block 7, a first sliding block 8 is slidably mounted in each first sliding groove, a first hollow groove is formed in each rectangular block 7, a first rack 13 is fixedly mounted in each first hollow groove through welding, a second hollow groove is formed in one side of each first sliding block 8, a second through hole is formed in the side wall of each first sliding groove, and is communicated with the first hollow groove and the second hollow groove, a second rotating rod 14 is rotatably arranged in the second through hole;
the top of the workbench 1 is provided with a third empty groove, an air cylinder 6 is fixedly arranged in the third empty groove by welding, a third through hole is arranged on the inner wall of the bottom of the first sliding groove and is communicated with the third empty groove, an output shaft of the air cylinder 6 is fixedly connected with the bottom of the first sliding block 8 by welding, a fixing plate 9 is fixedly arranged at the top of the first sliding block 8 by welding, two symmetrical second sliding grooves are arranged at the top of the fixing plate 9, a second sliding block 10 is arranged in each of the two second sliding grooves in a sliding manner, a fourth empty groove is arranged in the fixing plate 9, a fourth through hole is arranged on the side wall of each fourth sliding groove and is respectively communicated with the two second sliding grooves, a second rack 19 and a third rack 21 are respectively arranged in each of the two fourth through holes in a sliding manner, one end of each of the second rack 19 and the third rack 21 is fixedly connected with one side of each of, and a fifth through hole is formed in the bottom of the fourth empty groove, the fifth through hole is communicated with the second empty groove, a third rotating rod 18 is rotatably arranged in the fifth through hole, and a second bevel gear 17 is fixedly arranged at one end, located in the second empty groove, of the third rotating rod 18 through welding.
In this embodiment, first bearings are all installed on one side of two stand columns 2 through welded fastening, the inner rings of the two first bearings are connected with the outer side of the first rotating rod 4 through welded fastening, the side wall of the second empty groove is provided with a second bearing through welded fastening, the inner rings of the second bearings are connected with the outer side of the second rotating rod 14 through welded fastening, the inner wall of the bottom of the fourth empty groove is provided with a third bearing through welded fastening, the inner rings of the third bearings are connected with the outer side of the third rotating rod 18 through welded fastening, when the first rotating rod 4 and the second rotating rod 14 rotate with the third rotating rod 18, the two first bearings play a role of stabilizing the first rotating rod 4, the second bearing plays a role of stabilizing the second rotating rod 14, and the third bearing plays a role of stabilizing the third rotating rod 18.
In this embodiment, a first gear 15 is fixedly installed at one end of the second rotating rod 14 located in the first empty groove by welding, the first gear 15 is engaged with the first rack 13, a first bevel gear 16 is fixedly installed on the second rotating rod 14 by welding, the first bevel gear 16 is engaged with the second bevel gear 17, when the first slider 8 moves, the first rack 13 can make the first gear 15 rotate, and the first bevel gear 16 drives the second bevel gear 17.
In this embodiment, a second gear 20 is fixedly installed at one end of the third rotating rod 18 located in the fourth empty slot by welding, the second gear 20 is engaged with the second rack 19 and the third rack 21, and when the third rotating rod 18 rotates, the second gear 20 drives the second rack 19 and the third rack 21 to move.
In this embodiment, one side that two second sliders 10 are close to each other all is through the one end of two springs 11 of welded fastening connection symmetry, the other end of two springs 11 is through welded fastening connection fixed block 12, the guide way has all been seted up on through two second sliders 10, equal slidable mounting has guide bar 22 in the guide way, the one end of two guide bars 22 respectively with one side fixed connection's of two fixed blocks 12 setting, when two fixed blocks 12 and brick contact atress, two guide bars 22 play the effect that two fixed blocks 12 are not cheap of stabilizing respectively.
In this embodiment, when in use, a brick is placed on the fixing plate 9, then the motor 3 is turned on, the motor 3 drives the first rotating rod 4 to rotate, the first rotating rod 4 drives the saw blade 5 to rotate, then the cylinder 6 is turned on, the cylinder 6 drives the first slider 8 to move upward, the first rack 13 drives the first gear 15 to rotate, the first gear 15 drives the second rotating rod 14 to rotate, the second rotating rod 14 drives the first bevel gear 16 to rotate, the first bevel gear 16 drives the second bevel gear 17 to rotate, the second bevel gear 17 drives the third rotating rod 18 to rotate, the third rotating rod 18 drives the second gear 20 to rotate, the second gear 20 drives the second rack 19 and the third rack 21 to move, the second rack 19 and the third rack 21 respectively drive the two second sliders 10 to move, the two second sliders 10 respectively drive the two springs 11 to move, the four springs 11 respectively drive the two fixing blocks 12 to move, the four springs 11 play a role in buffering in the process of rising the brick, and then the two fixing blocks 12 can fix the brick, so that the saw blade 5 can cut the brick, when the brick is used, the motor 3 is turned off, then the cylinder 6 is turned on to rotate reversely, the cylinder 6 drives the first slider 8 to move downwards, the first rack 13 drives the first gear 15 to rotate, the first gear 15 drives the second rotating rod 14 to rotate, the second rotating rod 14 drives the first bevel gear 16 to rotate, the first bevel gear 16 drives the second bevel gear 17 to rotate, the second bevel gear 17 drives the third rotating rod 18 to rotate, the third rotating rod 18 drives the second gear 20 to rotate, the second gear 20 drives the second rack 19 and the third rack 21 to move, the second rack 19 and the third rack 21 respectively drive the two second sliders 10 to move, the two second sliders 10 respectively drive the two springs 11 to move, the four springs 11 respectively drive the two fixing blocks 12 to move, and then the two fixed blocks 12 loosen the brick so that the brick can be replaced to be cut again.
The above descriptions are only preferred embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the scope of the present invention, and the technical solutions and the utility model concepts of the present invention are equivalent to, replaced or changed.

Claims (5)

1. A brick mounting mechanism of a numerical control lathe cutting machine comprises a workbench (1) and is characterized in that two symmetrical upright posts (2) are fixedly mounted at the top of the workbench (1), a motor (3) is fixedly mounted at one side of each upright post (2), a first through hole is formed in each upright post (2), a first rotating rod (4) is rotatably mounted in each first through hole, a saw blade (5) is fixedly sleeved on each first rotating rod (4), a rectangular block (7) is fixedly mounted at the top of the workbench (1), a first sliding chute is formed in the top of each rectangular block (7), a first sliding block (8) is slidably mounted in each first sliding chute, a first empty groove is formed in each rectangular block (7), a first rack (13) is fixedly mounted in each first empty groove, a second empty groove is formed in one side of each first sliding block (8), a second through hole is formed in the side wall of each first sliding chute, and is communicated with the first empty grooves and the second empty grooves, a second rotating rod (14) is rotatably arranged in the second through hole;
a third empty groove is formed in the top of the workbench (1), an air cylinder (6) is fixedly installed in the third empty groove, a third through hole is formed in the inner wall of the bottom of the first sliding groove and communicated with the third empty groove, an output shaft of the air cylinder (6) is fixedly connected with the bottom of the first sliding block (8), a fixing plate (9) is fixedly installed at the top of the first sliding block (8), two symmetrical second sliding grooves are formed in the top of the fixing plate (9), second sliding blocks (10) are installed in the two second sliding grooves in a sliding mode, a fourth empty groove is formed in the fixing plate (9), a fourth through hole is formed in the side wall of the fourth sliding groove, the two fourth through holes are respectively communicated with the two second sliding grooves, a second rack (19) and a third rack (21) are installed in the two fourth through holes in a sliding mode, one end of the second rack (19) and one end of the third rack (21) are respectively fixedly connected with one side of the two second sliding blocks, a fifth through hole is formed in the bottom of the fourth empty groove and communicated with the second empty groove, a third rotating rod (18) is rotatably mounted in the fifth through hole, and a second bevel gear (17) is fixedly mounted at one end, located in the second empty groove, of the third rotating rod (18).
2. The brick mounting mechanism of the numerical control lathe cutting machine as claimed in claim 1, wherein a first bearing is fixedly mounted on one side of each of the two upright columns (2), the inner rings of the two first bearings are fixedly connected with the outer side of the first rotating rod (4), a second bearing is fixedly mounted on the side wall of the second empty groove, the inner ring of the second bearing is fixedly connected with the outer side of the second rotating rod (14), a third bearing is fixedly mounted on the inner wall of the bottom of the fourth empty groove, and the inner ring of the third bearing is fixedly connected with the outer side of the third rotating rod (18).
3. The brick mounting mechanism of the numerical control lathe cutting machine as claimed in claim 1, wherein one end of the second rotating rod (14) located in the first empty groove is fixedly provided with a first gear (15), the first gear (15) is meshed with the first rack (13), a first bevel gear (16) is fixedly sleeved on the second rotating rod (14), and the first bevel gear (16) is meshed with a second bevel gear (17).
4. The brick mounting mechanism of the numerical control lathe cutting machine as claimed in claim 1, wherein one end of the third rotating rod (18) positioned in the fourth empty groove is fixedly provided with a second gear (20), and the second gear (20) is meshed with a second rack (19) and a third rack (21).
5. The brick mounting mechanism of the numerical control lathe cutting machine according to claim 1, characterized in that one side of each of the two second sliding blocks (10) close to each other is fixedly connected with one end of two symmetrical springs (11), the other end of each of the two springs (11) is fixedly connected with a fixed block (12), each of the two second sliding blocks (10) is provided with a guide groove, each of the guide grooves is slidably mounted with a guide rod (22), and one end of each of the two guide rods (22) is fixedly connected with one side of each of the two fixed blocks (12).
CN202021013709.2U 2020-06-05 2020-06-05 Brick installation mechanism of numerical control lathe cutting machine Expired - Fee Related CN212888287U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202021013709.2U CN212888287U (en) 2020-06-05 2020-06-05 Brick installation mechanism of numerical control lathe cutting machine

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202021013709.2U CN212888287U (en) 2020-06-05 2020-06-05 Brick installation mechanism of numerical control lathe cutting machine

Publications (1)

Publication Number Publication Date
CN212888287U true CN212888287U (en) 2021-04-06

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Application Number Title Priority Date Filing Date
CN202021013709.2U Expired - Fee Related CN212888287U (en) 2020-06-05 2020-06-05 Brick installation mechanism of numerical control lathe cutting machine

Country Status (1)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114522921A (en) * 2022-02-25 2022-05-24 罗方 Cleaning system is used in automobile mold processing

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114522921A (en) * 2022-02-25 2022-05-24 罗方 Cleaning system is used in automobile mold processing

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Granted publication date: 20210406