阅读说明：本技术 一种双层玻璃的钻孔系统 (Double glazing's drilling system ) 是由 不公告发明人 于 2021-08-13 设计创作，主要内容包括：本发明属于钻孔机领域,具体涉及一种双层玻璃的钻孔系统,包括圆台,所述圆台上设置有四根成圆周分布的台柱,所述圆台上还设置有四个成圆周分布的滑动轨道,每个所述滑动轨道内设置有工作台,每个所述工作台上设置有用于钻孔的钻孔构件,能够防止玻璃碎屑与冷却水进入双层玻璃的空腔内。(The invention belongs to the field of drilling machines, and particularly relates to a double-layer glass drilling system which comprises a circular table, wherein four circular-distributed table columns are arranged on the circular table, four circular-distributed sliding rails are further arranged on the circular table, a working table is arranged in each sliding rail, a drilling component for drilling is arranged on each working table, and glass scraps and cooling water can be prevented from entering a cavity of double-layer glass.)

1. The double-layer glass drilling system comprises a circular table (1) and is characterized in that four circular-distributed table columns (5) are arranged on the circular table (1), four sliding rails (2) are further arranged on the circular table (1) and distributed in a circumferential mode, a workbench (3) is arranged in each sliding rail (2), and each drilling component (4) used for drilling is arranged on each workbench (3).

2. The double-glazing drilling system according to claim 1, characterized in that a water storage tank (101) is arranged inside the circular truncated cone (1), a filter plate (102) is arranged inside the water storage tank (101), a first motor (103) is arranged on the water storage tank (101), a rotating shaft (104) is arranged on the first motor (103), four connecting rods (105) are connected to the rotating shaft (104) in a circumferential array, one end of each connecting rod (105) far away from the rotating shaft (104) is connected to a circular ring (106), and the circular ring (106) is fixedly connected to four sliding guide rails (2) distributed in a circumferential manner.

3. The double-glazing drilling system according to claim 2, characterized in that each sliding guide rail (2) comprises a first sliding groove (201), a threaded rod (202) is arranged in the first sliding groove (201), a first bearing (203) is arranged at one end, away from the ring (106), of the threaded rod (202), a first belt pulley (204) is arranged at one end, away from the ring (106), of the threaded rod (202), a second motor (207) is arranged at one end, away from the ring (106), of the first movable groove (201), a first rotating rod (208) is arranged on the second motor (207), a second belt pulley (205) is arranged on the first rotating rod (208), and a first belt (206) is arranged on the first belt pulley (204) and the second belt pulley (205).

4. A double glazing drilling system according to claim 3, wherein each of the work stations (3) comprises a first slide block (301) disposed in the sliding rail (2), the first slide block (301) is connected with a threaded rod (202), a first support table (302) is disposed on the first slide block (301), a third motor (303) is disposed at the bottom of the first support table (302), a second support table (304) is disposed on the first support table (302), two clamping plates (305) are symmetrically disposed on the first support table (302), a spring (306) is disposed at one end of each of the clamping plates (305) located outside the first support table (302), and a flexible ball (307) is disposed at one end of each of the clamping plates (305) located inside the first support table (302).

5. The double-glazing drilling system according to claim 4, wherein each drilling member (4) comprises a piston cylinder (401) arranged on the first support platform (302), a drill bit (402) is arranged in the piston cylinder (401), through holes (412) are arranged in the drill bit (402), four second sliding grooves (403) are distributed on the outer wall of the piston cylinder (401) in a circumferential array, a first support plate (404) is arranged at one end of the piston cylinder (401) outside the support platform (302), a second support plate (405) is arranged on the first support plate (404), a bearing (406) is arranged between the second support plate (405) and the drill bit (402), a third belt pulley (407) is arranged at one end of the drill bit (402) close to the second support plate (405), and a fourth motor (411) is arranged on the first support plate (404), be provided with second dwang (410) on fourth motor (411), be provided with fourth belt pulley (409) on second dwang (410), be provided with second belt (408) between third belt pulley (407) and fourth belt pulley (409).

6. The double-glazing drilling system according to claim 5, wherein each drilling member (4) comprises an inner groove arranged at a position, close to the second support platform (304), of each second sliding groove (403), a third sliding block (413) arranged at a position, close to the second support platform (304), of each second sliding groove (403), a fourth sliding block (414) is arranged in the third sliding block (413), the fourth sliding block (414) is arranged in the inner groove and is in contact with the wall surface of the piston cylinder, a suction rod (415) is rotatably arranged at one end, far away from the piston cylinder (401), of the third sliding block (413), a suction cup (416) is arranged at a position, close to the second support platform (304), of each suction rod (415), a suction ring (417) is arranged in the middle of the four suction rods (415), a cavity is arranged inside the suction ring (417) and the suction rod (415), and an air pipe (418) is arranged outside the suction ring (417), a vacuum pump (419) is arranged on the first supporting platform (302), and the vacuum pump (419) is connected with an air pipe (418).

7. The double-glazing drilling system according to claim 6, characterized in that each drilling member (4) comprises a fifth motor (420) arranged on the support platform (302), a rotating ring (421) is arranged on the fifth motor (420), a second sliding block (423) is fixedly arranged on the rotating ring (421), a hollow rod (422) is fixedly arranged in the middle of the piston cylinder (401), the hollow rod (422) is connected with the second sliding block (423) in a sliding manner, a first water inlet pipe (424) is connected with a through hole (412) in the drill bit (402), a first water pump (425) is arranged on the first support platform (302), the first water pump (425) is connected with the first water inlet pipe (424), a first water outlet pipe (426) is connected with the first water pump (425), and one end of the first water outlet pipe (426) far away from the first water pump (425) is connected with the water storage tank (101), the water storage tank (101) is further connected with a second water inlet pipe (427), the first supporting platform (302) is further provided with a second water pump (428), the second water pump (428) is connected with the second water inlet pipe (427), and the second water pump (428) is further connected with a second water outlet pipe (429).

Technical Field

The invention belongs to the field of drilling machines, and particularly relates to a drilling system for double-layer glass.

Background

The double-layer glass separates the two pieces of glass by effective sealing material and spacing material, and a drying agent for absorbing moisture is arranged between the two pieces of glass, thereby ensuring that the interior of the double-layer glass is a dry air layer for a long time and no moisture or dust exists; double glazing's drilling mainly descends perpendicularly through high-speed pivoted drilling cutter, then can drill a hole to glass on the operation panel, in double glazing drilling, need spray the cooling water and cool down the drilling position and take place to break when preventing glass drilling, nevertheless cause cooling water and glass piece to get into double glazing's cavity at the in-process of drilling easily, consequently design a system of processing that can prevent glass piece and cooling water entering double glazing's cavity and seem very important.

Disclosure of Invention

The invention aims to solve the problems in the prior art and provides a double-layer glass drilling system.

In order to achieve the purpose, the invention adopts the following technical scheme: the double-layer glass drilling system comprises a circular table, wherein four circular-distributed table columns are arranged on the circular table, four circular-distributed sliding rails are further arranged on the circular table, each sliding rail is internally provided with a workbench, and each workbench is provided with a drilling component.

Preferably, a water storage tank is arranged in the circular truncated cone, a filter plate is arranged in the water storage tank, a first motor is arranged on the water storage tank, a rotating shaft is arranged on the first motor, four connecting rods are connected to the rotating shaft in a circumferential array mode, one end, far away from the rotating shaft, of each connecting rod is connected with a ring, and the ring is fixedly connected with four sliding guide rails distributed in a circumferential mode.

Preferably, every sliding guide includes first sliding tray, be provided with the threaded rod in the first sliding tray, the threaded rod is kept away from ring one end and is provided with first bearing, the threaded rod is kept away from ring one end and is provided with first belt pulley, first activity groove is kept away from ring one end and is provided with the second motor, be provided with first pivot pole on the second motor, be provided with the second belt pulley on the first pivot pole, be provided with first belt on first belt pulley and the second belt pulley.

Preferably, every the workstation is including setting up the first slider in the slip track, first slider is connected with the threaded rod, be provided with first supporting station on the first slider, first supporting station bottom is provided with the third motor, be provided with the second brace table on the first supporting station, the symmetry is provided with two splint, every on the first supporting station splint are in the outside one end of first supporting station and are provided with the spring, every splint are in one of first supporting station inside and serve and be provided with flexible ball.

Preferably, every drilling component is including setting up the piston cylinder on first supporting bench, be provided with the drill bit in the piston cylinder, be provided with the through-hole in the drill bit, the piston cylinder outer wall becomes the circumference array distribution and has four second sliding tray, the piston cylinder is provided with first backup pad in the outside one end of brace table, be provided with the second backup pad on the first backup pad, be provided with the bearing between second backup pad and the drill bit, the drill bit is close to second backup pad one end and is provided with the third belt pulley, be provided with the fourth motor on the first backup pad, be provided with the second dwang on the fourth motor, be provided with the fourth belt pulley on the second dwang, be provided with the second belt between third belt pulley and the fourth belt pulley.

Preferably, each drilling component includes that every second sliding tray is close to second brace table department and is provided with the inside groove, every the second sliding tray is close to second brace table department and is provided with the third slider, be provided with the fourth slider in the third slider, the fourth slider is in the inside groove and contacts with the piston cylinder wall, the third slider is kept away from piston cylinder one end rotation and is provided with the suction rod, the suction rod is close to second brace table department and is provided with the sucking disc, four be provided with in the middle of the suction rod and inhale the ring, inhale the ring with the inside cavity that is provided with of suction rod, inhale the ring and be provided with the trachea outward, be provided with the vacuum pump on the first brace table, the vacuum pump is connected with the trachea.

Preferably, every drilling component is including setting up the fifth motor on a supporting bench, be provided with the rotating ring on the fifth motor, the fixed second slider that is provided with on the rotating ring, the fixed hollow pole that is provided with in the middle of the piston cylinder, hollow pole and second slider sliding connection, through-hole in the drill bit is connected with first oral siphon, be provided with first water pump on the first supporting bench, first water pump links to each other with first oral siphon, first water pump department is connected with first outlet pipe, first water pump one end is kept away from to first outlet pipe links to each other with the tank, the tank still is connected with the second oral siphon, still be provided with the second water pump on the first supporting bench, the second water pump links to each other with the second oral siphon, the second water pump still is connected with the second outlet pipe.

Has the advantages that:

the invention provides a wheelchair capable of going up and down stairs by improvement, compared with the prior art, the wheelchair has the following improvements and advantages;

1. through the cavity that sets up in the drill bit and being connected of water pipe, make can go into the absorption to the water on the glass and the piece of drilling out when glass drilling, prevent in piece and the cavity of water entering double glazing.

2. Through setting up being connected between sucking disc and the piston rod to be equipped with sliding tray and slider in the piston cylinder, make equipment can carry out the secondary at the in-process of glass processing and stabilize, and cooperate with the glass plane, ensure the position accuracy that needs drilling.

3. The transmission and sliding rails of the circular truncated cone are arranged, so that the position and the angle of the workbench are adjusted, the workbench has high degree of freedom, and the position which cannot be machined is avoided.

4. Through setting up tank and water pump, make the water in the processing carry out the circulation and use, reduced the waste of water resource.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a top view of the present invention;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2;

FIG. 4 is an enlarged view of a portion of FIG. 3 at B;

FIG. 5 is an enlarged view of a portion of FIG. 3 at C;

FIG. 6 is an enlarged view of a portion of FIG. 5 at D;

FIG. 7 is an enlarged view of a portion of FIG. 5 at E;

fig. 8 is a plan view at the third slider.

In the figure: a circular table 1, a sliding rail 2, a worktable 3, a drilling member 4, a column 5, a water reservoir 101, a filter plate 102, a first motor 103, a rotating shaft 104, a connecting rod 105, a circular ring 106, a first sliding groove 201, a threaded rod 202, a first bearing 203, a first pulley 204, a second pulley 205, a first belt 206, a second motor 207, a first rotating rod 208, a first slider 301, a first support table 302, a third motor 303, a second support table 304, a clamping plate 305, a spring 306, a flexible ball 307, a piston cylinder 401, a drill 402, a second sliding groove 403, a first support plate 404, a second support plate 405, a bearing 406, a third pulley 407, a second belt 408, a fourth pulley 409, a second rotating rod 410, a fourth motor 411, a through hole 412, a third slider 413, a fourth slider, a suction rod 415, a suction cup 416, a suction ring 417, an air pipe 418, a vacuum pump 419, a fifth motor 420, a suction ring 414, a vacuum pump 417, a vacuum pump 414, a vacuum pump, a vacuum, The water pump comprises a rotating ring 421, a hollow rod 422, a second sliding block 423, a first water inlet pipe 424, a first water pump 425, a first water outlet pipe 426, a second water inlet pipe 427, a second water pump 428 and a second water outlet pipe 429.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

In the description of the present invention, it should be noted that the terms "inside", "below", and the like refer to orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention conventionally place when used, and are used only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

With reference to fig. 1, the double-layer glass drilling system comprises a circular table 1, wherein four circular-distributed table columns 5 are arranged on the circular table 1, four circular-distributed sliding rails 2 are further arranged on the circular table 1, a working table 3 is arranged in each sliding rail 2, and a drilling component 4 for drilling is arranged on each working table 3.

Referring to fig. 3, a water storage tank 101 is arranged inside the circular truncated cone 1, a filter plate 102 is arranged in the water storage tank 101, a first motor 103 is arranged on the water storage tank 101, a rotating shaft 104 is arranged on the first motor 103, four connecting rods 105 are connected to the rotating shaft 104 in a circumferential array manner, one end of each connecting rod 105, which is far away from the rotating shaft 104, is connected with a ring 106, and the ring 106 is fixedly connected with four sliding guide rails 2 which are distributed in a circumferential manner.

Referring to fig. 4, each sliding guide rail 2 includes a first sliding groove 201, a threaded rod 202 is disposed in the first sliding groove 201, a first bearing 203 is disposed at one end of the threaded rod 202 away from the ring 106, a first belt pulley 204 is disposed at one end of the threaded rod 202 away from the ring 106, a second motor 207 is disposed at one end of the first movable groove 201 away from the ring 106, a first rotating rod 208 is disposed on the second motor 207, a second belt pulley 205 is disposed on the first rotating rod 208, and a first belt 206 is disposed on the first belt pulley 204 and the second belt pulley 205.

With reference to fig. 5, each workbench 3 includes a first slider 301 disposed in the sliding track 2, the first slider 301 is connected to the threaded rod 202, a first supporting platform 302 is disposed on the first slider 301, a third motor 303 is disposed at the bottom of the first supporting platform 302, a second supporting platform 304 is disposed on the first supporting platform 302, two clamping plates 305 are symmetrically disposed on the first supporting platform 302, a spring 306 is disposed at one end of each clamping plate 305 located outside the first supporting platform 302, and a flexible ball 307 is disposed at one end of each clamping plate 305 located inside the first supporting platform 302.

Each drilling component 4 comprises a piston cylinder 401 arranged on the first supporting platform 302, a drill bit 402 is arranged in the piston cylinder 401, a through hole 412 is arranged in the drill bit 402, four second sliding grooves 403 are distributed on the outer wall of the piston cylinder 401 in a circumferential array mode, a first supporting plate 404 is arranged at one end, located outside the supporting platform 302, of the piston cylinder 401, a second supporting plate 405 is arranged on the first supporting plate 404, a bearing 406 is arranged between the second supporting plate 405 and the drill bit 402, a third belt pulley 407 is arranged at one end, close to the second supporting plate 405, of the drill bit 402, a fourth motor 411 is arranged on the first supporting plate 404, a second rotating rod 410 is arranged on the fourth motor 411, a fourth belt pulley 409 is arranged on the second rotating rod 410, and a second belt 408 is arranged between the third belt pulley 407 and the fourth belt pulley 409.

With reference to fig. 5-6, each drilling member 4 includes an inner groove disposed at a position of each second sliding groove 403 close to the second supporting platform 304, a third slider 413 disposed at a position of each second sliding groove 403 close to the second supporting platform 304, a fourth slider 414 disposed in the third slider 413 and contacting with a wall surface of the piston cylinder, a suction rod 415 rotatably disposed at one end of the third slider 413 away from the piston cylinder 401, a suction cup 416 disposed at a position of the suction rod 415 close to the second supporting platform 304, a suction ring 417 disposed between the four suction rods 415, a cavity disposed inside the suction ring 417 and the suction rod 415, an air pipe 418 disposed outside the suction ring 417, a vacuum pump 419 disposed on the first supporting platform 302 and connected to the air pipe 418.

With reference to fig. 5 to 7, each drilling member 4 includes a fifth motor 420 disposed on the support platform 302, a rotating ring 421 is disposed on the fifth motor 420, a second slider 423 is fixedly disposed on the rotating ring 421, a hollow rod 422 is fixedly disposed in the middle of the piston cylinder 401, the hollow rod 422 is slidably connected to the second slider 423, a first water inlet pipe 424 is connected to the through hole 412 in the drill bit 402, a first water pump 425 is disposed on the first support platform 302, the first water pump 425 is connected to the first water inlet pipe 424, a first water outlet pipe 426 is connected to the first water pump 425, one end of the first water outlet pipe 426, which is far away from the first water pump 425, is connected to the water storage tank 101, a second water inlet pipe 427 is further connected to the water storage tank 101, a second water pump 428 is further disposed on the first support platform 302, the second water pump 428 is connected to the second water inlet pipe 427, and a second water outlet pipe 429 is further connected to the second water pump 428.

The working principle is that initially, all motors are in a static state, and double-layer glass is placed on the table column 5.

During operation, the first motor 103 starts to rotate to drive the rotating shaft 104 to rotate, the rotating shaft 104 drives the ring 106 to rotate through the connecting rod 105, and the sliding track 2 connected with the ring 106 is driven to rotate on the circular truncated cone 1. Further, a second motor 207 on the sliding track 2 operates to drive the first rotating rod 208 to rotate, and drive the second belt pulley 205 to rotate, the second belt pulley 205 drives the first belt pulley 204 to rotate through the first belt 206, the first belt pulley 204 drives the threaded rod 202 to rotate, and the rotation of the threaded rod 202 drives the first slider 301 to move back and forth along the first sliding groove 201. Further, a third motor 303 located below the first sliding block 301 drives the first supporting table 302 to rotate, so that the position of the glass to be drilled is located.

Further, the double glazing is stabilized on the first support table 302 by the clamping plate 305, and the position of the double glazing needing to be drilled is positioned and stabilized by the second support table 304. Further, the fifth motor 420 starts to rotate to drive the rotating ring 421 to rotate, the second sliding block 423 located in the hollow rod 422 is driven by the rotating ring 421 to rotate, the hollow rod 422 is driven to move downwards, and the piston cylinder 401 fixedly connected with the hollow rod 422 is driven to move. Further, when the suction cup 416 contacts with the plane of the double-layer glass, the vacuum pump 419 starts to operate to suck air, so that the suction cup 416 is sucked on the glass, the suction rod 415 presses the third slide block 413 and enables the fourth slide block 414 to be tightly attached to the inner groove of the piston rod 402, the piston cylinder is secondarily stabilized, and the position accuracy of drilling is ensured.

Further, the second water pump 428 starts to work, water in the water storage tank 101 enters the second water pump 428 through the second water inlet pipe 427 and is discharged through the second water outlet pipe 429 to be sprayed on the surface of the glass, the fourth motor 411 starts to rotate to drive the fourth belt pulley 409 to rotate, the fourth belt pulley 409 drives the third belt pulley 407 through the second belt 408, the third belt pulley 407 drives the drill 402 to rotate, further, the piston cylinder 401 descends, the drill 402 drills the double-layer glass, the further first water pump 425 starts to work to suck cooling water and glass debris into the first water inlet pipe 424 through the cavity in the drill 402 and discharge the cooling water and the glass debris into the water storage tank 101 through the first water outlet pipe 426, and the glass debris in the water storage tank 101 is blocked by the filter plate 102 and is prevented from entering the second water inlet pipe 427.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.