CN213950463U

CN213950463U - Lifting robot for preventing automobile from being soaked in water

Info

Publication number: CN213950463U
Application number: CN202022925066.5U
Authority: CN
Inventors: 李帅锋
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-12-09
Filing date: 2020-12-09
Publication date: 2021-08-13
Anticipated expiration: 2030-12-09

Abstract

The utility model discloses a prevent lifting robot that car soaks usefulness, the device comprises a device body, first cavity has all been seted up to the both sides at device body bottom both ends, and first cavity is close to the inside both ends of one side device body each other and has all seted up the second cavity. The utility model discloses a positive and negative lead screw of third motor drive rotates, it moves the piece and carries out relative movement with the second nut to move the piece to drive first nut when positive and negative lead screw is pivoted, move the piece and move the piece with the second nut and drive first hinge bar and second hinge bar and carry out the top to the roof when removing when first nut moves the piece, it moves the piece and moves with the third motor to drive first when rethread first hinge bar and first hinge bar relative movement, it goes up and down to drive the roof when first piece and the second that moves move moves the piece and move, make the drive car that the device can be better go up and down when using, prevent that the car from being soaked by the water.

Description

Lifting robot for preventing automobile from being soaked in water

Technical Field

The utility model relates to an automotive robot technical field, concretely relates to prevent lifting robot that car soaks usefulness.

Background

With the development of society, the continuous progress of science and technology, the problem that the car is soaked in the ponding that appears raining easily when the car owner parks appears, just causes the loss to the life of vehicle easily when the vehicle receives to soak.

When the existing vehicle is parked, if rainwater weather occurs, the phenomenon that the surrounding accumulated water is too deep easily occurs, the phenomenon that the engine of the automobile is flooded occurs when the accumulated water is too deep, and the service life of the automobile is damaged once the engine enters water.

Therefore, it is necessary to provide a lifting robot for preventing the car from being immersed in water to solve the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a prevent that car soaks lifting robot of usefulness, rotate through the positive and negative lead screw of third motor drive, it moves the piece and be close to each other with the second nut to drive first nut when positive and negative lead screw is in the pivoted, move the piece and drive first hinge bar and second hinge bar and carry out the top with the roof when being close to each other with the second nut when first nut moves, it goes up and down to drive the car when the roof receives the top and move, it intakes when preventing to appear parking, with the above-mentioned weak point in the solution technique.

In order to achieve the above object, the present invention provides the following technical solutions: a lifting robot for preventing an automobile from being soaked in water comprises a device body, wherein first cavities are formed in two sides of two ends of the bottom end of the device body, second cavities are formed in two ends, close to one side of the device body, of the first cavities, a first motor is installed at one end, far away from the central axis of the device body, of the inner portion of each second cavity, a first gear shaft is installed at the output end of the first motor, a first roller penetrating into the inner portion of each first cavity is installed at one side, far away from the first motor, of the inner portion of each second cavity through a bearing, a second gear shaft meshed with the first gear shaft is installed at one end, close to the central axis of the device body, of the inner portion of each second cavity, a third gear shaft is installed at the output end of the second motor, a second roller penetrating into the inner portion of each first cavity is installed at one side, far away from the first roller, of each second cavity through a bearing, and a fourth gear shaft meshed with the third gear shaft is arranged at one end of the second roller wheel close to the first roller wheel, third cavities are arranged at two sides of one end inside the device body, fixed blocks are arranged at the middle positions of two ends of the bottom inside the device body, a third motor is arranged at one end of the inner part of the third cavity close to the central axis of the device body, a positive lead screw penetrating through the fixed blocks and connected with the inner wall of the device body is arranged at the output end of the third motor through a bearing, a first nut moving block is arranged at one end of the outer side of the positive lead screw and the outer side of the negative lead screw close to the third motor, a second nut moving block is arranged at one end of the outer side of the positive lead screw and the outer side of the negative lead screw far from the third motor, first hinge rods are hinged at the top ends of two sides of the second nut moving block, a second hinge rod hinged with the first hinge rods is hinged at the top end of the first nut moving block, and a top plate penetrating to the top end of the device body is arranged at the top end inside the device body, and the spout has all been seted up at roof bottom both ends, the inside guide bar that all transversely installs of spout, and the guide bar outside is close to third motor one end and all is provided with and moves the piece with first hinge bar looks articulated first, the guide bar outside is kept away from third motor one end and all is provided with and moves the piece with second hinge bar looks articulated second, the through-hole has evenly been seted up to the inside bottom of device body.

Preferably, the two ends of the fixed block are respectively and transversely provided with two guide rods which penetrate through the first nut moving block and the second nut moving block, the guide rods are connected with the first nut moving block and the second nut moving block in a sliding mode, and the number of the guide rods arranged at the two ends of the fixed block is two.

Preferably, the two sides of the second nut moving block are hinged with first hinged rods, and the first hinged rods are mutually hinged with the second hinged rods at positions close to the middle position of one side.

Preferably, the second nut moving blocks and the first nut moving blocks are symmetrical to each other through the fixing blocks, and the number of the first nut moving blocks and the number of the second nut moving blocks are two.

Preferably, the first moving block and the second moving block are respectively connected with the guide rod in a sliding manner, and the first moving block and the second moving block perform sliding guide in the sliding groove.

Preferably, the first hinge rod and the second hinge rod are arranged in a cross shape inside the device body.

Preferably, the first motor is connected with the first gear shaft through a coupler, the first gear shaft is meshed with the second gear shaft, the second motor is connected with the third gear shaft through a coupler, the third gear shaft is meshed with the fourth gear shaft, and the first motor, the first gear shaft and the third motor are all set to be stepping motors.

In the technical scheme, the utility model provides a technological effect and advantage:

1. the positive and negative screw rod is driven to rotate by the third motor, the first nut moving block and the second nut moving block are driven to move relatively when the positive and negative screw rod rotates, the first hinge rod and the second hinge rod are driven to jack the top plate when the first nut moving block and the second nut moving block move, the first moving block and the third motor are driven to move when the first hinge rod and the first hinge rod move relatively, and the top plate is driven to lift when the first moving block and the second moving block move, so that the device can better drive the automobile to lift when in use, and the automobile is prevented from being soaked by water;

2. the first gear shaft is driven by the first motor to drive the second gear shaft to rotate, the first idler wheel is driven to rotate when the second gear shaft rotates, the third gear shaft is driven by the second motor to drive the fourth gear shaft to rotate, and the second idler wheel is driven to rotate when the fourth gear shaft rotates, so that the device can be driven to move when used, and the device can be moved more conveniently when used.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to these drawings.

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

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

fig. 3 is a schematic front view of the present invention;

fig. 4 is a schematic top sectional view of the present invention.

Description of reference numerals:

1. a device body; 2. a first cavity; 3. a second cavity; 4. a first motor; 5. a first gear shaft; 6. a first roller; 7. a second gear shaft; 8. a second motor; 9. a third gear shaft; 10. a second roller; 11. a fourth gear shaft; 12. a third cavity; 13. a fixed block; 14. a third motor; 15. a positive and negative screw rod; 16. a first nut moving block; 17. a second nut moving block; 18. a first hinge lever; 19. a second hinge lever; 20. a top plate; 21. a chute; 22. a guide bar; 23. a first moving block; 24. a second moving block; 25. and a through hole.

Detailed Description

In order to make the technical solution of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings.

The utility model provides a lifting robot for preventing the automobile from being soaked in water, which comprises a device body 1, wherein both sides of both ends of the bottom end of the device body 1 are provided with first cavities 2, and both ends of the first cavities 2 close to one side of the device body 1 are provided with second cavities 3, one end of the second cavity 3 far away from one side of the central axis of the device body 1 is provided with a first motor 4, the output end of the first motor 4 is provided with a first gear shaft 5, one side of the second cavity 3 far away from the first motor 4 is provided with a first roller 6 penetrating into the first cavity 2 through a bearing, one end of the first roller 6 close to the first motor 4 is provided with a second gear shaft 7 meshed with the first gear shaft 5, one end of the second cavity 3 close to one side of the central axis of the device body 1 is provided with a second motor 8, and the output end of the second motor 8 is provided with a third gear shaft 9, one side of the interior of the second cavity 3 far away from the first roller 6 is provided with a second roller 10 penetrating into the interior of the first cavity 2 through a bearing, one end of the second roller 10 near the first roller 6 is provided with a fourth gear shaft 11 meshed with the third gear shaft 9, two sides of one end of the interior of the device body 1 are provided with third cavities 12, middle positions of two ends of the bottom end of the interior of the device body 1 are provided with fixed blocks 13, one end of the interior of the third cavity 12 near the central axis of the device body 1 is provided with a third motor 14, the output end of the third motor 14 is provided with a positive and negative screw rod 15 penetrating through the fixed blocks 13 and connected with the inner wall of the device body 1 through a bearing, one end of the outer side of the positive and negative screw rod 15 near the third motor 14 is provided with a first nut moving block 16, one end of the outer side of the positive and negative screw rod 15 far away from the third motor 14 is provided with a second nut moving block 17, and second nut moves that 17 both sides tops all articulate there is first articulated rod 18, first nut moves 16 tops and all articulates there is second articulated rod 19 articulated mutually with first articulated rod 18, the inside top of device body 1 is provided with the roof 20 that runs through to 1 top of device body, and roof 20 bottom both ends have all seted up spout 21, spout 21 is inside all transversely to be installed guide bar 22, and the guide bar 22 outside is close to third motor 14 one end and all is provided with and first articulated rod 18 articulated mutually first move piece 23, third motor 14 one end is all provided with and second articulated rod 19 articulated second move piece 24 in the guide bar 22 outside keeping away from, through-hole 25 has evenly been seted up to the inside bottom of device body 1.

Further, in the above technical solution, two ends of the fixed block 13 are respectively and transversely provided with a guide rod penetrating through the first nut moving block 16 and the second nut moving block 17, the guide rods are slidably connected with the first nut moving block 16 and the second nut moving block 17, and the number of the guide rods arranged at the two ends of the fixed block 13 is two.

Further, in the above technical solution, both sides of the second nut moving block 17 are hinged with a first hinge rod 18, and the first hinge rod 18 is hinged with a second hinge rod 19 at a position close to the middle of one side of the first hinge rod 18.

Further, in the above technical solution, the second nut moving blocks 17 and the first nut moving blocks 16 are symmetrical to each other through the fixing block 13, and the number of the first nut moving blocks 16 and the second nut moving blocks 17 is two.

Further, in the above technical solution, the first moving block 23 and the second moving block 24 are respectively connected with the guide rod 22 in a sliding manner, and the first moving block 23 and the second moving block 24 perform sliding guide in the sliding chute 21.

Further, in the above technical solution, the first hinge rod 18 and the second hinge rod 19 are arranged in a cross shape inside the device body 1.

Further, in the above technical solution, the first motor 4 is connected to the first gear shaft 5 through a coupler, the first gear shaft 5 is engaged with the second gear shaft 7, the second motor 8 is connected to the third gear shaft 9 through a coupler, the third gear shaft 9 is engaged with the fourth gear shaft 11, and the first motor 4, the first gear shaft 5, and the third motor 14 are all configured as step motors.

This practical theory of operation:

referring to the attached drawings 1-4 of the specification, a first motor 4 drives a first gear shaft 5 to rotate, when the first gear shaft 5 rotates, a second gear shaft 7 is driven to rotate, then the second gear shaft 7 drives a first roller 6 to rotate, meanwhile, a second motor 8 drives a third gear shaft 9 to rotate, when the third gear shaft 9 rotates, a fourth gear shaft 11 is driven to rotate, and simultaneously, the fourth gear shaft 11 drives a second roller 10 to rotate, so that the device can be driven to move when in use;

referring to the attached fig. 1-4 of the specification, the forward and reverse screw rod 15 is driven to rotate by the third motor 14 inside the third cavity 12, when the forward and reverse screw rod 15 rotates, the first nut moving block 16 and the second nut moving block 17 are driven to move relatively, and then the first nut moving block 16 and the second nut moving block 17 drive the first hinge rod 18 and the second hinge rod 19 to move when moving mutually, when the first hinge rod 18 and the second hinge rod 19 move mutually, the first moving block 23 and the second moving block 24 are driven to move outside the guide rod 22 in the sliding groove 21, when the first moving block 23 and the second moving block 24 move relative to each other, the top plate 20 is pushed, when the first moving block 23 and the second moving block 24 move, the top plate 20 is driven to lift, the device can better drive the automobile to lift when in use so as to prevent the automobile from being soaked by water.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the present invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims

1. The utility model provides a prevent that car soaks lifting robot of usefulness, includes device body (1), its characterized in that: the device is characterized in that first cavities (2) are respectively arranged on two sides of two ends of the bottom end of the device body (1), second cavities (3) are respectively arranged on two ends of the first cavities (2) close to one side of the interior of the device body (1), a first motor (4) is arranged at one end of the interior of each second cavity (3) far away from one side of the central axis of the device body (1), a first gear shaft (5) is arranged at the output end of each first motor (4), a first roller (6) penetrating into the interior of each first cavity (2) is arranged at one side of the interior of each second cavity (3) far away from the corresponding first motor (4) through a bearing, a second gear shaft (7) meshed with the first gear shaft (5) is arranged at one end of the first motor (4) close to the corresponding first roller (6), and a second motor (8) is arranged at one end of the interior of each second cavity (3) close to one side of the central axis of the device body (1), and the output end of the second motor (8) is provided with a third gear shaft (9), one side of the second cavity (3) far away from the first idler wheel (6) is provided with a second idler wheel (10) penetrating into the first cavity (2) through a bearing, one end of the second idler wheel (10) close to the first idler wheel (6) is provided with a fourth gear shaft (11) meshed with the third gear shaft (9), the two sides of one end inside the device body (1) are provided with third cavities (12), the middle positions of the two ends at the bottom inside the device body (1) are provided with fixed blocks (13), one end of the inside of the third cavity (12) close to the central axis of the device body (1) is provided with a third motor (14), and the output end of the third motor (14) is provided with a positive and negative screw rod (15) penetrating through the fixed blocks (13) and connected with the inner wall of the device body (1) through a bearing, one end of the outer side of the positive and negative screw rod (15) close to the third motor (14) is provided with a first nut moving block (16), one end of the outer side of the positive and negative screw rod (15) far away from the third motor (14) is provided with a second nut moving block (17), the top ends of the two sides of the second nut moving block (17) are hinged with first hinge rods (18), the top end of the first nut moving block (16) is hinged with second hinge rods (19) hinged with the first hinge rods (18), the top end of the inner part of the device body (1) is provided with a top plate (20) penetrating through the top end of the device body (1), the two ends of the bottom end of the top plate (20) are provided with sliding grooves (21), guide rods (22) are transversely arranged in the sliding grooves (21), and one end of the outer side of the guide rods (22) close to the third motor (14) is provided with a first moving block (23) hinged with the first hinge rods (18), one end of the outer side of the guide rod (22) far away from the third motor (14) is provided with a second moving block (24) hinged with a second hinged rod (19), and the bottom end inside the device body (1) is uniformly provided with through holes (25).

2. The lift robot for preventing the automobile from being soaked in water according to claim 1, wherein: the two ends of the fixed block (13) are respectively and transversely provided with guide rods which penetrate through the first nut moving block (16) and the second nut moving block (17), the guide rods are connected with the first nut moving block (16) and the second nut moving block (17) in a sliding mode, and the number of the guide rods arranged at the two ends of the fixed block (13) is two.

3. The lift robot for preventing the automobile from being soaked in water according to claim 1, wherein: the two sides of the second nut moving block (17) are hinged with first hinged rods (18), and the middle positions of the first hinged rods (18) close to one side are hinged with second hinged rods (19).

4. The lift robot for preventing the automobile from being soaked in water according to claim 1, wherein: the second nut moving blocks (17) and the first nut moving blocks (16) are mutually symmetrical through the fixing blocks (13), and the number of the first nut moving blocks (16) and the number of the second nut moving blocks (17) are two.

5. The lift robot for preventing the automobile from being soaked in water according to claim 1, wherein: the first moving block (23) and the second moving block (24) are respectively connected with the guide rod (22) in a sliding mode, and the first moving block (23) and the second moving block (24) conduct sliding guide in the sliding groove (21).

6. The lift robot for preventing the automobile from being soaked in water according to claim 1, wherein: the first hinge rod (18) and the second hinge rod (19) are arranged in a cross manner in the device body (1).

7. The lift robot for preventing the automobile from being soaked in water according to claim 1, wherein: the first motor (4) is connected with the first gear shaft (5) through a coupler, the first gear shaft (5) is meshed with the second gear shaft (7), the second motor (8) is connected with the third gear shaft (9) through a coupler, the third gear shaft (9) is meshed with the fourth gear shaft (11), and the first motor (4), the first gear shaft (5) and the third motor (14) are all set to be stepping motors.