CN112208661A

CN112208661A - Self-adaptive transportation equipment

Info

Publication number: CN112208661A
Application number: CN202011110198.0A
Authority: CN
Inventors: 王金行; 尹来容; 杜荣华; 张黄河; 王雨奇; 徐苏杨; 胡宇雄; 黄涛
Original assignee: Changsha University of Science and Technology
Current assignee: Changsha University of Science and Technology
Priority date: 2020-10-16
Filing date: 2020-10-16
Publication date: 2021-01-12
Anticipated expiration: 2040-10-16
Also published as: CN112208661B

Abstract

A self-adaptive transportation device comprises a rope climbing robot, a fruit basket and a base tower, wherein the rope climbing robot comprises a main body, an upper plate, a lower plate, a rope, a power supply, a motor, a rope climbing device, a lifting pressing device, a guiding device, a braking device and a detection device; the rope climbing device comprises an upper crawler belt, a lower crawler belt, a driving gear and a driven pinch roller; the lifting compressing device comprises a lifting platform, a hydraulic rod, a connecting rod assembly and a base, wherein the connecting rod assembly comprises a hinge rod and a sliding rod, and a groove is formed in the lifting platform; the guide device comprises a guide roller, a guide bracket, a suspension roller, a long plate and a short plate; the braking device comprises a braking traction rod, a driving piece, a braking ring plate and a clamping piece; the detection device comprises a support rod, a camera, a bending plate, a three-dimensional rod and a supporting ring.

Description

Self-adaptive transportation equipment

Technical Field

The invention relates to the field of robots, in particular to self-adaptive transportation equipment.

Background

The hills of China are about 100 kilometres square, account for one tenth of the total area of the country, and the economic gross of hilly areas occupies an important position in the main industrial production value of China, for example, the yield of grain and oil products and livestock products occupies a special position in the economic gross of China. The development of economy cannot be separated from the development of transportation industry, the development of transportation industry depends on the transportation mode and the quality of transportation equipment, and particularly, the initial transportation of carrier economy greatly depends on the transportation equipment, so that the development of economy is promoted and proper transportation equipment is needed. At present, in hilly areas, two types of transportation equipment are used for transporting cargoes on complicated terrains and tortuous road sections, and one type of transportation equipment is traditional transportation equipment; the other type is a relatively novel transportation device, which is used for transporting according to the change of the transportation mode of the hilly terrain. The conventional transportation means is mainly to drive the conventional transportation machine by human and to use animal power and change some zones of hills for transportation; traditional transportation needs a large amount of manpower and material resources to go to overcome the resistance that natural topography brought, and the precipitous complicacy of many hilly terrain topography, and the machine can't drive in, and the road is also difficult for opening up, and most highway sections can only hold alone and pass through, need the transportation of labour personnel many times, and this transportation work efficiency is low, and is with high costs and can't ensure staff's safety. Neotype transportation is equipped mainly transports according to selective adoption cableway or track of the topography of hills, cableway transportation mainly used hills slope degree of decline is big plant the district slightly, pile and frame cable through the fixed distance, generally utilize gravity to transport the fruit as power, manpower and materials have been saved to a certain extent, the conveying efficiency has been improved, but there are self-lock device and driving system, can have speed too fast in the time of the downhill path transportation, stability during the transportation is very poor, the basket of transportation is great to the wearing and tearing of cable up and down, the cable has cracked risk, consequently, cost of maintenance is higher and factor of safety is lower. Track transportation is mainly repaiied the road of local unevenness in comparatively spacious hilly area and is made it lay the track, and people drive special track machine and transport, and this transportation mode has improved conveying efficiency, but road rectification and laying track need a large amount of costs and destroy great to local topography and geomorphology, receives geographical environment to influence great.

However, in practical use, the following problems exist:

1. the rope climbing robot in the prior art only has the rope climbing function, but lacks of an adjusting means for clamping the rope.

2. The rope climbing robot in the prior art only considers the clamping principle and does not consider the problem of clamping stability in the clamping process.

3. In the prior art, a rope climbing robot probably considers a multifunctional design, but the multifunctional design is complex in structure and is difficult to simplify parts.

4. The rope climbing robot in the prior art probably has a multifunctional design, but various functional modules are independent of each other and lack the cooperation of functions and structures.

5. The prior art guide structure is usually that two identical rollers clamp the rope for guiding, and how to improve the guide effect and reduce the transmission resistance is never considered.

6. The camera detection device in the prior art is often provided with a detection platform, but the detection platform is often thick and heavy in structure.

7. The clamping equipment in the prior art is common in coaxial clamping, but has single function and can not realize the change of a clamping position.

8. In the braking technology in the prior art, the side turning is easy to happen due to sudden braking in the transmission process.

Disclosure of Invention

In order to overcome the above problems, the present invention proposes a solution to solve the above problems simultaneously.

The technical scheme adopted by the invention for solving the technical problems is as follows: a self-adaptive transportation device comprises a rope climbing robot, a fruit basket and a base tower, wherein the rope climbing robot comprises a main body, an upper plate, a lower plate, a rope, a power supply, a motor, a rope climbing device, a lifting pressing device, a guiding device, a braking device and a detection device; the rope climbing device comprises an upper crawler belt, a lower crawler belt, a driving gear and a driven pinch roller; the lifting compressing device comprises a lifting platform, a hydraulic rod, a connecting rod assembly and a base, wherein the connecting rod assembly comprises a hinge rod and a sliding rod, and a groove is formed in the lifting platform; the guide device comprises a guide roller, a guide bracket, a suspension roller, a long plate and a short plate; the braking device comprises a braking traction rod, a driving piece, a braking ring plate and a clamping piece; the detection device comprises a support rod, a camera, a bending plate, a three-dimensional rod and a supporting ring;

the base tower comprises: the device comprises a scaffold, wing plates, a supporting table and an arch frame, wherein the wing plates are arranged above the scaffold, the supporting table is arranged above the wing plates, the supporting table is connected with the arch frame, the arch frame consists of four arch-shaped rods, the number of the scaffolds is two, the number of the supporting tables is two, reinforcing ribs are connected between the scaffolds and the wing plates, four corners of the fruit basket are connected to the lower plate through hanging pieces, and two side faces of the fruit basket are provided with vent holes; a hook is arranged on the third side surface of the fruit basket;

the upper plate and the lower plate extend out of the range of the main body, the motor is arranged in the main body, the power supply is arranged above the upper plate, the rope climbing devices are arranged on the left side and the right side of the main body, and the guide devices and the brake devices are arranged at the front and the back of the rope climbing devices; the two braking devices are respectively connected to the upper plate or the lower plate through clamping pieces, the guide device is fixed on the lower plate through the guide support, and the lifting pressing device is arranged below the lower plate; the driving gear and the driven pinch roller are arranged in the upper crawler and the lower crawler; the rope is arranged between the upper crawler and the lower crawler;

the long plate and the short plate are fixed on the guide support, the length of the long plate is greater than that of the short plate, the long plate is positioned above the short plate, two ends of the guide roller are respectively connected with the long plate and the short plate, one end of the suspension roller is connected with the long plate, and the other end of the suspension roller is suspended;

one end of the supporting rod is connected above the long plate, the other end of the supporting rod is connected with the bending plate, the three-dimensional rod and the camera are connected to the bending plate, the three-dimensional rod comprises an X-direction rod, a Y-direction rod and a Z-direction rod, the supporting ring is connected below the X-direction rod, and the position of the supporting ring corresponds to the position below the camera;

the lifting pressing device is fixed below the lower plate through a shell, the base is fixed in the shell, the hydraulic rod is located inside the connecting rod assembly, the lifting platform is located above the hydraulic rod and the connecting rod assembly, the number of the grooves corresponds to the number of the driven pressing wheels, and the base is provided with folded edges;

the clamping piece is connected with the driving piece, the driving piece drives the braking traction rod to move, the braking traction rod comprises a straight rod and an inclined rod, and the braking ring plate is connected below the inclined rod.

Furthermore, a hollow structure is arranged on the upper plate.

Further, the hollow-out structures are obliquely arranged.

Further, a pulley is arranged below the lower plate.

Furthermore, a friction line is further arranged on the lifting platform.

Further, the friction line extends in the direction of the rope.

Further, the driving member is a hydraulic driving member.

Further, the driving member is an electromagnetic driving member.

Furthermore, a rib plate is arranged between the straight rod and the diagonal rod.

Further, the bending plate comprises two plates perpendicular to each other.

The invention has the beneficial effects that:

compared with the existing transport machines and rope climbing robots, the rope climbing transport robot adopts the crawler-type rope climbing device as the main body; the lower crawler belt is pressed onto the rope by the driven pinch roller on the driven wheel shaft, so that the rope is prevented from slipping; the detection device is connected with the controller, so that the motion state and the rope state of the transport robot can be accurately recorded; the electromagnetic braking device is adopted, so that the damage of the transport robot caused by faults or too high speed and incapability of reducing the speed is prevented, and the safety of the transport robot in the transport process is enhanced.

Drawings

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is one of the working schematic diagrams of the adaptive transportation device according to the present invention.

Fig. 2 is a schematic structural diagram of the adaptive transportation device according to the present invention.

Fig. 3 is a schematic position diagram of the lifting and pressing device of the adaptive transportation equipment.

Fig. 4 is a schematic structural diagram of a guiding device of the adaptive transportation equipment.

Fig. 5 is a schematic structural diagram of a detection device of the adaptive transportation equipment according to the present invention.

Fig. 6 is a schematic view of a lifting and pressing device of the adaptive transport equipment according to the present invention.

Fig. 7 is a schematic view of a braking device of the adaptive transport equipment according to the present invention.

Fig. 8 is a working fit relation diagram of the adaptive transportation device according to the invention.

Fig. 9 is a schematic view of a base tower of the adaptive transport equipment of the present invention.

The reference numbers in the figures are as follows:

the device comprises an upper plate 1, a power supply 2, a motor 3, a rope climbing device 4, an upper crawler 41, a lower crawler 42, a driving gear 43, a driven pinch roller 44, a lifting and pressing device 5, a lifting platform 51, a connecting rod assembly 52, a hydraulic rod 53, a base 54, a hinged rod 55, a sliding rod 56, a groove 57, a folded edge 58, a guide device 6, a guide roller 61, a guide support 62, an overhead roller 63, a long plate 64, a short plate 65, a brake device 7, a brake pull rod 71, a driving piece 72, a brake ring plate 73, a clamping piece 74, a detection device 8, a support rod 81, a camera 82, a bending plate 83, a three-dimensional rod 84, a support ring 85, a controller 9, a rope 10, a fruit basket 11, a base tower 12, a scaffold 121, a wing plate 122, a support platform 123, an arch 124.

Detailed Description

The invention of the application comprises the following steps:

1. to the 1 st point that the background art provided, adopted the centre gripping equipment to the track for when the track transmission, the centre gripping effect to the rope can be adjusted.

2. To the 2 nd point that the background art provided, designed centre gripping recess and friction line, realized the shape fit of centre gripping platform and driven pinch roller in the clamping process, increased the stability of centre gripping.

3. Aiming at the 3 rd point provided by the background technology, the upper plate and the lower plate are taken as references, the braking device is clamped on the upper plate, the guiding device is supported on the lower plate, the centering performance and the support performance are realized by the upper plate and the lower plate, the structure of parts is greatly simplified, and a complex support structure is not required to be designed.

4. In the 4 th point proposed by the background art, the guiding device and the detecting device are organically combined, and the functional combination comprises: because the distance is close, the guiding device helps the detection device to realize the stability, the structural combination includes: the detection device is arranged on the upper surface of the guide device.

5. To the 5 th point that the background art provided, set up a roller fixed, a roller unsettled structure to reduce unsettled roller corresponding fixed knot and reduced the part among the transmission process, thereby reduced the transmission energy consumption.

6. To the 6 th point that the background art provided, to the peculiarity of rope light, designed three-dimensional bar shape support and backing ring to realized supporting platform's lightweight, X can carry out spacingly to the rope to a certain extent to the position that the pole is higher than the backing ring to the X.

7. Aiming at the 7 th point provided by the background technology, a structure that a driving shaft and a clamping position are staggered is adopted, and the different-shaft clamping is realized.

8. In the 8 th point proposed by the background art, the matched linkage of the braking device and the lifting pressing device is adopted, so that even if the braking is suddenly carried out, the pressing device can press the rope.

Note: the foregoing designs are not sequential, each of which provides a distinct and significant advance in the present invention over the prior art.

The technical scheme comprises the following details:

as shown in the figure: a self-adaptive transportation device comprises a rope climbing robot, a fruit basket and a base tower, wherein the rope climbing robot comprises a main body, an upper plate, a lower plate, a rope, a power supply, a motor, a rope climbing device, a lifting pressing device, a guiding device, a braking device and a detection device; the rope climbing device comprises an upper crawler belt, a lower crawler belt, a driving gear and a driven pinch roller; the lifting compressing device comprises a lifting platform, a hydraulic rod, a connecting rod assembly and a base, wherein the connecting rod assembly comprises a hinge rod and a sliding rod, and a groove is formed in the lifting platform; the guide device comprises a guide roller, a guide bracket, a suspension roller, a long plate and a short plate; the braking device comprises a braking traction rod, a driving piece, a braking ring plate and a clamping piece; the detection device comprises a support rod, a camera, a bending plate, a three-dimensional rod and a supporting ring;

as shown in the figure: the upper plate and the lower plate extend out of the range of the main body, the motor is arranged in the main body, the power supply is arranged above the upper plate, the rope climbing devices are arranged on the left side and the right side of the main body, and the guide devices and the brake devices are arranged at the front and the back of the rope climbing devices; the two braking devices are respectively connected to the upper plate or the lower plate through clamping pieces, the guide device is fixed on the lower plate through the guide support, and the lifting pressing device is arranged below the lower plate; the driving gear and the driven pinch roller are arranged in the upper crawler and the lower crawler; the rope is arranged between the upper crawler and the lower crawler;

As shown in the figure: the upper plate is provided with a hollow structure. The hollow-out structures are obliquely arranged. And a pulley is arranged below the lower plate. And a friction line is also arranged on the lifting platform. The friction line extends in the direction of the rope. The driving part is a hydraulic driving part. The driving piece is an electromagnetic driving piece. And a rib plate is arranged between the straight rod and the inclined rod. The bending plate comprises two plates which are perpendicular to each other.

The compaction adjusting method comprises the following steps: after the goods are loaded, the motor is wirelessly controlled to output power to the driving gear, and the driving gear rotates to drive the upper crawler belt and the lower crawler belt to rotate; meanwhile, the hydraulic rod pushes the connecting rod assembly and the lifting platform to move, so that the lifting platform drives a driven wheel shaft connected with the driven pressing wheel to move, and the driven pressing wheel moves to press the lower crawler belt onto the rope.

The above detailed description is specific to possible embodiments of the present invention, and the embodiments are not intended to limit the scope of the present invention, and all equivalent implementations or modifications that do not depart from the scope of the present invention are intended to be included within the scope of the present invention.

Claims

1. An adaptive transport apparatus, characterized by: the fruit basket climbing robot comprises a main body, an upper plate, a lower plate, a rope, a power supply, a motor, a rope climbing device, a lifting pressing device, a guiding device, a braking device and a detection device; the rope climbing device comprises an upper crawler belt, a lower crawler belt, a driving gear and a driven pinch roller; the lifting compressing device comprises a lifting platform, a hydraulic rod, a connecting rod assembly and a base, wherein the connecting rod assembly comprises a hinge rod and a sliding rod, and a groove is formed in the lifting platform; the guide device comprises a guide roller, a guide bracket, a suspension roller, a long plate and a short plate; the braking device comprises a braking traction rod, a driving piece, a braking ring plate and a clamping piece; the detection device comprises a support rod, a camera, a bending plate, a three-dimensional rod and a supporting ring;

2. An adaptive transport device according to claim 1, characterized in that: the upper plate is provided with a hollow structure.

3. An adaptive transport device according to claim 2, characterized in that: the hollow-out structures are obliquely arranged.

4. An adaptive transport device according to claim 1, characterized in that: and a pulley is arranged below the lower plate.

5. An adaptive transport device according to claim 1, characterized in that: and a friction line is also arranged on the lifting platform.

6. An adaptive transport apparatus according to claim 5, characterized in that: the friction line extends in the direction of the rope.

7. An adaptive transport device according to claim 1, characterized in that: the driving part is a hydraulic driving part.

8. An adaptive transport device according to claim 1, characterized in that: the driving piece is an electromagnetic driving piece.

9. An adaptive transport device according to claim 1, characterized in that: and a rib plate is arranged between the straight rod and the inclined rod.

10. An adaptive transport device according to claim 1, characterized in that: the bending plate comprises two plates which are perpendicular to each other.