CN216190616U - Mechanical suspension arm for machining - Google Patents

Abstract

The utility model discloses a mechanical suspension arm for machining, which belongs to the field of machining and comprises a suspension arm frame, wherein a sliding groove is formed in the outer side surface of the suspension arm frame, a sliding suspension arm is arranged on the inner side of the sliding groove, a wire guide wheel is arranged on the upper surface of the left end of the suspension arm frame, the sliding groove penetrates through the outer side surface of the suspension arm frame, a sliding structure is formed between the sliding groove and the sliding suspension arm, a rotating structure is formed between the sliding suspension arm and a take-up rotating shaft, the suspension arm frame and the wire guide wheel are in threaded connection, a transmission guide cable is connected to the outer side surface of the wire guide wheel, and the transmission guide cable is fixedly connected with the sliding suspension arm. The whole body is moved to be lifted everywhere through punching the object, so that distance transmission and height transmission are realized and simultaneously the whole structure is simple, meanwhile, the whole body can be installed to the upper end to save occupied space, and the device has better adaptability.

Description

Mechanical suspension arm for machining

Technical Field

The utility model relates to the field of machining, in particular to a mechanical suspension arm for machining.

Background

A hoisting machine, which means an electromechanical device for vertically lifting or vertically lifting and horizontally moving a heavy object, and is defined as a lift having a rated lifting capacity of 0.5 ton or more; rated load lifting capacity is more than or equal to 1 ton, and promote the hoist and the fixed electric block of bearing form etc. of height more than or equal to 2m, in the aspect of machining production, the jack-up is also can play certain effect to bloodletting processing and production, but the transmission lifts by crane the mode and although the flexibility is good, nevertheless to the relatively single work flow of transportation task, the price is comparatively expensive, and the volume is great need to occupy great space, improve to above problem and the in-service use for this, make it have better practicality

SUMMERY OF THE UTILITY MODEL

1. Technical problem to be solved

In view of the problems in the prior art, an object of the present invention is to provide a mechanical suspension arm for machining, which can move an object to be lifted to a desired position to achieve simultaneous distance transfer and height transfer, has a simple structure, can be mounted on an upper end to save space, and has good adaptability.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

The mechanical suspension arm for machining comprises a suspension arm frame, wherein a sliding groove is formed in the outer side surface of the suspension arm frame, a sliding suspension arm is arranged on the inner side of the sliding groove, a take-up rotating shaft is arranged on the inner side of the sliding suspension arm, and a wire guide wheel is arranged on the upper surface of the left end of the suspension arm frame.

Furthermore, the sliding groove penetrates through the outer side surface of the boom frame, a sliding structure is formed between the sliding groove and the sliding boom, a rotating structure is formed between the sliding boom and the take-up rotating shaft, the boom frame is in threaded connection with the wire guide wheel, the outer side surface of the wire guide wheel is connected with a transmission guide cable, and the transmission guide cable is fixedly connected with the sliding boom.

Furthermore, a rotating wheel rod is arranged at the right side end of the transmission guide cable, a rotating structure is formed between the rotating wheel rod and the wire guide wheel, a fixed plate is fixed at the right side end of the boom frame, the boom frame is connected with the fixed plate in a welding mode, a winding guide cable is arranged in the middle of the winding rotating shaft, and penetrates through the bottom end of the fixed plate.

Furthermore, the front end lateral surface of runner bar is provided with the drive belt, and constitutes revolution mechanic between drive belt and the runner bar, settle directly over the fixed plate has driving motor, and constitutes threaded connection between driving motor and the fixed plate, driving motor's front end is provided with motor gear, and is fixed connection between driving motor and the motor gear, driving motor passes through the drive belt and constitutes revolution mechanic between the runner bar.

Furthermore, a winding gear is arranged right below the motor gear, the winding gear is meshed with the motor gear and is connected with the fixed plate, a rotating structure is formed between the winding gear and the fixed plate, a wired notch is formed in the left side surface of the fixed plate, and the wire slot penetrates through the bottom side surface of the fixed plate.

Further, both ends are connected with and receive the line rope around receiving the pivot, and receive the line rope and receive intertwine between the line pivot, the bottom of receiving the line rope is connected with fixed hanger plate, and fixed hanger plate and receive and be welded connection between the line rope, the bottom of spiral gear is provided with the spiral arbor wheel, and is fixed connection between spiral arbor wheel and the spiral gear, receive both sides end-to-end connection has the linkage gear around the line pivot, and receive and be fixed connection between line pivot and the linkage gear.

3. Advantageous effects

Compared with the prior art, the utility model has the advantages that:

the scheme includes that a sliding suspension arm is slidably moved to the leftmost end of a suspension arm frame through a sliding groove, a take-up rope on a take-up rotating shaft in the sliding suspension arm is in a pay-off state at the moment, the take-up rope is placed downwards on a fixed suspension plate, an object is placed on the fixed suspension plate, a driving motor on the fixed plate is driven to drive a motor gear to rotate, the take-up rope is collected by driving a take-up gear to rotate a take-up shaft wheel, when the take-up rope rotates, a take-up guide cable is wound through a wire notch, so that the take-up guide cable is wound at the same time, the take-up rotating shaft is driven to rotate, when the take-up rotating shaft rotates, linkage gears connected at two ends are meshed, the take-up rotating shafts on two sides rotate at the same time, the take-up rope is driven to rotate while rotating, and a driving transmission belt drives a rotating wheel rod to rotate through the driving motor, when the rotating wheel rod rotates, the transmission guide rope is moved through rotation of the guide wheel, the sliding suspension arm is made to slide to the right side, the object on the fixed suspension plate is moved to a higher position, the whole fixed suspension plate is lifted everywhere through moving the object to the position where the object is rushed, distance transmission and height transmission are achieved, meanwhile, the whole structure is simple, meanwhile, the whole fixed suspension plate can be installed to the upper end to save occupied space, and the fixed suspension plate has good adaptability.

Drawings

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

FIG. 2 is a schematic view of the winding gear structure of the present invention;

fig. 3 is a schematic view of a linkage gear structure of the present invention.

The reference numbers in the figures illustrate:

1. a boom frame; 2. a sliding groove; 3. sliding the boom; 4. a wire take-up rotating shaft; 5. a wire guide wheel; 6. a transmission guide cable; 7. a fixing plate; 8. a wire winding guide cable; 9. rotating the wheel lever; 10. a transmission belt; 11. a drive motor; 12. a motor gear; 13. a wire notch; 14. a winding gear; 15. a wire is taken up; 16. fixing the hanging plate; 17. a spool wheel; 18. a linkage gear.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

Referring to fig. 1-3, a mechanical arm for machining includes an arm frame 1, a sliding groove 2 is formed on an outer surface of the arm frame 1, a sliding arm 3 is disposed inside the sliding groove 2, a take-up rotating shaft 4 is disposed inside the sliding arm 3, and a wire guide wheel 5 is disposed on an upper surface of a left end of the arm frame 1.

Referring to fig. 1, the sliding groove 2 penetrates through the outer side surface of the boom frame 1, a sliding structure is formed between the sliding groove 2 and the sliding boom 3, a rotating structure is formed between the sliding boom 3 and the wire winding rotating shaft 4, the boom frame 1 is in threaded connection with the wire guide wheel 5, the outer side surface of the wire guide wheel 5 is connected with the transmission guide cable 6, and the transmission guide cable 6 is fixedly connected with the sliding boom 3.

Referring to fig. 1, a rotating wheel rod 9 is disposed at the right end of the transmission guide cable 6, a rotating structure is formed between the rotating wheel rod 9 and the guide wire wheel 5, a fixing plate 7 is fixed at the right end of the boom frame 1, the boom frame 1 and the fixing plate 7 are connected by welding, a winding guide cable 8 is disposed at the middle position of the winding shaft 4, and the winding guide cable 8 penetrates through the bottom end of the fixing plate 7.

Referring to fig. 1, a driving belt 10 is disposed on an outer side surface of a front end of the rotating wheel rod 9, a rotating structure is formed between the driving belt 10 and the rotating wheel rod 9, a driving motor 11 is disposed right above the fixing plate 7, the driving motor 11 and the fixing plate 7 are in threaded connection, a motor gear 12 is disposed at a front side end of the driving motor 11, the driving motor 11 and the motor gear 12 are fixedly connected, and the driving motor 11 and the rotating wheel rod 9 form the rotating structure through the driving belt 10.

Referring to fig. 1, a winding gear 14 is disposed right below the motor gear 12, the winding gear 14 is engaged with the motor gear 12, a rotating structure is formed between the winding gear 14 and the fixing plate 7, a wire slot 13 is formed in a left side surface of the fixing plate 7, and the wire slot 13 penetrates through a bottom side surface of the fixing plate 7.

Referring to fig. 2, the front end and the rear end of the take-up rotating shaft 4 are connected with the take-up rope 15, the take-up rope 15 and the take-up rotating shaft 4 are wound with each other, the bottom end of the take-up rope 15 is connected with the fixed hanging plate 16, the fixed hanging plate 16 is welded with the take-up rope 15, the bottom end of the winding gear 14 is provided with the winding shaft wheel 17, the winding shaft wheel 17 is fixedly connected with the winding gear 14, the tail ends of the front side and the rear side of the take-up rotating shaft 4 are connected with the linkage gears 18, the take-up rotating shaft 4 is fixedly connected with the linkage gears 18, and the whole body is lifted everywhere by moving the object to the impact position, so that distance transmission and height transmission can be carried out simultaneously.

When in use: firstly, the sliding suspension arm 3 is moved to the leftmost end of the suspension arm frame 1 through the sliding groove 2 in a sliding manner, at the moment, a take-up rope 15 on a take-up rotating shaft 4 in the sliding suspension arm 3 is in a pay-off state, the take-up rope 15 is placed downwards on a fixed suspension plate 16, then an object is placed upwards, the driving motor 11 on a fixed plate 7 is driven to drive a motor gear 12 to rotate, then the motor gear 12 rotates to drive a take-up gear 14 to rotate to drive a take-up shaft wheel 17 to rotate to take up the take-up rope 15, when the take-up rope 15 rotates, a take-up guide rope 8 is wound through a wire notch 13, when the take-up guide rope 8 is wound at the same time, the take-up rotating shaft 4 is driven to rotate, when the take-up rotating shaft 4 rotates, the take-up rotating shaft 4 rotates at the same time through the linkage gears 18 connected at two ends to mesh the take-up rotating shafts 4 at the same time, the wire winding rope 15 is wound up, the driving motor 11 drives the driving belt 10 to drive the rotating wheel rod 9 to rotate, when the rotating wheel rod 9 rotates, the driving guide rope 6 moves through the rotation of the wire guide wheel 5, the sliding suspension arm 3 slides towards the right side, and an object on the fixed suspension plate 16 is moved to a higher position.

The foregoing is only a preferred embodiment of the present invention; the scope of the utility model is not limited thereto. Any person skilled in the art should be able to cover the technical scope of the present invention by equivalent or modified solutions and modifications within the technical scope of the present invention.

Claims (6)

1. The utility model provides a machinery davit for machining, includes davit frame (1), its characterized in that: the wire guide device is characterized in that a sliding groove (2) is formed in the surface of the outer side of the boom support (1), a sliding boom (3) is arranged on the inner side of the sliding groove (2), a wire take-up rotating shaft (4) is arranged on the inner side of the sliding boom (3), and a wire guide wheel (5) is arranged on the upper surface of the left end of the boom support (1).

2. A mechanical boom for machining according to claim 1, characterized in that: the wire guiding device is characterized in that the sliding groove (2) penetrates through the outer side surface of the boom frame (1), a sliding structure is formed between the sliding groove (2) and the sliding boom (3), a rotating structure is formed between the sliding boom (3) and the wire collecting rotating shaft (4), the boom frame (1) is in threaded connection with the wire guiding wheel (5), the outer side surface of the wire guiding wheel (5) is connected with the transmission guide cable (6), and the transmission guide cable (6) is fixedly connected with the sliding boom (3).

3. A mechanical boom for machining according to claim 2, characterized in that: the wire winding device is characterized in that a rotating wheel rod (9) is arranged at the right side end of the transmission guide cable (6), a rotating structure is formed between the rotating wheel rod (9) and the wire guide wheel (5), a fixing plate (7) is fixed at the right side tail end of the boom frame (1), the boom frame (1) is connected with the fixing plate (7) in a welding mode, a winding guide cable (8) is arranged at the middle position of the wire winding rotating shaft (4), and the winding guide cable (8) penetrates through the bottom end of the fixing plate (7).

4. A mechanical boom for machining according to claim 3, characterized in that: the front end lateral surface of runner wheel pole (9) is provided with drive belt (10), and constitutes revolution mechanic between drive belt (10) and runner wheel pole (9), settle directly over fixed plate (7) has driving motor (11), and constitutes threaded connection between driving motor (11) and fixed plate (7), the front end of driving motor (11) is provided with motor gear (12), and is fixed connection between driving motor (11) and motor gear (12), driving motor (11) pass through and constitute revolution mechanic between drive belt (10) and runner wheel pole (9).

5. A mechanical boom for machining according to claim 4, characterized in that: a winding gear (14) is arranged right below the motor gear (12), the winding gear (14) is meshed with the motor gear (12) and is connected with the motor gear (12), a rotating structure is formed between the winding gear (14) and the fixing plate (7), a wire notch (13) is formed in the left side surface of the fixing plate (7), and the wire notch (13) penetrates through the bottom side surface of the fixing plate (7).

6. A mechanical boom for machining according to claim 5, characterized in that: receive line pivot (4) around both ends be connected with and receive line rope (15), and receive line rope (15) and receive intertwine between line pivot (4), the bottom of receiving line rope (15) is connected with fixed hanger plate (16), and is welded connection between fixed hanger plate (16) and the receipts line rope (15), the bottom of spiral gear (14) is provided with reel wheel (17), and is fixed connection between reel wheel (17) and spiral gear (14), receive line pivot (4) around both sides end-to-end connection have linkage gear (18), and receive line pivot (4) and linkage gear (18) between be fixed connection.

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