CN216635037U - Die device for manufacturing unmanned aerial vehicle paddle - Google Patents

Abstract

The utility model belongs to the field of unmanned aerial vehicles, and particularly relates to a mold device for manufacturing an unmanned aerial vehicle paddle, which comprises a feeding mechanism, a lifting mechanism and a turnover mechanism, wherein the turnover mechanism is used for preventing the surface of a mold from being damaged during demolding, the lifting mechanism is arranged above the feeding mechanism, the turnover mechanism is arranged below the lifting mechanism, the feeding mechanism comprises a workbench, a rail, a worm, a moving motor and a bearing seat, and the rail is arranged above the workbench. The utility model adopts the lifting mechanism and the turnover mechanism, utilizes the electric push rod to stretch and push the bracket and the upper die to move downwards, is matched with the action of the springs arranged at four corners below the bracket, can be uniformly molded in the die, and then carries out rotary motion through the turnover mechanism, can freely demold the molded blade, avoids the damage in the demolding process, thereby improving the die manufacturing efficiency, reducing manual operation and improving the working quality.

Description

Die device for manufacturing unmanned aerial vehicle paddle

Technical Field

The utility model belongs to the field of unmanned aerial vehicles, and particularly relates to a mold device for manufacturing an unmanned aerial vehicle paddle.

Background

Drones are unmanned planes operated by radio remote control devices and self-contained program control devices, or are operated autonomously, either completely or intermittently, by on-board computers, with more and more drones entering various industries. Among the prior art, general unmanned aerial vehicle paddle need demold the inside paddle of model when carrying out the mould preparation, damages the paddle surface when causing the drawing of patterns very easily, and the shaping is inefficient.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a die device for manufacturing an unmanned aerial vehicle blade.

The technical scheme adopted by the utility model is as follows:

a die device for manufacturing blades of an unmanned aerial vehicle comprises a feeding mechanism, a lifting mechanism and a turnover mechanism for preventing the surface of a die from being damaged during demoulding, the lifting mechanism is arranged above the feeding mechanism, the turnover mechanism is arranged below the lifting mechanism, the feeding mechanism comprises a workbench, a track, a worm, a mobile motor and a bearing seat, the track is arranged above the workbench, the worm is arranged at the inner side of the track, the moving motor is arranged at one side of the worm, the bearing seat is arranged above the track, the lifting mechanism comprises a lifting frame, an electric push rod, a bracket, a spring and an upper die, the electric push rod is arranged on the inner side of the lifting frame, the bracket is arranged below the electric push rod, the springs are arranged at four corners below the bracket, and the upper die is arranged on the inner side of each spring.

Preferably: tilting mechanism includes swivel mount, pivot, drive gear, first motor, pinch-off blades, bed die, swivel mount top inboard is provided with the pivot, the pivot front side is provided with drive gear, the drive gear below is provided with drive gear, the drive gear front side is provided with first motor, the pivot inboard is provided with the pinch-off blades, the pinch-off blades inboard is provided with the bed die.

According to the arrangement, the first motor is started to drive the driving gear and the transmission gear to rotate, and the transmission gear drives the rotating shaft and the clamping plate to perform turnover motion with the lower die.

Preferably: tilting mechanism includes swivel mount, pivot, follows driving wheel, action wheel, second motor, pinch-off blades, bed die, swivel mount top inboard is provided with the pivot, the pivot front side is provided with follow the driving wheel, be provided with from the driving wheel below the action wheel, the action wheel front side is provided with the second motor, the pivot inboard is provided with the pinch-off blades, the pinch-off blades inboard is provided with the bed die.

According to the arrangement, the second motor is started to drive the driving wheel and the driven wheel to rotate, and the driven wheel drives the rotating shaft and the clamping plate to perform turnover motion with the lower die.

Preferably: the workstation with the track passes through welded connection, the track with the worm passes through the bearing and connects, the worm with the moving motor key-type connection, the track with bear seat sliding connection.

So set up, the bearing connection has guaranteed the worm is nimble rotatory.

Preferably: the crane with electric putter passes through bolted connection, electric putter with welded connection is passed through to the bracket, the bracket with the spring passes through welded connection, the bracket with go up the mould and pass through welded connection.

So set up, bolted connection is convenient for dismouting change electric putter.

Preferably: the swivel mount with the pivot is passed through the bearing and is connected, the pivot with drive gear passes through welded connection, drive gear with drive gear meshing transmission, drive gear with first motor key-type connection, the pivot with the pinch-off blades passes through welded connection, the pinch-off blades with the bed die passes through bolted connection.

According to the arrangement, when the die is manufactured, the rotating shaft and the clamping plate are connected firmly, and the bearing connection ensures that the rotating shaft rotates flexibly.

Preferably: the swivel mount with the pivot is passed through the bearing and is connected, the pivot with pass through welded connection from the driving wheel, from the driving wheel with the action wheel passes through the belt and connects, the action wheel with second motor key-type connection, the pivot with the pinch-off blades passes through welded connection, the pinch-off blades with the bed die passes through bolted connection.

According to the arrangement, when the die is manufactured, the rotating shaft and the clamping plate are connected firmly, and the bearing connection ensures that the rotating shaft rotates flexibly.

The utility model has the beneficial effects that: adopt elevating system and tilting mechanism, utilize electric putter to stretch out and draw back and promote the bracket and go up the mould downstream, coordinate the effect of bracket below four corners installation spring, can evenly carry out the shaping in the mould, rethread tilting mechanism carries out rotary motion, can carry out the free drawing of patterns with fashioned paddle, avoids the drawing of patterns in-process to appear damaging to improve mould manufacturing efficiency, reduce manual operation, improve work quality.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the principles of the utility model and not to limit the utility model. In the drawings:

fig. 1 is a schematic front view of an embodiment 1 of a mold device for manufacturing an unmanned aerial vehicle blade according to the present invention;

fig. 2 is a schematic perspective view of an embodiment 1 of the mold device for manufacturing the blades of the unmanned aerial vehicle, according to the present invention;

fig. 3 is a schematic view of a feeding mechanism of the mold device for manufacturing the unmanned aerial vehicle blade, provided by the utility model;

fig. 4 is a schematic view of a lifting mechanism of the mold device for manufacturing the unmanned aerial vehicle blade, provided by the utility model;

fig. 5 is a schematic view of a turnover mechanism in embodiment 1 of the die device for manufacturing the unmanned aerial vehicle blade, disclosed by the utility model;

fig. 6 is a schematic view of a turnover mechanism in embodiment 2 of the die device for manufacturing the unmanned aerial vehicle blade.

The reference numerals are illustrated below:

1. a feeding mechanism; 2. a lifting mechanism; 3. a turnover mechanism; 11. a work table; 12. a track; 13. a worm; 14. a moving motor; 15. a bearing seat; 21. a lifting frame; 22. an electric push rod; 23. a bracket; 24. a spring; 25. an upper die; 31. a rotating frame; 32. a rotating shaft; 33. a transmission gear; 34. a drive gear; 35. a first motor; 36. a clamping plate; 37. a lower die; 301. a driven wheel; 302. a driving wheel; 303. a second motor.

Detailed Description

The utility model is further illustrated by the following examples in conjunction with the accompanying drawings.

Example 1

As shown in fig. 1, 2, 3, 4 and 5, a mold device for manufacturing an unmanned aerial vehicle blade comprises a feeding mechanism 1, a lifting mechanism 2 and a turnover mechanism 3 for preventing the surface of the mold from being damaged during demolding, wherein the lifting mechanism 2 is arranged above the feeding mechanism 1, the turnover mechanism 3 is arranged below the lifting mechanism 2, the feeding mechanism 1 comprises a workbench 11, a rail 12, a worm 13, a moving motor 14 and a bearing seat 15, the rail 12 is arranged above the workbench 11, the worm 13 is arranged inside the rail 12, the moving motor 14 is arranged on one side of the worm 13, the bearing seat 15 is arranged above the rail 12, the lifting mechanism 2 comprises a lifting frame 21, an electric push rod 22, a bracket 23, a spring 24 and an upper mold 25, the electric push rod 22 is arranged inside the lifting frame 21, the bracket 23 is arranged below the electric push rod 22, and the spring 24 is arranged at four corners below the bracket 23, the inner side of the spring 24 is provided with an upper die 25, the turnover mechanism 3 comprises a rotating frame 31, a rotating shaft 32, a transmission gear 33, a driving gear 34, a first motor 35, a clamping plate 36 and a lower die 37, the rotating shaft 32 is arranged on the inner side above the rotating frame 31, the transmission gear 33 is arranged on the front side of the rotating shaft 32, the driving gear 34 is arranged below the transmission gear 33, the first motor 35 is arranged on the front side of the driving gear 34, the clamping plate 36 is arranged on the inner side of the rotating shaft 32, and the lower die 37 is arranged on the inner side of the clamping plate 36.

Preferably: the workbench 11 is connected with the track 12 through welding, the track 12 is connected with the worm 13 through a bearing, the worm 13 is connected with the movable motor 14 through a key, and the track 12 is connected with the bearing seat 15 in a sliding manner; the lifting frame 21 is connected with the electric push rod 22 through a bolt, the electric push rod 22 is connected with the bracket 23 through welding, the bracket 23 is connected with the spring 24 through welding, and the bracket 23 is connected with the upper die 25 through welding; the rotating frame 31 is connected with the rotating shaft 32 through a bearing, the rotating shaft 32 is connected with the transmission gear 33 through welding, the transmission gear 33 is in meshing transmission with the driving gear 34, the driving gear 34 is in key connection with the first motor 35, the rotating shaft 32 is connected with the clamping plate 36 through welding, and the clamping plate 36 is connected with the lower die 37 through bolts.

Example 2

As shown in fig. 3, 4, and 6, the present embodiment is different from embodiment 1 in that: the turnover mechanism 3 comprises a rotating frame 31, a rotating shaft 32, a driven wheel 301, a driving wheel 302, a second motor 303, a clamping plate 36 and a lower die 37, wherein the rotating shaft 32 is arranged on the inner side above the rotating frame 31, the driven wheel 301 is arranged on the front side of the rotating shaft 32, the driving wheel 302 is arranged below the driven wheel 301, the second motor 303 is arranged on the front side of the driving wheel 302, the clamping plate 36 is arranged on the inner side of the rotating shaft 32, and the lower die 37 is arranged on the inner side of the clamping plate 36; the rotating frame 31 is connected with the rotating shaft 32 through a bearing, the rotating shaft 32 is connected with the driven wheel 301 through welding, the driven wheel 301 is connected with the driving wheel 302 through a belt, the driving wheel 302 is connected with the second motor 303 through a key, the rotating shaft 32 is connected with the clamping plate 36 through welding, and the clamping plate 36 is connected with the lower die 37 through a bolt.

The working principle is as follows: firstly, the paddle material is placed in a lower die 37, a worm 13 is driven to rotate by starting a moving motor 14, the worm 13 drives a bearing seat 15 to lift a turnover mechanism 3 to move left and right on a track 12, the paddle material in the lower die 37 is sent to the lower part of an upper die 25, an electric push rod 22 is arranged on a lifting frame 21 to telescopically push a support seat 23 and the upper die 25 to move downwards, the support seat 23 and the upper die 25 can be uniformly compacted in the die under the action of springs 24 arranged at four corners below the support seat 23, after the manufacture is finished, a first motor 35 is started to drive a drive gear 34 and a transmission gear 33 to rotate, the transmission gear 33 drives a rotating shaft 32 and a clamping plate 36 to perform turnover movement with the lower die 37, or a second motor 303 is started to drive a driving wheel 302 and a driven wheel 301 to rotate, the driven wheel 301 drives the rotating shaft 32 and the clamping plate 36 to perform turnover movement with the lower die 37, and the formed paddle is turned over and fallen off, avoid appearing damaging in the drawing of patterns process to improve mould manufacturing efficiency.

While the preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, the present invention is not limited to the above embodiments, and various changes can be made within the knowledge of those skilled in the art without departing from the spirit of the present invention.

Claims (7)

1. The utility model provides an unmanned aerial vehicle paddle mould device for manufacturing which characterized in that: the device comprises a feeding mechanism (1), a lifting mechanism (2) and a turnover mechanism (3) for preventing the surface of a die from being damaged during demoulding, wherein the lifting mechanism (2) is arranged above the feeding mechanism (1), and the turnover mechanism (3) is arranged below the lifting mechanism (2);

the feeding mechanism (1) comprises a workbench (11), a track (12), a worm (13), a moving motor (14) and a bearing seat (15), wherein the track (12) is arranged above the workbench (11), the worm (13) is arranged on the inner side of the track (12), the moving motor (14) is arranged on one side of the worm (13), and the bearing seat (15) is arranged above the track (12);

elevating system (2) include crane (21), electric putter (22), bracket (23), spring (24), go up mould (25), crane (21) inboard is provided with electric putter (22), electric putter (22) below is provided with bracket (23), bracket (23) below four corners is provided with spring (24), spring (24) inboard is provided with go up mould (25).

2. The die device for manufacturing the unmanned aerial vehicle blade of claim 1, wherein: tilting mechanism (3) are including swivel mount (31), pivot (32), transmission gear (33), drive gear (34), first motor (35), clamp plate (36), bed die (37), swivel mount (31) top inboard is provided with pivot (32), pivot (32) front side is provided with drive gear (33), drive gear (33) below is provided with drive gear (34), drive gear (34) front side is provided with first motor (35), pivot (32) inboard is provided with clamp plate (36), clamp plate (36) inboard is provided with bed die (37).

3. The die device for manufacturing the unmanned aerial vehicle blade of claim 1, wherein: tilting mechanism (3) include swivel mount (31), pivot (32), follow driving wheel (301), action wheel (302), second motor (303), pinch-off blades (36), bed die (37), swivel mount (31) top inboard is provided with pivot (32), pivot (32) front side is provided with follow driving wheel (301), be provided with from driving wheel (301) below action wheel (302), action wheel (302) front side is provided with second motor (303), pivot (32) inboard is provided with pinch-off blades (36), pinch-off blades (36) inboard is provided with bed die (37).

4. The die device for manufacturing the unmanned aerial vehicle blade of claim 1, wherein: workstation (11) with track (12) pass through welded connection, track (12) with worm (13) pass through the bearing and connect, worm (13) with moving motor (14) key-type connection, track (12) with bear seat (15) sliding connection.

5. The die device for manufacturing the unmanned aerial vehicle blade of claim 1, wherein: the lifting frame (21) is connected with the electric push rod (22) through a bolt, the electric push rod (22) is connected with the bracket (23) through welding, the bracket (23) is connected with the spring (24) through welding, and the bracket (23) is connected with the upper die (25) through welding.

6. The die device for manufacturing the unmanned aerial vehicle blade of claim 2, wherein: the swivel mount (31) with pivot (32) pass through the bearing and connect, pivot (32) with drive gear (33) pass through welded connection, drive gear (33) with drive gear (34) meshing transmission, drive gear (34) with first motor (35) key-type connection, pivot (32) with pinch-off blades (36) pass through welded connection, pinch-off blades (36) with bed die (37) passes through bolted connection.

7. The die device for manufacturing the unmanned aerial vehicle blade of claim 3, wherein: the swivel mount (31) with pivot (32) pass through the bearing and connect, pivot (32) with follow driving wheel (301) and pass through welded connection, follow driving wheel (301) with action wheel (302) pass through the belt and connect, action wheel (302) with second motor (303) key-type connection, pivot (32) with pinch-off blades (36) pass through welded connection, pinch-off blades (36) with bed die (37) pass through bolted connection.

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