CN215559855U - Glass mosaic brick cutting device - Google Patents

Abstract

The utility model discloses a glass mosaic brick cutting device which comprises a rack, and a feeding platform, a first discharging conveyer belt, a second discharging conveyer belt and a third discharging conveyer belt which are arranged on the rack, wherein the feeding platform is arranged on the rack; this decide device realizes the automatic feeding of glass mosaic brick through setting up first feeding frame, feeding guide rail, feeding cylinder, then realizes deciding the glass mosaic brick automatically through setting up cutting off cutter, hydraulic cylinder, and the rethread sets up first ejection of compact conveyer belt, second ejection of compact conveyer belt, third ejection of compact conveyer belt, realizes that the back automatic discharge is decided to the glass mosaic brick, and whole degree of automation is high, and the practicality is strong, has improved machining efficiency.

Description

Glass mosaic brick cutting device

Technical Field

The utility model relates to the technical field of machinery, in particular to a glass mosaic tile cutting device.

Background

After the glass mosaic tile is in primary production, need decide according to the actual production requirement, just can carry out subsequent polishing rounding etc. and device degree of automation is decided to current glass mosaic tile is low, makes whole machining efficiency low.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects of the prior art, the utility model aims to provide a glass mosaic tile cutting device with strong practicability and high efficiency.

In order to achieve the purpose, the scheme provided by the utility model is as follows: a glass mosaic brick cutting device comprises a rack, and a feeding platform, a first discharging conveying belt, a second discharging conveying belt and a third discharging conveying belt which are arranged on the rack, wherein a plurality of separation strips are arranged on the feeding platform and are arranged at equal intervals to form a feeding channel between every two separation strips, a first feeding frame is arranged above the feeding platform, a clamping cylinder is arranged on the first feeding frame, a pressing block is downwards connected to the clamping cylinder and used for pressing down glass mosaic bricks in the feeding channel, a cutting knife is arranged right above the discharging end of the feeding platform, and a lifting hydraulic cylinder is upwards connected to the cutting knife;

the feeding guide rail and the servo motor are arranged on the rack, the first feeding frame is connected to the feeding guide rail in a sliding mode, and the servo motor is used for driving the first feeding frame to move back and forth;

the feeding platform, the first discharging conveying belt, the second discharging conveying belt and the third discharging conveying belt are sequentially arranged along the conveying direction of the glass mosaic bricks.

The utility model has the beneficial effects that: realize automatic feeding, decide, the ejection of compact, should decide the device through setting up first feeding frame, feeding guide rail, servo motor realizes the automatic feeding of glass mosaic brick, then through setting up the cutting off cutter, hydraulic cylinder realizes deciding the glass mosaic brick automatically, the rethread sets up first ejection of compact conveyer belt, second ejection of compact conveyer belt, third ejection of compact conveyer belt, realize that the back automatic discharge is decided to the glass mosaic brick, whole degree of automation is high, therefore, the clothes hanger is strong in practicability, and machining efficiency is improved.

Furthermore, a second feeding frame is arranged above the feeding end of the feeding platform, a propelling cylinder is arranged on the rack and connected with the second feeding frame to propel the glass mosaic tiles on the feeding platform to a position right below the first feeding frame. After the structure is adopted, the feeding of the glass mosaic tiles is realized.

Furthermore, gaps are reserved between the feeding platform and the first discharging conveying belt and between the first discharging conveying belt and the second discharging conveying belt, and the third discharging conveying belt is obliquely and upwards arranged below the second conveying belt. After the structure is adopted, fragments of the glass mosaic tiles can be discharged from gaps between the feeding platform and the first discharging conveyer belt and gaps between the first discharging conveyer belt and the second discharging conveyer belt after the glass mosaic tiles are cut, and the subsequent discharging collection of the glass mosaic tiles cannot be influenced.

Further, second ejection of compact conveyer belt discharge end is provided with the dwang, the dwang is connected with the baffle downwards, dwang coaxial coupling has the rotation motor, the rotation motor drives the dwang and rotates the discharge end that realizes that the baffle opens or closes second ejection of compact conveyer belt.

Further, still include first driving motor, second driving motor, third driving motor, first driving motor drives first ejection of compact conveyer belt and carries, second driving motor drives second ejection of compact conveyer belt and carries, third driving motor drives third ejection of compact conveyer belt and carries. After the structure is adopted, the conveying of the first discharging conveying belt, the second discharging conveying belt and the third discharging conveying belt is driven.

Further, the rotating motor is connected with a rotating reduction box, and the rotating reduction box is connected with the rotating rod. By adopting the structure, the rotating rod is driven to rotate forward and backward, so that the discharge end of the second discharge conveying belt is opened or closed.

Furthermore, the servo motor is connected with a servo reduction gearbox, the servo reduction gearbox is connected with a feeding screw rod, and the feeding screw rod is in threaded connection with the first feeding frame. By adopting the structure, the first feeding frame is driven to move back and forth.

Drawings

FIG. 1 is a side view of the overall structure of the present invention.

Fig. 2 is a partially enlarged view of a portion a in fig. 1.

Fig. 3 is a front view of the cutting blade of the present invention.

Fig. 4 is a schematic view showing the rotating rod connected with the rotating motor (baffle closed) according to the present invention.

Fig. 5 is a schematic diagram of the rotating rod connected with the rotating motor (baffle is opened) of the utility model.

Wherein, 1 is the frame, 11 is the feeding guide rail, 12 is servo motor, 121 is servo reducing gear box, 122 is the feeding screw rod, 13 is for promoting the cylinder, 2 is the material loading platform, 21 is the parting bead, 211 is feedstock channel, 22 is first feeding frame, 221 is die clamping cylinder, 222 is the compact heap, 23 is second feeding frame, 24 is the cutting off cutter, 25 is hydraulic cylinder, 3 is first ejection of compact conveyer belt, 31 is first driving motor, 4 is second ejection of compact conveyer belt, 41 is second driving motor, 42 is the dwang, 43 is the baffle, 44 is the rotating electrical machines, 5 is third ejection of compact conveyer belt, 51 is third driving motor.

Detailed Description

The utility model will be further illustrated with reference to specific examples:

referring to fig. 1 to 5, a glass mosaic tile cutting device includes a frame 1, a first driving motor 31, a second driving motor 41, a third driving motor 51, a feeding platform 2, a first discharging conveyer belt 3, a second discharging conveyer belt 4 and a third discharging conveyer belt 5, wherein the feeding platform 2 is arranged on the frame 1, a plurality of separating strips 21 are arranged on the feeding platform 2, the plurality of separating strips 21 are arranged at equal intervals to form a feeding channel 211 between every two separating strips 21, a first feeding frame 22 is arranged above the feeding platform 2, a clamping cylinder 221 is arranged on the first feeding frame 22, the clamping cylinder 221 is connected with a pressing block 222 downwards to press down glass mosaic tiles in the feeding channel 211, a cutting knife 24 is arranged right above a discharging end of the feeding platform 2, and the cutting knife 24 is connected with a lifting hydraulic cylinder 25 upwards; gaps are reserved between the feeding platform 2 and the first discharging conveying belt 3 and between the first discharging conveying belt 3 and the second discharging conveying belt 4, and the third discharging conveying belt 5 is obliquely and upwards arranged below the second conveying belt.

Be provided with feeding guide rail 11 and servo motor 12 on the frame 1, first feeding frame 22 sliding connection is on feeding guide rail 11, and servo motor 12 is connected with servo reducing gear box 121, and servo reducing gear box 121 is connected with feeding screw rod 122, and feeding screw rod 122 threaded connection first feeding frame 22 to the realization drives first feeding frame 22 back-and-forth movement.

Feeding platform 2, first ejection of compact conveyer belt 3, second ejection of compact conveyer belt 4, third ejection of compact conveyer belt 5 sets gradually along glass mosaic brick direction of delivery, and 4 discharge ends of second ejection of compact conveyer belt are provided with dwang 42, and dwang 42 is connected with baffle 43 downwards, and dwang 42 coaxial coupling has rotation motor 44, and rotation motor 44 is connected with the rotation reducing gear box, and rotation reducing gear box connects dwang 42, realizes that baffle 43 opens or closes the discharge end of second ejection of compact conveyer belt 4.

A second feeding frame 23 is arranged above the feeding end of the feeding platform 2, a propelling cylinder 13 is arranged on the frame 1, and the propelling cylinder 13 is connected with the second feeding frame 23 and used for propelling the glass mosaic tiles on the feeding platform 2 to be under the first feeding frame 22.

The first driving motor 31 drives the first discharging conveyer belt 3 to convey, the second driving motor 41 drives the second discharging conveyer belt 4 to convey, and the third driving motor 51 drives the third discharging conveyer belt 5 to convey.

In this embodiment, the specific working process is as follows: firstly, a plurality of glass mosaic tiles are respectively placed in a plurality of feeding channels 211, then a propulsion cylinder 13 is started, a piston rod of the propulsion cylinder 13 extends out to drive a second feeding frame 23 to propel the plurality of glass mosaic tiles to be under a first feeding frame 22, then a lifting clamping cylinder 221 and a servo motor 12 are sequentially started, the clamping cylinder 221 drives a pressing block 222 to press downwards to press the plurality of glass mosaic tiles, the servo motor 12 drives a servo reduction gearbox 121 to work, the servo reduction gearbox 121 drives a feeding screw 122 to rotate to drive the first feeding frame 22 to advance until the plurality of glass mosaic tiles are propelled to be under a cutting knife 24;

at this moment, the lifting hydraulic cylinder 25 can be started, the lifting hydraulic cylinder 25 drives the cutting knife 24 to press down to cut off the glass mosaic tiles, the servo motor 12 is controlled again to push the cut off glass mosaic tiles onto the first discharging conveying belt 3, then the glass mosaic tiles are moved to the discharging end of the second discharging conveying belt 4, the bearing plate is arranged on the third discharging conveying belt 51, finally, the rotating motor 44 is synchronously started, the second driving motor 41 and the third driving motor 51 are started, the rotating motor 44 drives the baffle 43 to be opened, and the glass mosaic tiles fall onto the bearing plate of the third discharging conveying belt 5.

The above-described embodiments are merely preferred embodiments of the present invention, which is not intended to limit the present invention in any way. Those skilled in the art can make many changes and modifications to the disclosed embodiments, or modify equivalent embodiments to practice the disclosed embodiments, without departing from the scope of the disclosed embodiments. Therefore, equivalent variations made according to the idea of the present invention should be covered within the protection scope of the present invention without departing from the contents of the technical solution of the present invention.

Claims (7)

1. The utility model provides a device is decided to glass mosaic brick, includes frame (1) and sets up feeding platform (2), first ejection of compact conveyer belt (3), second ejection of compact conveyer belt (4), third ejection of compact conveyer belt (5) on frame (1), its characterized in that: the glass mosaic tile feeding device is characterized in that a plurality of separating strips (21) are arranged on the feeding platform (2), the separating strips (21) are arranged at equal intervals to enable a feeding channel (211) to be formed between every two separating strips (21), a first feeding frame (22) is arranged above the feeding platform (2), a clamping cylinder (221) is arranged on the first feeding frame (22), a pressing block (222) is connected to the clamping cylinder (221) downwards and used for pressing down the glass mosaic tile in the feeding channel (211), a cutting knife (24) is arranged right above the discharging end of the feeding platform (2), and the cutting knife (24) is connected with a lifting hydraulic cylinder (25) upwards;

the feeding mechanism is characterized in that a feeding guide rail (11) and a servo motor (12) are arranged on the rack (1), the first feeding frame (22) is connected to the feeding guide rail (11) in a sliding mode, and the servo motor (12) is used for driving the first feeding frame (22) to move back and forth;

the feeding platform (2), the first discharging conveying belt (3), the second discharging conveying belt (4) and the third discharging conveying belt (5) are sequentially arranged along the conveying direction of the glass mosaic tiles.

2. A glass mosaic tile cutting device according to claim 1, wherein: a second feeding frame (23) is arranged above the feeding end of the feeding platform (2), a propelling cylinder (13) is arranged on the rack (1), and the propelling cylinder (13) is connected with the second feeding frame (23) and used for propelling the glass mosaic tiles on the feeding platform (2) to be under the first feeding frame (22).

3. A glass mosaic tile cutting device according to claim 2, wherein: gaps are reserved between the feeding platform (2) and the first discharging conveying belt (3) and between the first discharging conveying belt (3) and the second discharging conveying belt (4), and the third discharging conveying belt (5) is obliquely and upwards arranged below the second conveying belt.

4. A glass mosaic tile cutting device according to claim 3, wherein: second ejection of compact conveyer belt (4) discharge end is provided with dwang (42), dwang (42) downwardly connected with baffle (43), dwang (42) coaxial coupling has rotation motor (44), rotation motor (44) drive dwang (42) rotate the discharge end that realizes that baffle (43) open or close second ejection of compact conveyer belt (4).

5. A glass mosaic tile cutting device according to claim 4, wherein: still include first driving motor (31), second driving motor (41), third driving motor (51), first driving motor (31) drive first ejection of compact conveyer belt (3) and carry, second driving motor (41) drive second ejection of compact conveyer belt (4) and carry, third driving motor (51) drive third ejection of compact conveyer belt (5) and carry.

6. A glass mosaic tile cutting device according to claim 5, wherein: the rotating motor (44) is connected with a rotating reduction box, and the rotating reduction box is connected with the rotating rod (42).

7. A glass mosaic tile cutting device according to claim 6, wherein: the servo motor (12) is connected with a servo reduction gearbox (121), the servo reduction gearbox (121) is connected with a feeding screw (122), and the feeding screw (122) is in threaded connection with the first feeding frame (22).

Images