CN120903283A

CN120903283A - Cable guiding structure for ship loader

Info

Publication number: CN120903283A
Application number: CN202511394327.6A
Authority: CN
Inventors: 郭勇; 童星
Original assignee: Jiangsu Lianyungang Port Co ltd
Current assignee: Jiangsu Lianyungang Port Co ltd
Priority date: 2025-09-28
Filing date: 2025-09-28
Publication date: 2025-11-07
Anticipated expiration: 2045-09-28
Also published as: CN120903283B

Abstract

The application provides a cable guide structure for a ship loader, which relates to the field of port transportation and comprises a machine body, a mounting seat arranged on the machine body, a winding drum rotatably arranged on the mounting seat, and a synchronous adjusting mechanism arranged on the mounting seat, wherein the mounting seat is provided with a plurality of guide grooves; the application aims to solve the problems that in the prior art, when a cantilever of the ship loader changes angles through a pitching device, a cable on the cantilever can rub against the cantilever, so that the cable is worn, and the service life of the cable is reduced; the cable winding and unwinding device solves the problem that cable damage is caused by knotting when the cable is released in the prior art through the synchronous adjusting mechanism, and solves the problem that winding and unwinding efficiency is reduced due to cable size change in the prior art through the synchronous adjusting mechanism.

Description

Cable guiding structure for ship loader

Technical Field

The invention relates to the field of port transportation, in particular to a cable guide structure for a ship loader.

Background

The utility model provides a shipment machine cable guide structure is an important mechanical device, mainly used guides and protects shipment machine cable that uses in the operation process, wherein current shipment machine cable guide structure comprises current hysteresis lag formula cable reel and tow chain, hysteresis formula cable reel is responsible for carrying out automatic winding and unwinding to the cable, the tow chain is responsible for carrying out dynamic direction to the cable, but when the cantilever carries out the angle change through every single move device, the cantilever is the arc motion around fixed fulcrum when every single move, cable length and the path length mismatch after the cantilever every single move for the cable of connection on the cantilever can produce friction with the cantilever, can lead to the cable wearing and tearing like this, make life reduce.

For example, the specification of the ship loader and the cable guiding structure disclosed in Chinese patent application number 202110621594.8 discloses that the ship loader is a large bulk cargo machine used for loading ships at a bulk cargo dock. The general ship loader consists of a cantilever, a running device, a portal frame, a tower, a pitching device, a turning device and the like. When the cantilever changes angle through the pitching device, the cable connected to the cantilever can rub against the cantilever, so that the outer layer of the cable is worn, the safe operation of the ship loader is affected, and the defects of the prior art can be confirmed by the patent.

Therefore, we make improvements to this and propose a cable guide structure for a ship loader.

Disclosure of Invention

The invention aims to solve the problems that when the cantilever of the ship loader is subjected to angle change through a pitching device, friction is generated between a cable on the cantilever and the cantilever, so that the cable is worn and the service life of the cable is shortened.

In order to achieve the above object, the present invention provides a cable guide structure for a ship loader, which solves the above problems.

The application is specifically as follows:

The device comprises a machine body, a mounting seat arranged on the machine body, a winding drum arranged on the mounting seat in a rotating mode, and a synchronous adjusting mechanism arranged on the mounting seat;

The synchronous regulating mechanism comprises a connecting shaft which is arranged on the mounting seat in a rotating way, a sliding seat which is arranged on the connecting shaft, a transmission block which is arranged on the sliding seat, a cavity which is arranged on the transmission block, a wedge block which is arranged in the cavity in a sliding way, a spring which is arranged in the cavity, a triangle block which is arranged on the winding drum, a worm wheel which is arranged on the connecting shaft, a motor which is arranged on the mounting seat and a worm which is arranged on the output end of the motor.

As a preferable technical scheme of the application, the triangular block is matched with the wedge block, and the worm wheel and the worm are mutually matched.

As a preferable technical scheme of the application, the wedge block is rotatably provided with a driving shaft, the driving shaft is provided with a roller, and the roller is matched with the winding drum.

As a preferable technical scheme of the application, the connecting shaft is provided with a sliding groove, and the sliding groove is provided with a bearing.

As a preferable technical scheme of the application, the connecting shaft is provided with a guide groove, the sliding seat is arranged on the guide groove in a sliding way, the winding drum is provided with a driving block, and the driving block is matched with the wedge-shaped block.

As the preferable technical scheme of the application, a top moving block is arranged in the cavity in a sliding way, threaded rods are rotatably arranged on the sliding seat and the transmission block, the top moving block is connected with the threaded rods through threads, and two ends of the spring are respectively arranged on corresponding surfaces of the top moving block and the cavity.

As the preferable technical scheme of the application, the threaded rod is provided with the driving gear, the sliding seat is rotatably provided with the fluted disc, the fluted disc is matched with the driving gear, and the fluted disc is provided with the driving ring.

As the preferable technical scheme of the application, the sliding groove is provided with a rubber pad, and the sliding seat is matched with the rubber pad.

Compared with the prior art, the invention has the beneficial effects that:

In the scheme of the application:

1. In order to solve the problem that the service life of a cable is shortened due to abrasion caused by friction between the cable on the cantilever and the cantilever when the cantilever of the ship loader changes angles through the pitching device in the prior art, the self-adaptive winding and unwinding of the cable is realized through the synchronous adjusting mechanism, the situation that the length of the cable is not matched with the path length of the cantilever after pitching is prevented, and the service life of the cable is prolonged;

2. Through the synchronous adjusting mechanism, when the cable is released, the possibility of winding and knotting of the cable is reduced through vibration, so that the efficiency of releasing the cable is improved, and the problem of cable damage caused by knotting when the cable is released in the prior art is solved;

3. Through the synchronous adjustment mechanism who sets up, through the elastic potential energy of adjusting spring, realized the self-adaptation to different size cables receive and releases, improved the commonality of this equipment, solved among the prior art cable size change and lead to receive and release the problem that efficiency reduces.

Drawings

Fig. 1 is a schematic structural view of a cable guide structure for a ship loader according to the present application;

Fig. 2 is a schematic diagram of the overall structure of a winding drum of the cable guiding structure for the ship loader;

FIG. 3 is a schematic view of a partial cross-sectional structure of a spool and a connecting shaft of the cable guiding structure for a ship loader provided by the application;

fig. 4 is a schematic diagram of the overall structure of a transmission block and a wedge block of the cable guiding structure for the ship loader;

FIG. 5 is a schematic view of a partially sectioned structure of a sliding seat and a transmission block of the cable guiding structure for a ship loader provided by the application;

fig. 6 is a schematic diagram of a two-dimensional structure of a triangular block and a driving block of the cable guiding structure for the ship loader.

The figures indicate:

1. the machine body comprises a machine body, a mounting seat, a winding drum and a winding drum;

2. The synchronous adjusting mechanism comprises a synchronous adjusting mechanism body 201, a connecting shaft 202, a sliding seat 203, a transmission block 204, a cavity 205, a wedge block 206, a spring 207, a triangular block 208, a worm gear 209, a motor 210, a worm 211, a driving shaft 212, a roller 213, a sliding groove 214, a bearing 215, a guide groove 216, a driving block 217, a top moving block 218, a threaded rod 219, a driving gear 220, a fluted disc 221, a driving ring 222 and a rubber pad.

Detailed Description

In order that those skilled in the art will better understand the present invention, a technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in which it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present invention without making any inventive effort, shall fall within the scope of the present invention.

As described in the background art, when the cantilever of the ship loader is subjected to angle transformation by the pitching device, friction is generated between the cable on the cantilever and the cantilever, so that the cable is worn, and the service life of the cable is reduced.

In order to solve the technical problem, the invention provides a cable guiding structure for a ship loader, which is applied to port transportation.

Specifically, referring to fig. 1-6, the cable guiding structure for a ship loader specifically includes a machine body 1, a mounting seat 101 disposed on the machine body 1, a winding drum 102 rotatably disposed on the mounting seat 101, and a synchronous adjusting mechanism 2 disposed on the mounting seat 101, wherein in the prior art, the winding drum 102 performs winding and unwinding operations on a cable through rotation, and a cantilever non-moving part (such as a cantilever root part) on the machine body 1 is provided with an existing drag chain, the cable passes through the interior of the drag chain, and the drag chain guides the cable;

The synchronous adjusting mechanism 2 comprises a connecting shaft 201 arranged on the mounting base 101 in a rotating manner, a sliding base 202 arranged on the connecting shaft 201, a transmission block 203 arranged on the sliding base 202, a cavity 204 arranged on the transmission block 203, a wedge-shaped block 205 arranged in the cavity 204 in a sliding manner, a spring 206 arranged in the cavity 204, a triangle block 207 arranged on the winding drum 102, a worm wheel 208 arranged on the connecting shaft 201, a motor 209 arranged on the mounting base 101 and a worm 210 arranged on the output end of the motor 209.

According to the cable guide structure for the ship loader, provided by the application, in order to solve the problem that the service life of a cable is shortened due to abrasion caused by friction between the cable on the cantilever and the cantilever when the cantilever of the ship loader is subjected to angle change through the pitching device in the prior art, the cable is self-adaptively wound and unwound through the synchronous adjusting mechanism 2, so that the condition that the length of the cable is not matched with the path length of the cantilever after pitching is prevented, and the service life of the cable is prolonged;

through the synchronous adjusting mechanism 2, when the cable is released, the possibility of winding and knotting of the cable is reduced through vibration, so that the efficiency of releasing the cable is improved, and the problem of cable damage caused by knotting when the cable is released in the prior art is solved;

Through the synchronous adjustment mechanism 2 that sets up, through the elastic potential energy of adjusting spring 206, realized the self-adaptation to different size cables receive and releases, improved the commonality of this equipment, solved the cable size change among the prior art and lead to receive and release efficiency reduction's problem.

In order to make the person skilled in the art better understand the solution of the present invention, the technical solution of the embodiment of the present invention will be clearly and completely described below with reference to the accompanying drawings.

It should be noted that, under the condition of no conflict, the embodiments of the present invention and the features and technical solutions in the embodiments may be combined with each other.

It should be noted that like reference numerals and letters refer to like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In embodiment 1, please refer to fig. 1, 2, 3,4, 5 and 6, the cable guiding structure for ship loader is adapted with the triangular block 207 and the wedge block 205, and the worm wheel 208 and the worm 210 are adapted with each other;

In use, when the cantilever of the machine body 1 is lifted, the cable wound on the winding drum 102 is stretched and drives the winding drum 102 to rotate, as shown in fig. 2, the winding drum 102 rotates clockwise and drives the triangular block 207 to rotate synchronously, the triangular block 207 rotates clockwise and presses the wedge-shaped block 205, and the worm 210 has a self-locking function on the worm wheel 208, so that the connecting shaft 201, the sliding seat 202, the transmission block 203 and the wedge-shaped block 205 cannot rotate, and further the wedge-shaped block 205 is pressed by the triangular block 207 and slides along the cavity 204, when the triangular block 207 passes over the wedge-shaped block 205, the wedge-shaped block 205 is reset through the elasticity of the spring 206, so that when the cantilever of the machine body 1 is lifted upwards, the winding drum 102 can release the cable timely, when the cantilever of the machine body 1 is lowered, the cable sags down, the motor 209 drives the worm 210 to rotate, as shown in fig. 2, the worm 210 drives the worm wheel 208 to rotate anticlockwise, the worm wheel 208 drives the connecting shaft 201, the sliding seat 202, the transmission block 203 and the wedge block 205 to synchronously rotate anticlockwise, the triangular block 207 and the winding drum 102 synchronously rotate through the jacking triangular block 207 of the wedge block 205, when a cable on the winding drum 102 is wound and tightened, the wedge block 205 presses the triangular block 207, the wedge block 205 is pressed and slides along the cavity 204, the winding drum 102 does not rotate, the wedge block 205 idles along the inner wall of the winding drum 102, in this way, winding of the cable is realized, the tightness of the cable is adaptively controlled, the cable always maintains proper tightness in the movement process, collision or friction between the cable and other parts of the machine body 1 is avoided, the situation that the cable length is not matched with the path length after the cantilever pitching is prevented through the adaptive winding and unwinding of the cable, and the service life of the cable is further prolonged;

further, a driving shaft 211 is rotatably arranged on the wedge block 205, a roller 212 is arranged on the driving shaft 211, and the roller 212 is matched with the winding drum 102;

The roller 212 rolls along the inner wall of the winding drum 102, friction between the triangular block 207 and the wedge block 205 is reduced through contact between the roller 212 and the triangular block 207, when the triangular block 207 drives the wedge block 205 to slide along the cavity 204, the wedge block 205 is driven to slide and reset through elasticity of the spring 206 and impact the inner wall of the winding drum 102, so that vibration is generated inside the winding drum 102, and when a cable is released, the possibility of winding and knotting of the cable is reduced through vibration, so that the cable release efficiency is improved;

Further, a sliding groove 213 is provided on the connecting shaft 201, and a bearing 214 is provided on the sliding groove 213;

one end of the cable is connected with cantilever external equipment, and the other end of the cable passes through the bearing 214 and the sliding groove 213 and is connected with the junction box of the machine body 1;

Through synchronous adjustment mechanism 2 to the self-adaptation receive and releases of cable, prevent the unmatched condition of cable length and path length behind the cantilever every single move, improved the life of cable, when the cable is releasing, reduce the cable through vibrations and twine and tie the possibility of knot to improve the efficiency of cable release.

In embodiment 2, the cable guiding structure for the ship loader provided in embodiment 1 is further optimized, specifically, as shown in fig. 2, 3,4, 5 and 6, a guiding groove 215 is provided on the connecting shaft 201, the sliding seat 202 is slidably provided on the guiding groove 215, a driving block 216 is provided on the winding drum 102, and the driving block 216 is adapted to the wedge block 205;

As shown in fig. 6, one end of the driving block 216, which contacts the wedge block 205, is wedge-shaped, when the driving block 203 rotates, the driving block 216 blocks the driving block 203, and when the sliding seat 202 is driven to slide along the guide groove 215, so that the wedge block 205 is separated from the triangular block 207 and contacts the driving block 216, under the condition of winding a cable, as shown in fig. 3, when the sliding seat 202, the driving block 203 and the wedge block 205 are driven to rotate anticlockwise, the driving block 203 pushes the driving block 216, and the driving block 216 drives the winding drum 102 to synchronously rotate, so that winding of the cable is realized, and the method is suitable for the condition that the cable is blocked in the winding process;

Further, a top sliding block 217 is slidably arranged in the cavity 204, threaded rods 218 are rotatably arranged on the sliding seat 202 and the transmission block 203, the top sliding block 217 and the threaded rods 218 are connected through threads, and two ends of the spring 206 are respectively arranged on corresponding surfaces of the top sliding block 217 and the cavity 204;

when the threaded rod 218 is rotated, the threaded rod 218 rotates and drives the top movable block 217 to slide along the cavity 204, and the top movable block 217 slides and presses the spring 206, so that the elastic potential energy of the spring 206 is increased, and the self-adaptive retraction of cables with different sizes is realized by changing the elastic potential energy of the spring 206 for cables with different sizes;

Further, a driving gear 219 is disposed on the threaded rod 218, a fluted disc 220 is rotatably disposed on the sliding seat 202, the fluted disc 220 is adapted to the driving gear 219, and a driving ring 221 is disposed on the fluted disc 220;

When the driving ring 221 is rotated, the driving ring 221 drives the fluted disc 220 to rotate synchronously, the fluted disc 220 drives the driving gear 219 to rotate synchronously, and the driving gear 219 drives the threaded rod 218 to rotate synchronously, as shown in fig. 5

Further, the sliding groove 213 is provided with a rubber pad 222, the sliding seat 202 is matched with the rubber pad 222, and friction force between the sliding seat 202 and the sliding groove 213 is increased by the rubber pad 222, so that the sliding seat 202 is prevented from sliding on the sliding groove 213 when the roller 212 impacts the inner wall of the winding drum 102;

when the cables with different sizes are wound and unwound, the self-adaptive winding and unwinding of the cables with different sizes is realized by adjusting the elastic potential energy of the spring 206, and the universality of the equipment is improved.

The use process of the cable guiding structure for the ship loader provided by the invention is as follows:

When in use, when the cantilever of the machine body 1 is lifted, the cable wound on the winding drum 102 is stretched and driven to rotate by the elastic driving wedge 205 and the roller 212 of the spring 206 to synchronously slide and reset and strike the inner wall of the winding drum 102, the cable winding and the possibility of driving the triangular block 207 to synchronously rotate are reduced by the vibration, the winding drum 102 can timely release the cable when the cantilever of the machine body 1 is lifted, the cable is drooping by the starting motor 209, the worm 210 is driven to drive the worm 210 to rotate by the driving worm 208 to drive the connecting shaft 201, the sliding seat 202, the transmission block 203 and the wedge 205 to synchronously rotate anticlockwise, the wedge 205 pushes the three-angle block 205 to rotate along the inner wall of the winding drum 102, the three-angle block 205 is driven by the worm wheel 205 to always rotate by the driving wedge 205 and the wedge 205 to synchronously rotate by the driving ring 219 of the cable, the cable is driven by the wedge 219 to synchronously rotate by the driving ring 220, the cable is driven by the driving ring 220 to synchronously rotate by the wedge 219, and the rotation of the wedge 219 is controlled by the driving ring 218, and the rotation of the wedge 219 is driven to synchronously rotate along the inner wall of the wedge 204, the pushing block 217 slides and presses the spring 206, so that the elastic potential energy of the spring 206 is increased, and the self-adaptive retraction of cables with different sizes is realized by changing the elastic potential energy of the spring 206 for cables with different sizes.

In the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed, mechanically connected, electrically connected, or communicable with each other, directly connected, indirectly connected through an intervening medium, or in communication between two elements or in an interactive relationship between two elements, unless otherwise explicitly specified. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

It is apparent that the above-described embodiments are only some embodiments of the present invention, but not all embodiments, and the preferred embodiments of the present invention are shown in the drawings, which do not limit the scope of the patent claims. This invention may be embodied in many different forms, but rather, embodiments are provided in order to provide a thorough and complete understanding of the present disclosure. Although the 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 described in the foregoing description, or equivalents may be substituted for elements thereof. All equivalent structures made by the content of the specification and the drawings of the invention are directly or indirectly applied to other related technical fields, and are also within the scope of the invention.

Claims

1. The cable guide structure for the ship loader comprises a machine body (1), a mounting seat (101) arranged on the machine body (1) and a winding drum (102) rotatably arranged on the mounting seat (101), and is characterized by comprising a synchronous adjusting mechanism (2) arranged on the mounting seat (101);

Synchronous adjustment mechanism (2) are including rotating connecting axle (201) that sets up on mount pad (101), set up sliding seat (202) on connecting axle (201), set up drive block (203) on sliding seat (202), set up cavity (204) on drive block (203), slide setting is in wedge (205) in cavity (204), set up spring (206) in cavity (204), set up triangle piece (207) on reel (102), set up worm wheel (208) on connecting axle (201), set up motor (209) on mount pad (101), set up worm (210) on motor (209) output.

2. The cable guide structure for a ship loader according to claim 1, wherein the triangle block (207) and the wedge block (205) are adapted, and the worm wheel (208) and the worm (210) are adapted to each other.

3. The cable guide structure for the ship loader according to claim 2, wherein a driving shaft (211) is rotatably arranged on the wedge block (205), a roller (212) is arranged on the driving shaft (211), and the roller (212) is matched with the winding drum (102).

4. A cable guide structure for a ship loader according to claim 3, characterized in that the connecting shaft (201) is provided with a sliding groove (213), and the sliding groove (213) is provided with a bearing (214).

5. The cable guide structure for the ship loader according to claim 4, wherein a guide groove (215) is formed in the connecting shaft (201), the sliding seat (202) is slidably arranged on the guide groove (215), a driving block (216) is arranged on the winding drum (102), and the driving block (216) is matched with the wedge block (205).

6. The cable guide structure for the ship loader according to claim 5, wherein a top moving block (217) is slidably arranged in the cavity (204), a threaded rod (218) is rotatably arranged on the sliding seat (202) and the transmission block (203), the top moving block (217) and the threaded rod (218) are connected through threads, and two ends of the spring (206) are respectively arranged on corresponding surfaces of the top moving block (217) and the cavity (204).

7. The cable guiding structure for ship loader according to claim 6, wherein the threaded rod (218) is provided with a driving gear (219), the sliding seat (202) is rotatably provided with a fluted disc (220), the fluted disc (220) is matched with the driving gear (219), and the fluted disc (220) is provided with a driving ring (221).

8. The cable guide structure for the ship loader according to claim 7, wherein the sliding groove (213) is provided with a rubber pad (222), and the sliding seat (202) is matched with the rubber pad (222).