CN117301229A - Assembled building module and processing system - Google Patents

Abstract

The invention relates to the technical field of building module processing, in particular to an assembled building module and a processing system, which comprises a bracket I and a sleeve rotationally connected to the bracket I, wherein a reversing disc is fixedly connected to the sleeve, a plurality of limiting grooves are uniformly formed in the circumference of the reversing disc, a plurality of sliding grooves I are uniformly formed in the circumference of the reversing disc, a rotary table is rotationally connected to the bracket I, a limiting shaft is fixedly connected to the rotary table, the limiting shaft can be rotated into the limiting grooves, the limiting shaft is used for limiting the reversing disc to rotate when the limiting shaft is rotated out of the limiting grooves, a sliding shaft is fixedly connected to the rotary table, the sliding shaft can slide into the sliding grooves I, the sliding shaft and the sliding grooves I are used for driving the reversing disc to rotate, a motor I is fixedly connected to the lower end of the bracket I, and an output shaft of the motor I penetrates through the bracket I.

Description

An assembled building module and processing system

Technical field

The invention relates to the technical field of building module processing, and more specifically to an assembled building module and a processing system.

Background technique

Modular building is an emerging building structure system. This system uses each room as a modular unit, which is prefabricated in the factory. After completion, it is transported to the site and assembled into the building as a whole through reliable connections. The future The building will be a unit structure, like matchboxes, but it will not be limited to a four-sided cube. Each unit body can be polygonal and present different physical structures. These units, which are built using special new energy-saving materials, will be plugged and welded together. The wooden boards are made of complete wood. These boards are durable and have natural textures, making them the best choice for decoration. When assembling wooden building modules, the protrusions and grooves on both sides are used to plug in and fix the wooden building modules. However, there is a lack of a method in the existing technology. A device that can create ridges and grooves on both sides of a wooden board.

Contents of the invention

The invention relates to the technical field of building module processing, and more specifically to an assembled building module and a processing system. The beneficial effect is that protrusions and grooves can be processed on both sides of wooden boards, further improving the production of wooden building blocks. efficiency.

The purpose of the present invention is achieved through the following technical solutions:

An assembled building module and processing system, including a bracket I and a sleeve rotatably connected to the bracket I. A reversing plate is fixedly connected to the sleeve, and a plurality of limit grooves are evenly provided on the reversing plate circumferentially. A plurality of chutes I are evenly arranged on the circumference of the steering wheel.

Further, a turntable is rotatably connected to the bracket I, and a limit shaft is fixedly connected to the turntable. The limit shaft can be rotated into the limit slot. The limit shaft is used to limit the rotation of the reversing plate when it is transferred into the limit slot. The position shaft is used to terminate the restriction on the rotation of the reversing plate when it rotates out of the limit groove. The turntable is fixedly connected with a sliding shaft. The sliding shaft can slide into the chute I. The sliding shaft and chute I are used to drive the reversing plate to rotate. The lower end of the bracket I is fixedly connected to the motor I, the output shaft of the motor I passes through the bracket I, and the output shaft of the motor I is fixedly connected to the turntable.

Further, the sleeve is fixedly connected to a cutter head box, the bracket I is rotatably connected to a rotating shaft I, the rotating shaft I passes through the bracket I and the cutter head box, the lower end of the bracket I is fixedly connected to the motor II, and the output shaft of the motor II is fixedly connected. Fixedly connected to the rotating shaft I.

Further, a bracket II is fixedly connected to the cutter head box, a rotating shaft II is rotatably connected to the cutter head box, the rotating shaft II is rotatably connected to the bracket II, the bevel gear I is fixedly connected to the rotating shaft I, and the umbrella is fixedly connected to the rotating shaft II. Gear II, bevel gear I mesh with bevel gear II.

Further, a rotating shaft III is rotatably connected to the cutter head box, a milling cutter I is fixedly connected to the rotating shaft III and the rotating shaft II, a gear is fixedly connected to the rotating shaft III and the rotating shaft II, and the two gears mesh.

Description of drawings

The present invention will be described in further detail below in conjunction with the accompanying drawings and specific implementation methods.

Figure 1 is a schematic structural diagram I of the overall building module processing system;

Figure 2 is a schematic diagram II of the overall structure of the building module processing system;

Figure 3 is a schematic structural diagram of a bidirectional milling cutter;

Figure 4 is a schematic structural diagram I of the tool changing mechanism;

Figure 5 is a structural schematic diagram II of the tool changing mechanism;

Figure 6 is a schematic structural diagram I of the gear transmission system;

Figure 7 is a schematic structural diagram of the gear transmission system II;

Figure 8 is a schematic structural diagram of the sliding processing table;

Figure 9 is a schematic structural diagram of the processing table and fixture;

Figure 10 is a schematic structural diagram of the clamp.

Detailed ways

The present invention will be further described in detail below in conjunction with the accompanying drawings.

The following is a detailed description with reference to Figures 1-5, an assembled building module and processing system. The building module processing system includes a bracket I101, a sleeve 102, a reversing plate 103, a limiting groove 104 and a limiting groove 104. The bracket A sleeve 102 is rotatably connected to I101, and the reversing plate 103 is fixedly connected to the sleeve 102 by welding. A plurality of limiting grooves 104 are evenly provided on the reversing plate 103 in the circumferential direction. A plurality of chute I105, limiting grooves 104 and chute I105 are distributed alternately.

Further, the bracket I101 plays a supporting role and provides a rotation space for the sleeve 102. A circular hole I is provided in the center of the reversing plate 103. The sleeve 102 is fixedly connected in the circular hole I, and the sleeve 102 passes through the circular hole. Ⅰ passes through the reversing plate 103.

Described in detail below with reference to Figures 1-5, the building module processing system also includes a turntable 201, a limit shaft 202, a sliding shaft 203 and a motor I204. The turntable 201 is rotatably connected to the bracket I101, and the limit shaft 202 is fixedly connected by welding. On the turntable 201, the limit shaft 202 can be rotated into the limit slot 104. The limit shaft 202 is used to limit the rotation of the reversing plate 103 when rotating into the limit slot 104. The limit shaft 202 is used to rotate out of the limit slot 104. When the restriction on the rotation of the reversing plate 103 is terminated, the sliding shaft 203 is fixedly connected to the turntable 201 through welding. The sliding shaft 203 can slide into the chute I105. The sliding shaft 203 and the chute I105 are used to drive the reversing plate 103 to rotate. The motor I204 is fixedly connected to the lower end of the bracket I101 through bolts. The output shaft of the motor I204 passes through the bracket I101. The turntable 201 and the motor I204 are fixedly connected through a coupling.

Further, the motor I 204 is used to drive the turntable 201 to rotate, and the limit shaft 202 has a semi-cylindrical structure. When the limit shaft 202 rotates into the limit groove 104, the cylindrical surface of the limit shaft 202 blocks the limit groove 104 to reverse direction. The plate 103 cannot rotate, so the reversing plate 103 is fixed. When the limit shaft 202 rotates out of the limit slot 104, the fixation of the limit slot 104 is released, the limit slot 104 can rotate, and the sliding shaft 203 follows the turntable 201 It can slide into the limit groove 104 when rotating. When the sliding shaft 203 slides into the limit groove 104, the limit shaft 202 rotates out of the limit groove 104 at the same time. The sliding shaft 203 makes the reversing plate 103 rotate 45 by pushing the chute I105. °, when the sliding shaft 203 slides out of the limit groove 104, the limit shaft 202 rotates into the limit groove 104 to fix the reversing plate 103, completing the fixed-angle rotation and fixation of the reversing plate 103, and realizing the reversing plate 103. Periodic rotation and fixation.

Described in detail below with reference to Figures 3-5, the building module processing system also includes a cutter head box 301, a rotating shaft I 302 and a motor II 303. The cutter head box 301 is fixedly connected to the sleeve 102 through welding, and the rotating shaft I 302 rotates through the shaft hole I. Connected to the bracket I101, the rotating shaft I302 passes through the cutter head box 301 and the bracket I101 through the shaft hole II and the shaft hole I respectively. The motor II303 is connected to the lower end of the bracket I101 through bolts. The rotating shaft I302 and the output shaft of the motor II303 pass through a flat key. Fixed connection.

Further, the bracket I101 is provided with an axis hole I, the lower end of the cutter head box 301 is provided with an axis hole II, and the rotating shaft I302 is rotatably connected in the axis hole I and the axis hole II.

Described in detail below with reference to Figures 6 and 7, the building module processing system also includes a bracket II 304, a rotating shaft II 305, a bevel gear I 306 and a bevel gear II 307. The bracket II 304 is fixedly connected to the cutter head box 301 by welding, and the rotating shaft II 305 passes through the rotating shaft IV. Rotationally connected to the cutter head box 301, bracket II 304 and rotation shaft II 305 are rotationally connected through rotation shaft III, bevel gear I 306 is fixedly connected to rotation shaft I 302 through a flat key, bevel gear II 307 is fixedly connected to the rotation shaft II 305 through a flat key, bevel gear II 307 and Bevel gear I306 meshes.

Further, the bracket II 304 is provided with an axis hole III, the cutter head box 301 is provided with an axis hole IV, and the rotating shaft II 305 is rotatably connected in the axis hole III and the axis hole IV.

Described in detail below with reference to Figures 6 and 7, the building module processing system also includes a rotating shaft III 308, a milling cutter I 309 and a gear 310. The rotating shaft III 308 is rotatably connected to the cutter head box 301 through the shaft hole V, and the two milling cutters I 309 pass through The flat key is fixedly connected to the rotating shaft II 305 and the rotating shaft III 308, and the two gears 310 are fixedly connected to the rotating shaft II 305 and the rotating shaft III 308 respectively through the flat key, and the two gears 310 mesh.

Further, the cutter head box 301 is provided with a rotating shaft V, and the rotating shaft III 308 is rotatably connected in the rotating shaft V. Through the meshing of two gears 310, the rotating shaft III 308 and the rotating shaft II 305 are driven to rotate synchronously, so that they are fixedly connected to the rotating shaft III 308 and the rotating shaft II 305 respectively. The two milling cutters I309 rotate at the same angular speed.

Described in detail below with reference to Figures 6 and 7, the building module processing system also includes a bracket III 311, a rotating shaft IV 312, a bevel gear III 313, a bevel gear IV 314 and a milling cutter II 315. The bracket III 311 is fixedly connected to the cutter head box 301 by welding, and the rotating shaft IV312 is rotatably connected to the cutter head box 301 through the rotary shaft VII, the bracket III311 and the rotary shaft IV312 are rotatably connected through the rotary shaft VI, the bevel gear III313 is fixedly connected to the rotary shaft I302 through a flat key, and the bevel gear IV314 is fixedly connected to the rotary shaft IV312 through a flat key. The bevel gear IV314 meshes with the bevel gear III313, and the milling cutter II315 is fixedly connected to the rotating shaft IV312 through a flat key.

Further, the bracket III 311 is provided with a shaft hole VI, the cutter head box 301 is provided with a shaft hole VII, the rotating shaft IV 312 is rotatably connected in the rotating shaft VI and the shaft hole VII, the motor I 204 drives the sliding shaft 203 to rotate, and the sliding shaft 203 passes through The bevel gear I 306 and the bevel gear II 307 drive the rotating shaft II 305 to rotate to realize the rotation of the bevel gear I 306. The sliding shaft 203 drives the rotating shaft IV 312 to rotate through the bevel gear III 313 and the bevel gear IV 314 to realize the rotation of the milling cutter II 315. When the reversing plate 103 rotates around, it drives the cutter. The head box 301 rotates 180° to realize the replacement of the milling cutter I 309 and the milling cutter II 315 to complete the replacement of the milling cutters. The two milling cutters I 309 can process one side of the wooden board into a bulge, and the milling cutter II 315 can process the other side of the wooden board into a bulge. groove.

Described in detail below with reference to Figure 1, the building module processing system also includes a work table 401. The work table 401 is fixedly connected to the lower end of the bracket I101 through welding.

Further, the work table 401 plays a supporting role and provides installation space for the bracket I101 and the bracket IV402.

Described in detail below with reference to Figure 8, the building module processing system also includes a bracket IV 402, a sliding rod I 403, a processing table 404, a screw I 405 and a motor II 406. The bracket IV 402 is fixedly connected to the work table 401 through welding, and the two sliding rods I 403 It is fixedly connected to the bracket IV402 by welding. The processing table 404 is slidingly connected to the two sliding rods I403 passing through the round hole II. The screw I405 is rotatably connected to the bracket IV402 through the axis hole VIII. The processing table 404 and the screw I405 are threaded through the threaded hole. Connection, the motor II406 is fixedly connected to the bracket IV402 through bolts, and the screw I405 and the output shaft of the motor II406 are fixedly connected through a flat key.

Further, the processing table 404 is provided with two round holes II, and the processing table 404 is slidingly connected in the round hole II, so that the processing table 404 can only slide along the axis direction of the slide rod I 403, and the bracket IV 402 is provided with an axis hole. Ⅷ. The screw I 405 is rotatably connected in the shaft hole VIII. The processing table 404 is provided with a threaded hole I. The screw I 405 is rotatably connected in the threaded hole I. When the motor II 406 rotates clockwise, the motor II 406 drives the processing through the screw I 405. The table 404 moves forward. When the motor II 406 rotates counterclockwise, the motor II 406 drives the processing table 404 backward through the screw I 405.

Described in detail below with reference to Figure 9, the building module processing system also includes a chute II 407, a slide bar II 408 and a clamp slider 409. The chute II 407 is provided on the processing table 404, and the two slide bars II 408 are fixedly connected to the slide block by welding. In the slot II 407, the clamp slider 409 is slidingly connected to the two slide rods II 408 through the two circular holes III.

Furthermore, the clamp slider 409 is provided with two circular holes III, and the clamp slider 409 is slidably connected in the circular holes III, so that the clamp slider 409 can only slide along the axis direction of the slide rod II 408.

Described in detail below with reference to Figure 10, the building module processing system also includes a bracket V501, a screw II 502, a clamp 503 and a handle 504. The bracket V501 is threaded with a screw II 502 through a threaded hole II, and the lower end of the screw II 502 is rotationally connected with a clamp. The claw 503 and the handle 504 are fixedly connected to the screw rod II 502 through welding, the middle bracket V501 of the fixture located at the right end is fixedly connected to the processing table 404 through welding, and the middle bracket V501 of the fixture located at the left end is fixedly connected to the fixture slider 409 through welding.

Further, the bracket V501 is provided with a threaded hole II, and the screw rod II502 is rotatably connected in the threaded hole II. The clamping jaw 503 is rotated clockwise. The screw rod II502 drives the clamping jaw 503 to move downward to complete the fixation of the clamp. Turn the clamp counterclockwise. The claw 503 and the screw II 502 drive the clamping claw 503 to move upward to complete the opening of the clamp, which can change the relative distance between the two clamps and install boards of different sizes.

Claims (10)

1. An assembled building module and processing system, its characterized in that: including support I (101) and rotate sleeve (102) of connection on support I (101), fixedly connected with switching-over dish (103) on sleeve (102), circumference evenly is provided with a plurality of spacing grooves (104) on switching-over dish (103), circumference evenly is provided with a plurality of spouts I (105) on switching-over dish (103).

2. The fabricated building module and processing system of claim 1, wherein: the rotary table (201) is rotationally connected to the support I (101), the limiting shaft (202) is fixedly connected to the rotary table (201), the limiting shaft (202) can rotate into the limiting groove (104), the limiting shaft (202) is used for limiting rotation of the reversing disc (103) when rotating out of the limiting groove (104), the limiting shaft (202) is used for stopping rotation of the reversing disc (103), the sliding shaft (203) is fixedly connected to the rotary table (201), the sliding shaft (203) can slide into the sliding groove I (105), the sliding shaft (203) and the sliding groove I (105) are used for driving the reversing disc (103) to rotate, the motor I (204) is fixedly connected to the lower end of the support I (101), an output shaft of the motor I (204) penetrates through the support I (101), and the output shaft of the motor I (204) is fixedly connected with the rotary table (201).

3. The fabricated building module and processing system of claim 2, wherein: fixedly connected with tool bit box (301) on sleeve (102), rotation is connected with pivot I (302) on support I (101), and pivot I (302) pass support I (101) and tool bit box (301), and the lower extreme fixedly connected with motor II (303) of support I (101), the output shaft and the pivot I (302) fixed connection of motor II (303).

4. A fabricated building module and processing system according to claim 3, wherein: the tool bit box (301) is fixedly connected with a support II (304), the tool bit box (301) is rotationally connected with a rotating shaft II (305), the rotating shaft II (305) is rotationally connected with the support II (304), the rotating shaft I (302) is fixedly connected with a bevel gear I (306), the rotating shaft II (305) is fixedly connected with a bevel gear II (307), and the bevel gear I (306) is meshed with the bevel gear II (307).

5. The fabricated building module and processing system of claim 4, wherein: the tool bit box (301) is rotationally connected with a rotating shaft III (308), the rotating shaft III (308) and a rotating shaft II (305) are fixedly connected with a milling cutter I (309), the rotating shaft III (308) and the rotating shaft II (305) are fixedly connected with gears (310), and the two gears (310) are meshed.

6. The fabricated building module and processing system of claim 5, wherein: the tool bit box (301) is internally fixedly connected with a support III (311), the tool bit box (301) is rotationally connected with a rotating shaft IV (312), the rotating shaft IV (312) is rotationally connected with the support III (311), the rotating shaft I (302) is fixedly connected with a bevel gear III (313), the rotating shaft IV (312) is fixedly connected with a bevel gear IV (314), the bevel gear III (313) is meshed with the bevel gear IV (314), and the rotating shaft IV (312) is fixedly connected with a milling cutter II (315).

7. The fabricated building module and processing system of claim 1, wherein: the lower end of the support I (101) is fixedly connected with a work table (401).

8. The fabricated building module and processing system of claim 7, wherein: fixedly connected with support IV (402) on table (401), fixedly connected with slide bar I (403) on support IV (402), sliding connection has processing platform (404) on slide bar I (403), slide bar I (403) are used for making processing platform (404) only can slide along slide bar I (403) axis direction, rotate on support IV (402) and are connected with screw rod I (405), screw rod I (405) and processing platform (404) threaded connection, fixedly connected with motor II (406) on support IV (402), the output shaft and the screw rod I (405) fixed connection of motor II (406).

9. The fabricated building module and processing system of claim 8, wherein: the machining table (404) is provided with a sliding groove II (407), a sliding rod II (408) is fixedly connected in the sliding groove II (407), a clamp sliding block (409) is connected to the sliding rod II (408) in a sliding mode, and the sliding rod II (408) is used for enabling the clamp sliding block (409) to only slide along the axis direction of the sliding rod II (408).

10. The fabricated building module and processing system of claim 9, wherein: including two anchor clamps, anchor clamps include support V (501), threaded connection has screw rod II (502) on support V (501), and the lower extreme rotation of screw rod II (502) is connected with clamping jaw (503), and the top fixedly connected with handle (504) of screw rod II (502), support V (501) and processing platform (404) fixed connection in the anchor clamps of being located the right-hand member, support V (501) and anchor clamps slider (409) fixed connection in the anchor clamps of being located the right-hand member.