CN213085313U

CN213085313U - Hoist engine for geological exploration engineering field

Info

Publication number: CN213085313U
Application number: CN202021036399.6U
Authority: CN
Inventors: 李勇
Original assignee: Individual
Current assignee: Liu Jie
Priority date: 2020-06-08
Filing date: 2020-06-08
Publication date: 2021-04-30
Anticipated expiration: 2030-06-08

Abstract

The utility model provides a geological exploration is hoist engine for engineering field. The winch for the geological exploration engineering field comprises a bottom plate, a winch body, a fastening installation structure, a dust blocking installation structure and a moving structure, wherein the dust blocking installation structure is connected to the top of the bottom plate and comprises a mesh enclosure, a Y-shaped elastic clamping rod, a clamping block and an I-shaped through hole, the I-shaped through hole formed by four rectangles is formed in the bottom plate, the Y-shaped elastic clamping rod formed by four rectangles is connected to the side wall of the bottom of the mesh enclosure arranged in a reverse buckling mode, the Y-shaped elastic clamping rod is inserted into the I-shaped through hole, and the clamping block is fixedly connected to the outer side walls of two ends of the Y-shaped elastic clamping rod. The utility model provides a geological exploration is hoist engine for engineering field has and reduces hoist engine body working process and receives external dust and pile up the influence possibility, and the dust is piled up inside the hoist engine body takes the motor certainly, can influence its operating speed, guarantees the long-time life's of hoist engine body advantage.

Description

Hoist engine for geological exploration engineering field

Technical Field

The utility model relates to a hoist engine technical field especially relates to a geological exploration is hoist engine for engineering field.

Background

A winch, a light and small hoisting device for hoisting or pulling heavy objects by winding a steel wire rope or a chain on a winding drum, which is also called a winch. The hoist can drag the heavy object vertically, horizontally or obliquely. The winding machine is divided into a manual winding machine, an electric winding machine and a hydraulic winding machine. Mainly an electric winch. Can be used independently, can also be used as a component part in machinery such as hoisting, road building, mine hoisting and the like, and is widely applied due to simple operation, large rope winding amount and convenient displacement. The lifting device is mainly applied to material lifting or flat dragging of buildings, hydraulic engineering, forestry, mines, wharfs and the like.

The hoist engine is needed to be used in the geological exploration area to salvage the broken stones, and because the dust in the geological exploration area is large, the hoist engine forms dust accumulation in the long-time working process, the performance of an internal motor is used for a long time, and the service life is influenced.

Therefore, there is a need to provide a new winch for geological exploration engineering to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a reduce hoist engine body working process and receive external dust and pile up influence possibility, the dust is piled up inside the hoist engine body takes the motor certainly, can influence its operating speed, guarantees the long-time life's of hoist engine body hoist engine for the geological exploration engineering field.

The utility model provides a hoist engine for geological exploration engineering field includes: the top of the bottom plate is close to the central position and is provided with a winch body, the bottom of the bottom plate is provided with a through hole, and a steel wire rope at the output end of the winch body penetrates through the through hole; a fastening mounting structure connected to the base plate; the dust-blocking mounting structure is connected to the top of the bottom plate and comprises a screen, Y-shaped elastic clamping rods, clamping blocks and I-shaped through holes, the bottom plate is provided with four rectangular I-shaped through holes, the side walls of the bottom of the screen which is arranged in an inverted manner are connected with the four rectangular Y-shaped elastic clamping rods, the Y-shaped elastic clamping rods are inserted into the I-shaped through holes, and the outer side walls of two ends of each Y-shaped elastic clamping rod are fixedly connected with the clamping blocks; a moving structure connected to the base plate.

Preferably, the center of the top of the mesh enclosure is connected with two clamping plates, and two ends of the U-shaped telescopic rod are rotatably connected with the adjacent clamping plates through pin shafts.

Preferably, the fastening and mounting structure comprises a hydraulic cylinder, a motor, a lifting plate and a conical insertion pipe, the rotary rod, the rectangle intubate, first helical gear, threaded rod and second helical gear, the pneumatic cylinder that the back-off set up is installed respectively at bottom plate both sides wall top, the both sides wall bottom of bottom plate is equipped with the recess respectively, the output of pneumatic cylinder runs through bottom plate top side and connect the board that falls, the motor that the back-off set up is installed respectively at the both sides face top of board that falls, the toper intubate is connected respectively to the bottom of the board both sides that falls, the bottom rotates the rotary rod of connecting vertical setting in the toper intubate, the threaded rod that the level set up is connected in the rotation of toper intubate inside wall, the other end threaded connection rectangle intubate of threaded rod, the other end of rectangle intubate runs through the toper intubate lateral wall and with toper intubate lateral wall sliding connection, the side.

Preferably, two adjacent rectangular cannulas are arranged diagonally, and the heads of the rectangular cannulas are conical.

Preferably, the moving structure comprises L-shaped plates, rollers and a rotating shaft, the front side wall and the rear side wall of the bottom plate are respectively connected with the two L-shaped plates, and the vertical ends of the L-shaped plates are rotatably connected with the rollers through the rotating shaft.

Preferably, the top parts of the two side walls of the bottom plate are respectively provided with a hydraulic system, and the hydraulic cylinder is controlled by the hydraulic system.

Compared with the prior art, the utility model provides a hoist engine for geological exploration engineering field has following beneficial effect:

the utility model provides a hoist engine for geological exploration engineering field:

1. reduce hoist engine body working process and receive external dust and pile up the influence possibility, the dust is piled up inside the hoist engine body takes the motor certainly, can influence its operating speed, guarantees the long-time life of hoist engine body, and the screen panel guarantees that inside heat normally discharges, guarantees normal radiating process, regularly through two fixture blocks of extrusion for Y shape elasticity kelly is taken out from I shape through-hole is inside, accomplishes its screen panel and dismantles or the installation, and the periodic disassembly of being convenient for washs.

2. The threaded rod is driven to rotate, so that the rectangular insertion pipe is horizontally moved out, the holding power formed by the rectangular insertion pipe and the address exploration area is increased, and the stability of the placed geological exploration area is improved.

Drawings

Fig. 1 is a schematic structural diagram of a preferred embodiment of a winch for use in the field of geological exploration engineering according to the present invention;

FIG. 2 is an enlarged view of a portion A of FIG. 1;

fig. 3 is a partially enlarged structural view of a portion B shown in fig. 1.

Reference numbers in the figures: 1. a base plate; 2. a winch body; 3. fastening the mounting structure; 4. a dust-blocking mounting structure; 5. a moving structure; 31. a hydraulic cylinder; 32. a groove; 33. an electric motor; 34. a lifting plate; 35. a tapered cannula; 36. rotating the rod; 37. a rectangular cannula; 38. a first helical gear; 39. a threaded rod; 3a, a second bevel gear; 41. a mesh enclosure; 42. a splint; 43. a U-shaped telescopic rod; 44. a pin shaft; 45. a Y-shaped elastic clamping rod; 46. a clamping block; 47. an I-shaped through hole; 51. an L-shaped plate; 52. a roller; 53. a rotating shaft.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and embodiments.

Please refer to fig. 1, fig. 2 and fig. 3 in combination, wherein fig. 1 is a schematic structural diagram of a preferred embodiment of a winch for use in the field of geological exploration engineering according to the present invention; FIG. 2 is an enlarged view of a portion A of FIG. 1; fig. 3 is a partially enlarged structural view of a portion B shown in fig. 1. The hoist engine for the geological exploration engineering field includes: the device comprises a bottom plate 1, a winch body 2, a fastening mounting structure 3, a dust blocking mounting structure 4 and a moving structure 5.

In the specific implementation process, as shown in fig. 1 and 2, a winch body 2 is installed at a position close to the center of the top of a bottom plate 1, a through hole is formed in the bottom of the bottom plate 1, a steel wire rope at the output end of the winch body 2 penetrates through the through hole, a dust blocking installation structure 4 is connected to the top of the bottom plate 1, the dust blocking installation structure 4 comprises a mesh enclosure 41, a Y-shaped elastic clamping rod 45, a clamping block 46 and an i-shaped through hole 47, four rectangular i-shaped through holes 47 are formed in the bottom plate 1, four rectangular Y-shaped elastic clamping rods 45 are connected to the bottom side walls of the mesh enclosure 41 which are reversely arranged, the Y-shaped elastic clamping rod 45 is inserted into the i-shaped through hole 47, the clamping block 46 is fixedly connected to the outer side walls at two ends of the Y-shaped elastic clamping rod 45, it should be noted that the dust in the geological exploration area is large, the mesh enclosure 41 blocks the external dust from falling, inside hoist engine body 12 is piled up from taking the motor to the dust, can influence its rate of operation, guarantees the long-time life of hoist engine body 2, and screen panel 41 guarantees that inside heat normally discharges, guarantees normal radiating process, regularly through two fixture blocks 46 of extrusion for Y shape elasticity kelly 45 is taken out from I shape through-hole 47 is inside, accomplishes its screen panel 4 and dismantles or the installation, is convenient for dismantle the washing regularly.

Referring to fig. 1 and 2, the top center of the mesh enclosure 41 is connected with two clamping plates 42, and two ends of the U-shaped telescopic rod 43 are rotatably connected with the adjacent clamping plates 42 through a pin 44, and it should be noted that the mesh enclosure 41 is pulled by hand to facilitate the operation in the assembling process.

Referring to fig. 1 and 3, the fastening installation structure 3 is connected to the bottom plate 1, the fastening installation structure 3 includes a hydraulic cylinder 31, a motor 33, a rising and falling plate 34, a tapered insertion tube 35, a rotating rod 36, a rectangular insertion tube 37, a first bevel gear 38, a threaded rod 39 and a second bevel gear 3a, the hydraulic cylinder 31 is installed on the top of two side walls of the bottom plate 1 in a reverse buckling manner, the bottom of two side walls of the bottom plate 1 is respectively provided with a groove 32, the output end of the hydraulic cylinder 31 penetrates through the side surface of the top of the bottom plate 1 and is connected with the rising and falling plate 34, the motor 33 is installed on the top of two side surfaces of the rising and falling plate 34 in a reverse buckling manner, the bottom of two sides of the rising and falling plate 34 is respectively connected with the tapered insertion tube 35, the bottom of the tapered insertion tube 35 is rotatably connected, the other end of the rectangular insertion tube 37 penetrates through the side wall of the conical insertion tube 35 and is in sliding connection with the side wall of the conical insertion tube 35, a second bevel gear 3a is installed on the side wall of the threaded rod 39, a first bevel gear 38 is installed on the side wall of the rotary rod 36 and meshed with the second bevel gear 3a, it needs to be noted that the proper position is moved through the moving structure 5, the two hydraulic cylinders 31 are opened, the lifting plate 34 is driven to move downwards, the conical insertion tube 35 is inserted into the ground of the geological exploration area, the electric motor 33 is started again, the rotary rod 36 is driven to rotate, the first bevel gear 38 and the second bevel gear 3a are meshed, the threaded rod 39 is driven to rotate, the rectangular insertion tube 37 is horizontally moved out 1, the holding power is increased by 1 when the rectangular insertion tube 37 is.

Referring to fig. 1, two adjacent rectangular insertion tubes 37 are diagonally arranged, and the heads of the rectangular insertion tubes 37 are tapered to facilitate lateral insertion into a geological exploration area.

Referring to fig. 1, the moving structure 5 is connected to the base plate 1, the moving structure 5 includes L-shaped plates 51, rollers 52 and a rotating shaft 53, the two L-shaped plates 51 are respectively connected to the front side wall and the rear side wall of the base plate 1, and the vertical end of the L-shaped plate 51 is rotatably connected to the rollers 52 through the rotating shaft 53.

Referring to fig. 1, hydraulic systems are respectively installed on the tops of two side walls of the bottom plate 1, and the hydraulic cylinders 31 are controlled by the hydraulic systems, and it should be noted that related circuits and control are the prior art.

The above is only the embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent processes of the present invention can be used in other related technical fields, directly or indirectly, or in the same way as the present invention.

Claims

1. A hoist engine for the geological exploration engineering field is characterized by comprising:

the winch comprises a bottom plate (1), wherein a winch body (2) is arranged at the position, close to the center, of the top of the bottom plate (1), a through hole is formed in the bottom of the bottom plate (1), and a steel wire rope at the output end of the winch body (2) penetrates through the through hole;

a fastening mounting structure (3), the fastening mounting structure (3) being connected to the base plate (1);

the dust blocking mounting structure (4) is connected to the top of the base plate (1), the dust blocking mounting structure (4) comprises a mesh enclosure (41), a Y-shaped elastic clamping rod (45), a clamping block (46) and an I-shaped through hole (47), the base plate (1) is provided with four rectangular I-shaped through holes (47), the side wall of the bottom of the mesh enclosure (41) which is arranged in an inverted manner is connected with the four rectangular Y-shaped elastic clamping rods (45), the Y-shaped elastic clamping rods (45) are inserted into the I-shaped through holes (47), and the outer side walls of two ends of each Y-shaped elastic clamping rod (45) are fixedly connected with the clamping block (46);

a moving structure (5), the moving structure (5) being connected to the base plate (1).

2. The winding machine for the geological exploration engineering field as claimed in claim 1, wherein the top center of the net cover (41) is connected with two clamping plates (42), and two ends of the U-shaped telescopic rod (43) are rotatably connected with the adjacent clamping plates (42) through a pin shaft (44) by a pin shaft (44).

3. The winding machine used in the geological exploration engineering field according to claim 1, wherein the fastening installation structure (3) comprises a hydraulic cylinder (31), a motor (33), a lifting plate (34), a conical insertion tube (35), a rotary rod (36), a rectangular insertion tube (37), a first helical gear (38), a threaded rod (39) and a second helical gear (3a), the hydraulic cylinder (31) is installed on the top of two side walls of the bottom plate (1) in a back-off manner, grooves (32) are respectively arranged on the bottom of two side walls of the bottom plate (1), the output end of the hydraulic cylinder (31) penetrates through the side surface of the top of the bottom plate (1) and is connected with the lifting plate (34), the motors (33) are installed on the top of two side surfaces of the lifting plate (34) in a back-off manner, the bottom of two sides of the lifting plate (34) is respectively connected with the conical insertion tube (35), the bottom of, the threaded rod (39) that toper intubate (35) inside wall rotated connection level set up, the other end threaded connection rectangle intubate (37) of threaded rod (39), the other end of rectangle intubate (37) run through toper intubate (35) lateral wall and with toper intubate (35) lateral wall sliding connection, the side wall mounting of threaded rod (39) second helical gear (3a), the side wall mounting of rotary rod (36) and first helical gear (38) of second helical gear (3a) meshing.

4. Winding engine for the geological exploration engineering field according to claim 3, characterized in that two adjacent rectangular insertion pipes (37) are diagonally arranged, the heads of the rectangular insertion pipes (37) being tapered.

5. The winding machine for the geological exploration engineering field as claimed in claim 1, wherein said moving structure (5) comprises L-shaped plates (51), rollers (52) and a rotating shaft (53), the front side wall and the rear side wall of the bottom plate (1) are respectively connected with the two L-shaped plates (51), and the vertical end of the L-shaped plate (51) is rotatably connected with the rollers (52) through the rotating shaft (53).

6. The winding machine for the geological exploration engineering field as claimed in claim 4, wherein a hydraulic system is respectively installed on the top of two side walls of the bottom plate (1), and the hydraulic cylinder (31) is controlled by the hydraulic system.