CN221088933U - Maintenance vehicle for glass coated cathode - Google Patents

Abstract

The utility model relates to a maintenance vehicle for a glass coated cathode, and belongs to the technical field of glass coated cathode maintenance equipment. The maintenance vehicle for the glass coated cathode comprises a movable frame, a main roll-over stand and an auxiliary roll-over stand; one end of the movable frame is provided with a main roll-over stand; the other end of the movable frame is provided with an auxiliary roll-over stand; the main roll-over stand and the auxiliary roll-over stand comprise bearing seats, rotating shafts, supporting plates, clamping connectors and guide rods; one end of the movable frame is provided with a rotating shaft through a bearing seat; one end of the rotating shaft is provided with a supporting plate; the supporting plate is symmetrically provided with clamping connectors. The maintenance vehicle for the glass coating cathode has compact structure and ingenious design, solves the problems of high safety risk and complex operation procedures of the existing cathode maintenance vehicle, and is particularly suitable for the needs of glass coating.

Description

Maintenance vehicle for glass coated cathode

Technical Field

The utility model relates to a maintenance vehicle for a glass coated cathode, and belongs to the technical field of glass coated cathode maintenance equipment.

Background

In the field of coated glass production, a glass coated cathode needs to be overturned for maintenance; because the glass coated cathode has the characteristics of large weight and large size, the traditional turnover work of the glass coated cathode is carried out by means of a crown block, and the problem of inconvenient operation exists. At present, a maintenance trolley such as a cathode turnover trolley disclosed in the patent of the utility model with the publication number of CN202543063U is available, and the turnover work of the cathode is completed by adopting a mode that a main rotating frame and an auxiliary rotating frame are used for fixing two ends of a coated cathode to drive the cathode to turn over. The existing cathode overturning trolley can well finish overturning work of a cathode, but has the following problems:

1. The auxiliary rotating frame of the existing cathode overturning trolley is in a free moving state, when the cathode is hung on the auxiliary rotating frame, the auxiliary rotating frame needs to be manually righted, and after the cathode is clamped on the auxiliary rotating frame, an operator can withdraw. Therefore, operators need to be positioned below the hoisting cathode for a long time, and the problem of high safety risk caused by the fact that operators are injured easily occurs when the cathode is hoisted.

2. When the existing cathode overturning trolley works, after the cathode is hung on the main rotating frame and the auxiliary rotating frame, two ends of the cathode are required to be manually clamped on the main rotating frame and the auxiliary rotating frame, and the problem of complex operation procedures exists.

Therefore, a new maintenance vehicle for the glass coated cathode needs to be developed to solve the problems existing in the existing maintenance vehicles.

Disclosure of Invention

The utility model aims at: the glass coated cathode overhauling vehicle is compact in structure and ingenious in design, and solves the problems of high safety risk and complex operation procedures of the existing cathode overhauling vehicle.

The technical scheme of the utility model is as follows:

The maintenance vehicle for the glass coated cathode comprises a movable frame, a main roll-over stand and an auxiliary roll-over stand; one end of the movable frame is provided with a main roll-over stand; the other end of the movable frame is provided with an auxiliary roll-over stand; the method is characterized in that: the main roll-over stand and the auxiliary roll-over stand comprise bearing seats, rotating shafts, supporting plates, clamping connectors and guide rods; one end of the movable frame is provided with a rotating shaft through a bearing seat; one end of the rotating shaft is provided with a supporting plate; the supporting plate is symmetrically provided with clamping connectors; guide rods are symmetrically arranged at the ends of the two ends of the supporting plate; a speed reducer is arranged on the moving frame at one end of the rotating shaft of the main roll-over stand through a driving motor; the speed reducer is connected with one end of the rotating shaft.

The supporting plate comprises a bottom plate, a limit strip and a connecting plate; one end of the rotating shaft is provided with a connecting plate; the lower end of the connecting plate is provided with a limit strip; the lower end of the limit bar is provided with a bottom plate; guide rods are arranged at two ends of the bottom plate.

The inner side of the upper end of the guide rod is provided with a guide inclined plane.

The clamping device comprises a transmission gear, a driving rack, a driven rack and a clamping sliding sleeve; the driving rack is movably arranged on the bottom plate through the supporting spring; a driven rack is slidably arranged on the bottom plate at one side of the driving rack; a transmission gear is arranged between the driven rack and the driving rack; the transmission gear is meshed with the driven rack and the driving rack; the wedge-shaped block is arranged at the upper end of the driven rack; the upper end face of the limit bar above the wedge block is provided with a clamping sliding sleeve in a sliding way; the lower end of the clamping sliding sleeve is connected with a push rod; the lower end of the pushing rod is connected with a wedge-shaped sliding rail on the wedge-shaped block through a wedge-shaped sliding groove; an inner slide bar is slidably arranged in the clamping sliding sleeve; one end of the inner slide bar is connected with an operating rod; one end of the operating rod extends to the outside of the clamping sliding sleeve and is provided with a rotary handle; a reset spring is arranged in the clamping sliding sleeve at one end of the inner sliding strip; a locating block is arranged on a limit bar at one end of the operating rod; the rotary handle is connected with the positioning block in an intermittent clamping way.

Two groups of support sliding blocks are symmetrically arranged on the moving frame below the auxiliary roll-over stand through sliding rails; the movable frame is provided with an adjusting screw rod; the adjusting screw rod is connected with the two groups of supporting sliding blocks; when the adjusting screw rod rotates forwards, the two groups of supporting sliding blocks are mutually close; when the adjusting screw rod reversely rotates, the two groups of supporting sliding blocks are mutually separated.

The utility model has the advantages that:

The maintenance vehicle for the glass coated cathode has the advantages of compact structure and ingenious design, the auxiliary roll-over stand is righted for a long time, and the cathode is not required to be locked manually, so that the problems of high safety risk and complex operation procedures of the existing cathode maintenance vehicle are solved, and the maintenance vehicle is particularly suitable for the needs of glass coating.

Drawings

FIG. 1 is a schematic top view of the present utility model;

FIG. 2 is a schematic diagram of a front view structure of the present utility model;

FIG. 3 is a schematic view of the structure of the sub roll-over stand of the present utility model;

FIG. 4 is a schematic view of the structure in the direction A-A in FIG. 1;

FIG. 5 is an enlarged schematic view of the structure shown at B in FIG. 2;

FIG. 6 is a schematic view of the structure of FIG. 5 in a clamped state;

fig. 7 is a schematic view of the structure of fig. 5 in a released state.

In the figure: 1. a moving frame; 2. a main roll-over stand; 3. an auxiliary roll-over stand; 4. a bearing seat; 5. a rotation shaft; 6. a support plate; 7. a clip connector; 8. a guide rod; 9. a driving motor; 10. a speed reducer; 11. a splice plate; 12. a limit bar; 13. adjusting a screw rod; 14. a guide slope; 15. a support spring; 16. a driving rack; 17. a driven rack; 18. a transmission gear; 19. wedge blocks; 20. the sliding sleeve is clamped; 21. a push rod; 22. an inner slide; 23. an operation lever; 24. rotating the handle; 25. a return spring; 26. a positioning block; 27. a support slider; 28. a bottom plate.

Detailed Description

The overhauling vehicle of the glass coated cathode comprises a moving frame 1, a main roll-over stand 2 and an auxiliary roll-over stand 3; one end of the movable frame 1 is provided with a main roll-over stand 2; the other end of the moving frame 1 is provided with a sub roll-over stand 3 (see fig. 1 and 2 of the specification).

The main roll-over stand 2 and the sub roll-over stand 3 include a bearing housing 4, a rotation shaft 5, a support plate 6, a clamper 7, and a guide bar 8.

One end of the movable frame 1 is provided with a rotary shaft 5 through a bearing seat 4; one end of the rotating shaft 5 is provided with a supporting plate 6; the supporting plate 6 is symmetrically provided with clamping connectors 7; guide rods 8 are symmetrically arranged at the ends of the two ends of the supporting plate 6.

The guide rod 8 is provided inside its upper end with a guide slope 14 (see fig. 3 of the specification). The purpose of the guide ramp 14 is to: so that the glass coated cathode can fall on the supporting plate 6 along the guide inclined plane 14 of the guide rod 8 to perform the guiding and positioning functions. Therefore, the problem that the cathode of the glass coating film deviates from the installation position can be avoided.

A speed reducer 10 is arranged on the moving frame 1 at one end of the rotating shaft 5 of the main roll-over stand 2 through a driving motor 9; the speed reducer 10 is connected to one end of the rotary shaft 5 (see fig. 1 and 2 of the specification). The speed reducer 10 has a self-locking function, and is outsourcing equipment. When the driving motor 9 works, the main roll-over stand 2 can be driven to rotate freely through the speed reducer 10.

The supporting plate 6 comprises a bottom plate 28, a limit strip 12 and an engagement plate 11; one end of the rotating shaft 5 is provided with a connecting plate 11; the lower end of the joint plate 11 is provided with a limit strip 12; the lower end of the limit bar 12 is provided with a bottom plate 28; the bottom plate 28 is provided with guide bars 8 at both ends (see fig. 3 of the specification).

The limiting strip 12 has the function of limiting the cathode coated with the glass to be overhauled from the end.

The clamping device 7 comprises a transmission gear 18, a driving rack 16, a driven rack 17 and a clamping sliding sleeve 20 (see fig. 2 and 5 of the specification).

The driving rack 16 is movably arranged on the bottom plate 28 through the supporting spring 15. The upper end of the drive rack 16 extends above the floor 28; when the driving rack 16 is pressed, it will move downward against the elastic force of the supporting spring 15; when the driving rack 16 loses pressure, the driving rack 16 is reset under the action of the elastic force of the supporting spring 15.

A bottom plate 28 at one side of the driving rack 16 is slidably provided with a driven rack 17; the driving rack 16 and the driven rack 17 are respectively and slidably arranged in the bottom plate 28 through sliding rails; the driving rack 16 and the driven rack 17 can only move up and down and can not generate other movements when being stressed.

A transmission gear 18 is arranged between the driven rack 17 and the driving rack 16; the transmission gear 18 is engaged with the driven rack 17 and the driving rack 16 (see fig. 5 and 6 of the specification). The driving rack 16 moves downwards to drive the transmission gear 18 to rotate clockwise; the driven rack 17 will be driven upwards during clockwise rotation of the transfer gear 18.

The wedge-shaped block 19 is arranged at the upper end of the driven rack 17; the upper end face of the limit bar 12 above the wedge block 19 is provided with a clamping sliding sleeve 20 in a sliding way; the lower end of the clamping sliding sleeve 20 is connected with a push rod 21; the lower end of the push rod 21 is connected with a wedge-shaped sliding rail on the wedge-shaped block 19 through a wedge-shaped sliding groove (see fig. 5 and 6 of the specification).

When the wedge block 19 moves upwards, the wedge slide rail pushes the push rod 21 to drive the clamping sliding sleeve 20 to move transversely.

An inner slide bar 22 is slidably arranged in the clamping sliding sleeve 20; one end of the inner slide bar 22 is connected with an operating rod 23; one end of the operating rod 23 extends to the outside of the clamping sliding sleeve 20 and is provided with a rotary handle 24; the inside of the clamping sliding sleeve 20 at one end of the inner sliding strip 22 is provided with a reset spring 25. When in operation, the inner slide bar 22 can be pulled by the operating rod 23 to move against the elastic force of the return spring 25.

The limiting bar 12 at one end of the operating rod 23 is provided with a positioning block 26; the rotary handle 24 is connected with the positioning block 26 in an intermittent clamping way. When the sliding sleeve is in operation, after the inner sliding strip 22 is pulled by the operating rod 23 to retract into the clamping sliding sleeve 20, the rotating handle 24 is rotated to be in clamping connection with the positioning block 26, so that the inner sliding strip 22 can be limited in the clamping sliding sleeve 20 (see fig. 7 of the specification).

Two groups of support sliding blocks 27 are symmetrically arranged on the moving frame 1 below the auxiliary roll-over stand 3 through sliding rails; the movable frame 1 is provided with an adjusting screw rod 13; the adjusting screw rod 13 is connected with two groups of supporting sliding blocks 27 (see fig. 1 and 4 of the specification); when the adjusting screw rod 13 rotates forwards, the two groups of supporting sliding blocks 27 are mutually close; the two sets of support sliders 27 are separated from each other when the adjustment screw 13 rotates in the opposite direction.

When the maintenance vehicle for the glass coated cathode works, the adjusting screw rod 13 is rotated forward at first to enable the two groups of support sliding blocks 27 to be close to each other and move to the lower part of the auxiliary roll-over stand 3 to keep contact with the auxiliary roll-over stand. The secondary roll-over stand 3 will now remain level all the time under the action of the support slide 27. So can solve the during operation manual work and right the problem that has the risk high with vice roll-over stand 3. After the auxiliary roll-over stand 3 is leveled, the driving motor 9 drives the main roll-over stand 2 to rotate to a horizontal state through the speed reducer 10.

After the above work is finished, the glass coating cathode is hoisted, so that two ends of the glass coating cathode are placed on the auxiliary roll-over stand 3 and the main roll-over stand 2 under the guidance of the guide rod 8, at the moment, two sides of the glass coating cathode are in contact with the guide rod 8, and two ends of the glass coating cathode are in contact with the limit strips 12.

During the downward movement of the glass coated cathode, it will push down the drive rack 16 to move it downward. The driving rack 16 moves downwards to drive the transmission gear 18 to rotate clockwise; the driven rack 17 will be driven upwards during clockwise rotation of the transfer gear 18.

The driven rack 17 drives the wedge block 19 to synchronously move upwards in the upward moving process. When the wedge block 19 moves upwards, the wedge slide rail pushes the push rod 21 to drive the clamping sliding sleeve 20 to move transversely. Finally, the inner slide 22 in the clamping sliding sleeve 20 moves to the upper part of the bottom plate 28 and is clamped with the cathode base of the glass coating. The glass film plating cathode is fixedly connected with the auxiliary roll-over stand 3 and the main roll-over stand 2 under the limit of the guide rod 8, the limit strip 12 and the inner slide strip 22.

The adjustment screw 13 is then rotated in opposite directions to separate the two sets of support blocks 27 from each other and from contact with the secondary roll-over stand 3. And then the driving motor 9 can overturn the glass coated cathode to a proper angle through the speed reducer 10 under the cooperation of the main overturning frame 2 and the auxiliary overturning frame 3 for overhauling.

After the maintenance is finished, the driving motor 9 can turn the cathode of the glass coating to a state with the front face upwards through the speed reducer 10. Then the inner slide bar 22 is pulled by the operating rod 23 to retract into the clamping sliding sleeve 20, and the rotary handle 24 is rotated to be in clamping connection with the positioning block 26. At this time, the inner slide 22 is limited inside the clamping sliding sleeve 20 and is separated from contact with the cathode of the glass coating. And then lifting away the overhauled glass coated cathode to finish overhauling work of the glass coated cathode. The maintenance vehicle of the glass coated cathode can enter the next working cycle.

The maintenance vehicle for the glass coated cathode has compact structure and ingenious design, the auxiliary roll-over stand 3 is righted for a long time, and the cathode is not required to be locked manually, so that the problems of high safety risk and complex operation procedures of the existing cathode maintenance vehicle are solved, and the maintenance vehicle is particularly suitable for the needs of glass coating.

Claims (5)

1. The overhauling vehicle for the glass coated cathode comprises a movable frame (1), a main roll-over stand (2) and an auxiliary roll-over stand (3); one end of the movable frame (1) is provided with a main roll-over stand (2); the other end of the movable frame (1) is provided with an auxiliary roll-over stand (3); the method is characterized in that: the main roll-over stand (2) and the auxiliary roll-over stand (3) comprise bearing seats (4), rotating shafts (5), supporting plates (6), clamping connectors (7) and guide rods (8); one end of the movable frame (1) is provided with a rotating shaft (5) through a bearing seat (4); one end of the rotating shaft (5) is provided with a supporting plate (6); the supporting plate (6) is symmetrically provided with clamping connectors (7); guide rods (8) are symmetrically arranged at the ends of the two ends of the supporting plate (6); a speed reducer (10) is arranged on the moving frame (1) at one end of the rotating shaft (5) of the main roll-over stand (2) through a driving motor (9); the speed reducer (10) is connected with one end of the rotating shaft (5).

2. The maintenance vehicle for a glass coated cathode according to claim 1, wherein: the supporting plate (6) comprises a bottom plate, a limit strip (12) and a connecting plate (11); one end of the rotating shaft (5) is provided with a connecting plate (11); the lower end of the connecting plate (11) is provided with a limit strip (12); the lower end of the limit bar (12) is provided with a bottom plate (28); guide rods (8) are arranged at two ends of the bottom plate (28).

3. The maintenance vehicle for a glass coated cathode according to claim 2, wherein: the inner side of the upper end of the guide rod (8) is provided with a guide inclined plane (14).

4. The maintenance vehicle for a glass coated cathode according to claim 2, wherein: the clamping connector (7) comprises a transmission gear (18), a driving rack (16), a driven rack (17) and a clamping sliding sleeve (20); the driving rack (16) is movably arranged on the bottom plate (28) through the supporting spring (15); a bottom plate (28) at one side of the driving rack (16) is internally provided with a driven rack (17) in a sliding way; a transmission gear (18) is arranged between the driven rack (17) and the driving rack (16); the transmission gear (18) is meshed with the driven rack (17) and the driving rack (16); the upper end of the driven rack (17) is provided with a wedge block (19); the upper end face of the limit bar (12) above the wedge block (19) is provided with a clamping sliding sleeve (20) in a sliding way; the lower end of the clamping sliding sleeve (20) is connected with a pushing rod (21); the lower end of the pushing rod (21) is connected with a wedge-shaped sliding rail on the wedge-shaped block (19) through a wedge-shaped sliding groove; an inner slide bar (22) is slidably arranged in the clamping sliding sleeve (20); one end of the inner slide bar (22) is connected with an operating rod (23); one end of the operating rod (23) extends to the outside of the clamping sliding sleeve (20) and is provided with a rotary handle (24); a reset spring (25) is arranged in the clamping sliding sleeve (20) at one end of the inner sliding strip (22); a positioning block (26) is arranged on the limit bar (12) at one end of the operating rod (23); the rotary handle (24) is connected with the positioning block (26) in an intermittent clamping way.

5. The maintenance vehicle for a glass coated cathode according to claim 1, wherein: two groups of support sliding blocks (27) are symmetrically arranged on the moving frame (1) below the auxiliary overturning frame (3) through sliding rails; the movable frame (1) is provided with an adjusting screw rod (13); the adjusting screw rod (13) is connected with two groups of supporting sliding blocks (27); when the adjusting screw rod (13) rotates forwards, the two groups of supporting sliding blocks (27) are mutually close; when the adjusting screw rod (13) reversely rotates, the two groups of supporting sliding blocks (27) are separated from each other.