CN218598527U - Hydraulic equipment with anti-collision structure - Google Patents

Abstract

The utility model discloses a hydraulic equipment with anticollision structure, including base and spring, the surface mounting cushion block under the base, install the fan through the bolt in the notch, the ventilation hole has been seted up to the fan below, be equipped with the spring in the cushion chamber, spring one end is connected with the baffle, be connected with the connecting rod on the baffle, the connecting rod runs through the base bottom and is connected with the fagging, the flank board is interior to be equipped with the radiator-grid, and the flank board lateral surface is connected with the buffer, the bearing frame is connected with the bull stick through the bearing, install the pulley on the bull stick; this hydraulic equipment with anticollision structure is provided with spring, baffle, connecting rod and fagging and makes this buffer stop can protect the pneumatic cylinder bottom, and stability when the pneumatic cylinder used has been improved to anti-skidding line structural design's bed course simultaneously, and wheel frame, buffer and the pulley that this buffer stop set up can cushion the collision of pneumatic cylinder side in addition, take place to damage when avoiding the pneumatic cylinder to receive the collision.

Description

Hydraulic equipment with anti-collision structure

Technical Field

The utility model relates to a hydraulic equipment technical field specifically is a hydraulic equipment with anticollision structure.

Background

The hydraulic equipment with anticollision structure is a power transmission equipment that people often used, changes hydraulic energy into the hydraulic actuator of mechanical energy during the pneumatic cylinder, and it generally comprises cylinder, cylinder cap, piston rod and sealing device, and people's work efficiency can be improved greatly to the pneumatic cylinder, and some problems are found in the hydraulic equipment with anticollision structure in the use of current nevertheless:

1. when the existing hydraulic equipment is used, an effective protection device is lacked, when the hydraulic cylinder is used, if the hydraulic cylinder is impacted, the hydraulic cylinder can be damaged, and the hydraulic cylinder is troublesome to mount and dismount after being damaged, so that the hydraulic cylinder needs to be protected by the protection device, and the hydraulic cylinder is prevented from being damaged due to collision;

2. current hydraulic equipment can produce the heat in lasting use, and current hydraulic equipment radiating effect is not good, and it only utilizes hydraulic equipment's louvre to dispel the heat, when hydraulic equipment was in high temperature environment and uses, only was difficult to discharge the heat through the louvre to influence hydraulic equipment's normal use easily.

We have therefore proposed a hydraulic apparatus having a crash-proof structure in order to solve the problems set forth above.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a hydraulic equipment with anticollision structure to solve the hydraulic equipment that has now on the existing market that above-mentioned background art provided when using, lack effectual protector and the not good problem of radiating effect.

In order to achieve the above purpose, the utility model provides a following technical scheme: a hydraulic device with an anti-collision structure comprises a base and a spring, wherein a cushion block is arranged on the lower surface of the base, a supporting table is arranged in the middle of the upper surface of the base, a side wing plate is connected to the upper end of the base, a buffer cavity is formed in the base, notches are formed in one fifth of the positions, located at two ends, of the base, and a hydraulic cylinder is arranged on the supporting table;

a fan is arranged in the notch through a bolt, a vent hole is formed below the fan, and a dust screen is arranged in the vent hole;

a spring is arranged in the buffer cavity, one end of the spring is connected with a baffle plate, the baffle plate is connected with a connecting rod, the connecting rod penetrates through the bottom of the base and is connected with a supporting plate, and a cushion layer is connected to the supporting plate;

the improved side wing plate structure is characterized in that a radiating net is arranged in the side wing plate, the outer side face of the side wing plate is connected with a buffer, one end of the buffer is connected with a wheel frame, bearing seats are installed on the top face and the bottom face of the interior of the wheel frame, the bearing seats are connected with rotating rods through bearings, and pulleys are installed on the rotating rods.

Preferably, the pulleys are uniformly distributed on the rotating rod in multiple groups, extend out of one side of the wheel frame by 2cm, and are designed to be elastic rubber structures.

The pulleys are uniformly distributed on the rotating rod in multiple groups, so that the conversion of the pulleys to collision energy is improved, and the collision avoidance capability of the hydraulic equipment is improved.

Preferably, the cushion layer is rectangular, and the surface of the cushion layer adopts an anti-skid texture structure.

The cushion layer is rectangular, so that the protection effect of the cushion layer on the supporting plate is improved.

Preferably, the cushion block is of an elastic rubber structure, and the cushion blocks are uniformly distributed at the bottom of the base at equal intervals.

The cushion blocks are uniformly distributed at equal intervals at the bottom of the base, so that the damage and noise caused by the collision of the supporting plate and the base are avoided.

Preferably, the fagging adopts the design of high strength steel construction, and the fagging links to each other with the connecting rod through the welding mode simultaneously.

The fagging links to each other with the connecting rod through welding mode and has improved the stability between fagging and the connecting rod.

Preferably, the side wing plate is designed to be in an L-shaped structure, and a gap is reserved between the side wing plate and the wheel frame.

The side wing plate adopts the L-shaped structural design, so that the attractiveness of the hydraulic equipment is improved, and the anti-collision capacity of the hydraulic equipment is improved.

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

1. this hydraulic equipment with anticollision structure is provided with spring, baffle, connecting rod and fagging and makes this buffer stop can protect the pneumatic cylinder bottom, and stability when the pneumatic cylinder used has been improved to antiskid line structural design's bed course simultaneously, and wheel frame, buffer and the pulley that this buffer stop set up can cushion the collision of pneumatic cylinder side in addition, take place to damage when avoiding the pneumatic cylinder to receive the collision.

2. This fan, ventilation hole and radiator-grid that has the hydraulic equipment setting of crashproof structure make this crashproof structure can discharge the heat that produces in the pneumatic cylinder use, and the fan can blow the heat dissipation around the pneumatic cylinder, and the clearance that contains thermal wind and pass through radiator-grid and side wing board and wheel frame is dispelled, has improved this buffer stop to hydraulic equipment's radiating effect.

Drawings

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

FIG. 2 is a schematic view of a partial structure at the position A of the present invention;

FIG. 3 is a schematic view of a partial structure at the position B of the present invention;

fig. 4 is a side view schematic structure diagram of the present invention;

fig. 5 is a schematic view of the main structure of the supporting plate of the present invention.

In the figure: 1. a base; 2. a support table; 3. a supporting plate; 4. a buffer chamber; 5. a cushion layer; 6. a buffer; 7. a pulley; 8. a wheel frame; 9. a hydraulic cylinder; 10. a side wing panel; 11. a bearing seat; 12. a rotating rod; 13. a heat-dissipating web; 14. a cushion block; 15. a dust screen; 16. a vent hole; 17. a notch; 18. a fan; 19. a connecting rod; 20. a baffle plate; 21. a spring.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: a hydraulic device with an anti-collision structure comprises a base 1, a supporting platform 2, a supporting plate 3, a buffer cavity 4, a cushion layer 5, a buffer 6, a pulley 7, a wheel frame 8, a hydraulic cylinder 9, a side wing plate 10, a bearing seat 11, a rotating rod 12, a radiating net 13, a cushion block 14, a dustproof net 15, a ventilation hole 16, a notch 17, a fan 18, a connecting rod 19, a baffle plate 20 and a spring 21, wherein the cushion block 14 is installed on the lower surface of the base 1, the supporting platform 2 is installed in the middle of the upper surface of the base 1, the upper end part of the base 1 is connected with the side wing plate 10, the buffer cavity 4 is formed in the base 1, notches 17 are formed in one fifth of two end parts of the base 1, the cushion block 14 is of an elastic rubber structure, the cushion blocks 14 are uniformly distributed at the bottom of the base 1 at equal intervals, the cushion block 14 is of the elastic rubber structure, the protective capacity of the cushion block 14 is improved, and the hydraulic cylinder 9 is arranged on the supporting platform 2;

a fan 18 is arranged in the notch 17 through a bolt, a vent hole 16 is formed below the fan 18, and a dust screen 15 is arranged in the vent hole 16;

a spring 21 is arranged in the buffer cavity 4, one end of the spring 21 is connected with a baffle plate 20, the baffle plate 20 is connected with a connecting rod 19, the connecting rod 19 penetrates through the bottom of the base 1 and is connected with a supporting plate 3, a cushion layer 5 is connected onto the supporting plate 3, the supporting plate 3 is designed to be of a high-strength steel structure, meanwhile, the supporting plate 3 is connected with the connecting rod 19 in a welding mode, the supporting plate 3 is designed to be of the high-strength steel structure, the service life of the supporting plate 3 is prolonged, the cushion layer 5 is rectangular, an anti-skid grain structure is adopted on the surface of the cushion layer 5, and the stability of the hydraulic equipment during placement is improved due to the anti-skid grain structure adopted on the surface of the cushion layer 5;

seted up radiator-grid 13 in flank board 10, and flank board 10 lateral surface is connected with buffer 6, flank board 10 adopts L shape structural design, and leave the space between flank board 10 and the wheel frame 8, leave the space between flank board 10 and the wheel frame 8 and make gas discharge in can following the space, the thermal diffusivity of this hydraulic equipment has been improved, buffer 6 one end is connected with wheel frame 8, bearing frame 11 is all installed to the inside top surface of wheel frame 8 and bottom surface, bearing frame 11 is connected with bull stick 12 through the bearing, install pulley 7 on the bull stick 12, pulley 7 adopts multiunit evenly distributed on bull stick 12, and pulley 7 stretches out 2cm from wheel frame 8 one side, pulley 7 adopts the elastic rubber structural design simultaneously, pulley 7 adopts the elastic rubber structural design to make pulley 7 have elastic buffer capacity, this hydraulic equipment's crashworthiness has further been strengthened.

The working principle is as follows: when the hydraulic equipment with the anti-collision structure is used, the hydraulic cylinder 9 is firstly installed on the support table 2 to be used, when the side face of the hydraulic equipment is collided, the hydraulic equipment firstly contacts the pulley 7, the rolling of the pulley 7 can convert a part of collision energy, meanwhile, the compression of the buffer 6 can buffer the residual collision energy, and the influence of the collision on the hydraulic cylinder 9 is avoided;

when the environmental temperature that hydraulic equipment is located is higher, start fan 18, fan 18 can blow the heat dissipation to pneumatic cylinder 9, and the clearance that contains thermal wind between 13 and flank board 10 and wheel frame 8 of radiator-grid is scattered, and the design of dust screen 15 can avoid external dust to enter into inside this hydraulic equipment simultaneously.

Those not described in detail in this specification are within the skill of the art.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. A hydraulic equipment with anticollision structure, includes base (1) and spring (21), its characterized in that: the lower surface of the base (1) is provided with a cushion block (14), a supporting table (2) is arranged in the middle of the upper surface of the base (1), the upper end part of the base (1) is connected with a side wing plate (10), meanwhile, a buffer cavity (4) is formed in the base (1), in addition, notches (17) are formed in one fifth of the positions, located at the two end parts, of the base (1), and a hydraulic cylinder (9) is arranged on the supporting table (2);

a fan (18) is installed in the notch (17) through a bolt, a vent hole (16) is formed below the fan (18), and a dust screen (15) is arranged in the vent hole (16);

a spring (21) is arranged in the buffer cavity (4), one end of the spring (21) is connected with a baffle (20), the baffle (20) is connected with a connecting rod (19), the connecting rod (19) penetrates through the bottom of the base (1) and is connected with a supporting plate (3), and a cushion layer (5) is connected to the supporting plate (3);

seted up radiator-grid (13) in flank board (10), and flank board (10) lateral surface is connected with buffer (6), buffer (6) one end is connected with wheel frame (8), bearing frame (11) are all installed to wheel frame (8) inside top surface and bottom surface, bearing frame (11) are connected with bull stick (12) through the bearing, install pulley (7) on bull stick (12).

2. The hydraulic apparatus having a crash structure according to claim 1, wherein: the pulley (7) adopts multiunit evenly distributed on bull stick (12), and pulley (7) follow wheel frame (8) one side and stretch out 2cm, and pulley (7) adopt the design of elasticity rubber structure simultaneously.

3. The hydraulic apparatus having a crash structure according to claim 1, wherein: the cushion layer (5) is rectangular, and the surface of the cushion layer (5) adopts an anti-skid texture structure.

4. The hydraulic apparatus having a collision avoidance structure according to claim 1, wherein: the cushion blocks (14) are of elastic rubber structures, and the cushion blocks (14) are uniformly distributed at the bottom of the base (1) at equal intervals.

5. The hydraulic apparatus having a crash structure according to claim 1, wherein: the supporting plate (3) is designed by adopting a high-strength steel structure, and meanwhile, the supporting plate (3) is connected with the connecting rod (19) in a welding mode.

6. The hydraulic apparatus having a collision avoidance structure according to claim 1, wherein: the side wing plates (10) are designed to be L-shaped structures, and gaps are reserved between the side wing plates (10) and the wheel frame (8).

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