CN112648264B

CN112648264B - Independent oil radiator motor support for engineering machinery

Info

Publication number: CN112648264B
Application number: CN202011524776.5A
Authority: CN
Inventors: 张斌
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-12-22
Filing date: 2020-12-22
Publication date: 2023-12-29
Anticipated expiration: 2040-12-22
Also published as: CN112648264A

Abstract

The utility model discloses an independent oil radiator motor bracket for engineering machinery, which comprises a bracket body; the frame body is welded with a mounting seat structure, and the mounting seat structure is fixedly connected with a driving structure; two heat dissipation structures are installed on the installation seat structure, and a spraying structure is also installed on the installation seat structure. Because the poking rod is arranged on the rotating shaft of the servo motor and is contacted with the stress plate, the mounting arm, the stress plate and the sliding plate are in a reciprocating motion state when the poking rod rotates, so that the continuous cutting off of the air flow sprayed out of the box body is realized, and finally, the intermittent wind power heat dissipation of the radiator is realized; because the baffle is welded on the mounting arm, and the baffle is aligned with the servo motor, the baffle can realize continuous cutting of wind power blown to the servo motor when the mounting arm reciprocates, and then intermittent wind power heat dissipation of the servo motor is realized.

Description

Independent oil radiator motor support for engineering machinery

Technical Field

The utility model relates to the technical field of mechanical equipment, in particular to an independent oil radiator motor bracket for engineering machinery.

Background

Description of the prior art: the main function of the independent oil radiator motor bracket for engineering machinery is to fix a hydraulic motor for a radiator, wherein the hydraulic motor is generally arranged on a flange plate of the bracket, and a cooling fan is arranged on the hydraulic motor.

The application number is as follows: the utility model discloses a motor bracket of an independent oil radiator for engineering machinery, which belongs to the technical field of engineering machinery. The motor bracket solves the defects that in the prior art, the number of the bottom plates in the motor bracket of the independent oil radiator for engineering machinery is too large and the connection strength between the bracket steel pipes and the bottom plates is insufficient. The flange plate is fixedly installed between the support steel pipes. The utility model is used for supporting the independent oil radiator motor for engineering machinery.

The existing problems are as follows: the existing device is poor in stability when a bracket is fixed, and elastic anti-loosening of a fixing bolt and multidirectional anti-skid of a fixing seat cannot be realized through structural improvement; furthermore, the support of the existing device does not have heat dissipation capability, intermittent air supply can not be realized when the fan rotates to dissipate heat through structural improvement, and spray cooling can be realized through linkage.

Disclosure of Invention

The utility model aims to provide a pushing device for machining and producing an independent oil radiator motor bracket for engineering machinery, which aims to solve the problems in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: a pushing device for machining and producing an independent oil radiator motor bracket for engineering machinery comprises a bracket body; the frame body is welded with a mounting seat structure, and the mounting seat structure is fixedly connected with a driving structure; two heat dissipation structures are arranged on the mounting seat structure, and a spraying structure is also arranged on the mounting seat structure; the heat dissipation structure comprises a mounting arm and a stress plate, wherein the mounting arm is welded on the sliding plate, and the stress plate is welded on the mounting arm; the driving structure further comprises a poking rod, the poking rod is arranged on a rotating shaft of the servo motor, and the poking rod is in contact with the stress plate; the heat radiation structure also comprises a baffle plate, wherein the baffle plate is welded on the mounting arm, and the baffle plate is aligned with the servo motor.

Preferably, the frame body comprises a rectangular plate A and a supporting plate, the frame body consists of two concave bent rods, and the frame body is welded with the two rectangular plates A; two backup pads have all been welded to the terminal surface behind every rectangular plate A, and backup pad and rectangular plate A have constituteed the elasticity locking structure of fastening bolt on the rectangular plate A jointly.

Preferably, the frame body further comprises protrusions, two protrusions are symmetrically welded on the rear end face of each supporting plate, and the protrusions are of a wavy structure.

Preferably, the mounting seat structure comprises a rectangular plate B and a flange, wherein the rectangular plate B is welded on the frame body, and the flange is welded on the rectangular plate B; the driving structure comprises a servo motor and blades, wherein the servo motor is fixedly connected to the flange through bolts, and the blades are arranged on the servo motor.

Preferably, the heat dissipation structure comprises a box body, a rectangular hole A, a rectangular block, a sliding rod, a sliding plate and a rectangular hole B, wherein the box body is welded on the rectangular plate B, and three rectangular holes A are formed in the box body in a rectangular array shape; two rectangular blocks are welded on the box body, and a sliding rod is welded on each rectangular block; the two sliding rods are connected with a sliding plate in a sliding manner, three rectangular holes B are formed in the sliding plate in a rectangular array shape, and the sizes of the rectangular holes B and the rectangular holes A are equal.

Preferably, the heat dissipation structure further comprises two elastic pieces, and the two elastic pieces are sleeved on the two sliding rods respectively; the two elastic pieces form an elastic reset structure of the sliding plate together, and the rectangular hole B is aligned with the rectangular hole A when the sliding plate is at the initial position.

Preferably, the spraying structure comprises a telescopic bottle, a water inlet pipe, a spray pipe and a spray hole, wherein the telescopic bottle is fixedly connected to the box body, and the water inlet pipe and the spray pipe are connected to the telescopic bottle; the spray pipe is of a cylindrical tubular structure, the outer wall of the spray pipe is provided with spray holes in an annular array shape, and the spray holes in the annular array shape form a diffusion spray type structure together.

Preferably, the heat radiation structure further comprises a stirring plate, the stirring plate is welded on the baffle, the stirring plate is in contact with the head end of the telescopic bottle, and the telescopic bottle is in a continuous extrusion state when the stirring plate moves back and forth along with the baffle.

Compared with the prior art, the utility model has the beneficial effects that:

1. through the arrangement of the driving structure and the heat dissipation structure, firstly, as the two sliding rods are connected with one sliding plate in a sliding way, three rectangular holes B are formed in the sliding plate in a rectangular array shape, and the sizes of the rectangular holes B and the rectangular holes A are equal, when the rectangular holes B and the rectangular holes A are aligned, gas in the box body is in a discharge state; secondly, because the two elastic pieces jointly form an elastic reset structure of the sliding plate, and the rectangular hole B is aligned with the rectangular hole A when the sliding plate is at the initial position, the continuous cutting off of the air flow sprayed out of the box body can be realized when the sliding plate reciprocates; thirdly, as the poking rod is arranged on the rotating shaft of the servo motor and is contacted with the stress plate, when the poking rod rotates, the mounting arm, the stress plate and the sliding plate are in a reciprocating motion state, so that the continuous cutting off of the air flow sprayed out of the box body is realized, and finally, the intermittent wind power heat dissipation of the radiator is realized; fourth, because the baffle welds on the installation arm, and the baffle aligns with servo motor to the baffle can realize blowing to the continuous shutoff of servo motor department wind-force when installation arm reciprocating motion, and then just also realized servo motor's intermittent type wind-force heat dissipation.

2. Through the arrangement of the heat radiation structure and the spraying structure, firstly, as the stirring plate is welded on the baffle plate and is contacted with the head end of the telescopic bottle, and the telescopic bottle is in a continuous extrusion state when the stirring plate moves back and forth along with the baffle plate, the spraying of the spray pipe is realized; secondly, because the spray pipe is cylindrical tubular structure, and the spray pipe outer wall is annular array form and has seted up the orifice to the orifice that annular array form was seted up constitutes diffusion spray formula structure jointly, thereby accessible orifice department carries out diffusion water spray cooling when the telescopic bottle is extruded.

Drawings

Fig. 1 is an isometric view of the present utility model.

Fig. 2 is an enlarged schematic view of the structure of fig. 1 at a.

Fig. 3 is a schematic top view of the present utility model.

Fig. 4 is a schematic rear view of the present utility model.

Fig. 5 is a schematic view of an enlarged axial view structure of the present utility model with the frame removed.

Fig. 6 is an enlarged schematic view of the structure of fig. 5B according to the present utility model.

Fig. 7 is an enlarged schematic view of the structure of fig. 5 at C according to the present utility model.

Fig. 8 is a schematic top view of fig. 5 according to the present utility model.

In the figure: 1-a frame body; 101-rectangular plate a; 102-supporting a plate; 103-bump; 2-a mounting base structure; 201-rectangular plate B; 202-a flange; 3-driving structure; 301-a servo motor; 302-leaf; 303-a toggle lever; 4-a heat dissipation structure; 401-a box body; 402-rectangular hole a; 403-rectangular blocks; 404-sliding bar; 405-sliding plate; 406-rectangular hole B; 407-an elastic member; 408-mounting arms; 409-force plate; 410-a baffle; 411-toggle plate; 5-spraying structure; 501-a telescopic bottle; 502-a water inlet pipe; 503-spraying pipe; 504-orifice.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-8, the present utility model provides a technical scheme of a stand-alone oil radiator motor bracket for engineering machinery, which comprises: a thrust unit for machining and producing a motor bracket of an independent oil radiator for engineering machinery comprises a bracket body 1; the frame body 1 is welded with a mounting seat structure 2, and the mounting seat structure 2 is fixedly connected with a driving structure 3; two heat dissipation structures 4 are arranged on the mounting seat structure 2, and a spraying structure 5 is also arranged on the mounting seat structure 2; referring to fig. 5, the heat dissipation structure 4 includes a mounting arm 408 and a force receiving plate 409, the mounting arm 408 is welded to the sliding plate 405, and the force receiving plate 409 is welded to the mounting arm 408; the driving structure 3 further comprises a poking rod 303, the poking rod 303 is arranged on the rotating shaft of the servo motor 301, and the poking rod 303 is in contact with the stress plate 409, so that when the poking rod 303 rotates, the mounting arm 408, the stress plate 409 and the sliding plate 405 are in a reciprocating motion state, further continuous cutting off of air flow sprayed out of the box 401 is realized, and finally intermittent wind power heat dissipation of the radiator is realized; referring to fig. 5, the heat dissipation structure 4 further includes a baffle 410, where the baffle 410 is welded to the mounting arm 408, and the baffle 410 is aligned with the servo motor 301, so that when the mounting arm 408 reciprocates, the baffle 410 can continuously cut off wind force blowing to the servo motor 301, and intermittent wind force heat dissipation of the servo motor 301 is further realized.

Referring to fig. 1, a frame 1 includes a rectangular plate a101 and a support plate 102, the frame 1 is composed of two concave bent rods, and two rectangular plates a101 are welded on the frame 1; two backup pads 102 have all been welded to the terminal surface behind every rectangular plate A101, and backup pad 102 and rectangular plate A101 have constituteed the elasticity locking structure of fastening bolt on the rectangular plate A101 jointly to can reduce the loose probability of fixing bolt on the rectangular plate A101.

Referring to fig. 2, the frame body 1 further includes protrusions 103, two protrusions 103 are symmetrically welded to the rear end surface of each support plate 102, and the protrusions 103 are of a wave-shaped structure, so that the anti-slip capability of the support plates 102 in multiple directions is improved.

Referring to fig. 8, the mount structure 2 includes a rectangular plate B201 and a flange 202, the rectangular plate B201 is welded on the frame body 1, and the flange 202 is welded on the rectangular plate B201; the driving structure 3 comprises a servo motor 301 and blades 302, the servo motor 301 is fixedly connected to the flange 202 through bolts, and the blades 302 are mounted on the servo motor 301, so that wind power heat dissipation can be achieved when the blades 302 rotate.

Referring to fig. 5, the heat dissipation structure 4 includes a box 401, a rectangular hole a402, a rectangular block 403, a sliding rod 404, a sliding plate 405 and a rectangular hole B406, wherein the box 401 is welded on the rectangular plate B201, and three rectangular holes a402 are formed in a rectangular array on the box 401; two rectangular blocks 403 are welded on the box body 401, and a sliding rod 404 is welded on each rectangular block 403; the two sliding rods 404 are connected with a sliding plate 405 in a sliding way, three rectangular holes B406 are formed in the sliding plate 405 in a rectangular array shape, and the sizes of the rectangular holes B406 and the rectangular holes A402 are equal, so that when the rectangular holes B406 and the rectangular holes A402 are aligned, the gas in the box body 401 is in a discharge state.

Referring to fig. 5, the heat dissipation structure 4 further includes two elastic members 407, where the two elastic members 407 are sleeved on the two sliding rods 404 respectively; the two elastic members 407 together form an elastic return structure of the sliding plate 405, and the rectangular hole B406 is aligned with the rectangular hole a402 when the sliding plate 405 is in the initial position, so that continuous cutting of the airflow ejected from the box 401 can be achieved when the sliding plate 405 reciprocates.

Referring to fig. 5 and 7, the spraying structure 5 includes a telescopic bottle 501, a water inlet pipe 502, a spray pipe 503 and a spray hole 504, the telescopic bottle 501 is fixedly connected to the box 401, and the water inlet pipe 502 and the spray pipe 503 are connected to the telescopic bottle 501; the spray pipe 503 is of a cylindrical tubular structure, the outer wall of the spray pipe 503 is provided with spray holes 504 in an annular array shape, and the spray holes 504 in the annular array shape form a diffusion spray type structure together, so that when the telescopic bottle 501 is extruded, diffusion water spray cooling can be carried out through the spray holes 504.

Referring to fig. 5, the heat dissipation structure 4 further includes a toggle plate 411, the toggle plate 411 is welded on the baffle 410, and the toggle plate 411 contacts with the head end of the telescopic bottle 501, and when the toggle plate 411 moves reciprocally along with the baffle 410, the telescopic bottle 501 is in a continuous extrusion state, so that spraying of the spray pipe 503 is realized.

Working principle: when the servo motor 301 rotates, wind power generated by the blades 302 firstly contacts with the heat dissipation main body and then rebounds, the rebounded gas can enter the box body 401, and at the same time, the continuously poking of the poking rod 303 to the stress plate 409 can realize the reciprocating sliding of the sliding plate 405, so that intermittent ejection of air flow in the box body 401 is realized, and further, the continuously ejected air flow contacts with the radiator to realize continuous heat dissipation of the radiator, and meanwhile, because the baffle 410 is aligned with the servo motor 301, when the mounting arm 408 reciprocates, the baffle 410 can realize continuous cutting of wind power blown to the servo motor 301, and further, intermittent wind power heat dissipation of the servo motor 301 is realized, and finally, the impact property and heat dissipation range of the wind power are improved; meanwhile, as the stirring plate 411 is in contact with the head end of the telescopic bottle 501, the water inlet pipe 502 and the spray pipe 503 are both internally provided with one-way valves, and the water inlet pipe 502 is connected with the radiating water tank, when the stirring plate 411 moves back and forth along with the baffle 410, the telescopic bottle 501 is in a continuous extrusion state, so that the spray of the spray pipe 503 is realized;

when fixed, at first backup pad 102 and rectangular plate A101 have formed the elasticity locking structure of fastening bolt on the rectangular plate A101 jointly, and rectangular plate A101 is crooked form when the bolt is screwed up to can reduce the not hard up probability of fixing bolt on the rectangular plate A101, and the equal symmetrical welding of terminal surface has two protruding 103 behind every backup pad 102, and protruding 103 is wave-like structure, thereby improves the skid resistance in backup pad 102 multiparty direction.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides an independent oil radiator motor support for engineering machine tool, includes support body (1), its characterized in that: the mounting seat structure (2) is welded on the frame body (1), and the driving structure (3) is fixedly connected to the mounting seat structure (2); two heat dissipation structures (4) are arranged on the mounting seat structure (2), and a spraying structure (5) is also arranged on the mounting seat structure (2); the heat dissipation structure (4) comprises a box body (401), a rectangular hole A (402), a rectangular block (403), a sliding rod (404), a sliding plate (405), a rectangular hole B (406), a mounting arm (408) and a stress plate (409);

the box body (401) is welded on the rectangular plate B (201), and three rectangular holes A (402) are formed in the box body (401) in a rectangular array shape; two rectangular blocks (403) are welded on the box body (401), and a sliding rod (404) is welded on each rectangular block (403); the two sliding rods (404) are connected with a sliding plate (405) in a sliding way, three rectangular holes B (406) are formed in the sliding plate (405) in a rectangular array shape, and the sizes of the rectangular holes B (406) and the rectangular holes A (402) are equal;

the mounting arm (408) is welded on the sliding plate (405), and a stress plate (409) is welded on the mounting arm (408);

the mounting seat structure (2) comprises a rectangular plate B (201) and a flange (202), wherein the rectangular plate B (201) is welded on the frame body (1), and the flange (202) is welded on the rectangular plate B (201); the driving structure (3) comprises a servo motor (301) and blades (302), the servo motor (301) is fixedly connected to the flange (202) through bolts, and the blades (302) are arranged on the servo motor (301);

the driving structure (3) further comprises a poking rod (303), the poking rod (303) is arranged on the rotating shaft of the servo motor (301), and the poking rod (303) is in contact with the stress plate (409); the heat dissipation structure (4) further comprises a baffle (410), the baffle (410) is welded on the mounting arm (408), and the baffle (410) is aligned with the servo motor (301);

the heat dissipation structure (4) further comprises two elastic pieces (407), wherein the two elastic pieces (407) are sleeved on the two sliding rods (404) respectively; the two elastic members (407) together form an elastic return structure of the sliding plate (405), and the rectangular hole B (406) is aligned with the rectangular hole A (402) when the sliding plate (405) is at the initial position.

2. The independent oil radiator motor support for construction machinery according to claim 1, wherein: the frame body (1) comprises a rectangular plate A (101) and a supporting plate (102), the frame body (1) is composed of two concave bent rods, and the frame body (1) is welded with the two rectangular plates A (101); two supporting plates (102) are welded on the rear end face of each rectangular plate A (101), and the supporting plates (102) and the rectangular plates A (101) form an elastic anti-loosening structure of fastening bolts on the rectangular plates A (101).

3. The independent oil radiator motor support for construction machinery according to claim 2, wherein: the frame body (1) further comprises protrusions (103), two protrusions (103) are symmetrically welded on the rear end face of each supporting plate (102), and the protrusions (103) are of a wavy structure.

4. The independent oil radiator motor support for construction machinery according to claim 1, wherein: the spraying structure (5) comprises a telescopic bottle (501), a water inlet pipe (502), a spray pipe (503) and a spray hole (504), wherein the telescopic bottle (501) is fixedly connected to the box body (401), and the water inlet pipe (502) and the spray pipe (503) are connected to the telescopic bottle (501); the spray pipe (503) is of a cylindrical tubular structure, the outer wall of the spray pipe (503) is provided with spray holes (504) in an annular array shape, and the spray holes (504) in the annular array shape form a diffusion spray type structure together.

5. The independent oil radiator motor support for construction machinery according to claim 4, wherein: the heat radiation structure (4) further comprises a stirring plate (411), the stirring plate (411) is welded on the baffle plate (410), the stirring plate (411) is in contact with the head end of the telescopic bottle (501), and the telescopic bottle (501) is in a continuous extrusion state when the stirring plate (411) moves along with the baffle plate (410) in a reciprocating mode.