CN219636581U

CN219636581U - Nondestructive cable discharges conveyor

Info

Publication number: CN219636581U
Application number: CN202320084526.7U
Authority: CN
Inventors: 么洪坤
Original assignee: Kunming Ruijian Power Transmission And Distribution Engineering Co ltd
Current assignee: Me Hongkun
Priority date: 2023-01-29
Filing date: 2023-01-29
Publication date: 2023-09-05
Anticipated expiration: 2033-01-29

Abstract

The utility model discloses a nondestructive cable applying and conveying device, which is used for clamping a conveying belt assembly of a cable, wherein the conveying belt assembly can provide driving force for forward conveying of the cable and can adjust the clamping interval of the conveying belt assembly to adapt to cables with different thickness and diameter; the cable can be clamped in a self-adaptive mode and driven to be conveyed forwards in a constant-speed mode, and the conveying sensor arranged on the conveying module can detect whether the cable is in place or not, acquire current lateral pressure data of the cable and feed the lateral pressure data back to the master control module. The utility model can monitor the current operation parameters of the conveying device in each application link, has the self-adaptive clamping force adjusting function, realizes the quick assembly of the conveying device through the modularized and lightweight structural design, is flexible to use, realizes the quick, safe and lossless conveying of cables through the monitoring of real-time state data and pressure data, and has the characteristics of equal height, constant speed, safety and convenience.

Description

Nondestructive cable discharges conveyor

Technical Field

The utility model relates to the technical field of high-voltage cable laying and applying in the power industry, in particular to a nondestructive cable applying and conveying device.

Background

The traditional cable laying system mainly adopts manual laying experience, and relies on professional tools, but a large amount of manpower is required to complete the cable laying work. The cable laying and conveying device is used as equipment for providing cable travelling power in the laying process and is key and indispensable equipment in the cable laying process; however, the current cable conveying device has the following general problems:

in the process of laying the cable, the stress condition of the cable cannot be monitored in real time, the whole laying process is operated by a black box, the problems of overlarge local stress and overlarge tensile force easily occur in the laying process, and if the stress of the cable exceeds a standard value, the cable cannot be automatically warned, so that the cable and equipment are lost; in the prior art, when a cable is required to be laid, a plurality of conveying devices are required to be installed and combined along the whole release path, and because of site environmental factors such as topography, topography and the like, the initial point positions of the cable entering the belt of the conveying devices are different in height and different in contact with the conveying devices, so that the situation that the surface of the cable is different in linear speed is generated, the outer layer of the cable is easy to have different speeds, the traction force and the speed are not matched, the conveying devices cannot keep the same-speed conveying, and the risk of damaging the cable is increased; when the situation is met, the existing conveying device has the problems that slipping and idle running occur due to unstable clamping of passing cables, the clamping position is easy to deviate, upwarp and the like at the head and tail positions of the conveying device, different conveying friction forces are generated at the head and tail positions and the middle section of the conveying device, the speed is poor, the idle running of the conveying device is easy to occur, or the uneven stress of the cables is caused, insulating skin abrasion is generated, the conveying devices cannot be adaptively adjusted for cables with different thickness, the space is often required to be manually adjusted to meet the passing of the cables with different thickness, the problems occur in many times, namely the conveying device can slip due to poor clamping force, the damage to the cables is easy to be caused due to excessive pressure, and the monitoring to the clamping force is absent; in addition, the existing conveying device needs to be arranged in advance in the cabling process, and the arrival of the cable is waited after the cable is started, so that unnecessary electric energy waste is caused.

Disclosure of Invention

In order to solve the defects and shortcomings in the prior art, the inventor provides a nondestructive cable applying and conveying device through research and development and design, can monitor the current operation parameters of the conveying device in each applying link, has a self-adaptive clamping force adjusting function, and realizes rapid, safe and nondestructive conveying of cables through monitoring of real-time state data and pressure data, and has the characteristics of equal height, constant speed and safety.

Specifically, the utility model is realized as follows: the device comprises a frame for mounting and supporting and symmetrically distributed power crawler devices arranged on the frame, wherein the two power crawler devices are arranged above the frame in a movable mode capable of adjusting the distance, are connected and arranged on a mounting frame through elastic components and two guide rods, can adaptively clamp a cable along the guide rods within the adjusting range of the elastic components according to the thickness of the passed cable, and can rotate along the same direction and speed to drive the cable to be conveyed forwards; the power track device comprises a conveying track for clamping the cable, the conveying track rotates under the driving of the driving motor, the driving force for forward conveying of the cable can be provided, the conveying sensor is arranged on the frame, whether the cable is in place or not can be detected, and the current lateral pressure data of the cable can be acquired and fed back to the master control module.

Further, the bottom of the power track device is arranged on the bottom plate, the driving motor and the gearbox are arranged at the bottom of the bottom plate, the gearbox is connected to the power track in a transmission mode, the bottom of the bottom plate is provided with a sliding block, the sliding block is sleeved on the two guide rods, the elastic component is transversely arranged between the sliding blocks of the two power track devices and is a spring piece, and the bottom plate can drive the respective power track devices to adaptively adjust the distance under the action of the spring piece.

Further, the two sliding blocks are also reversely provided with threaded holes respectively, an adjusting screw rod penetrates through the two threaded holes, a manual rocker is arranged at one side of the adjusting screw rod at the end, and the distance between the two power crawler devices can be manually adjusted under the rotation of the adjusting screw rods.

Further, be located the department of power crawler attachment's import one side, still be provided with a door type frame, a door type frame includes: two door posts arranged on the frame or the framework, and two transverse roller shafts are transversely arranged between the door posts, wherein two ends of the lower transverse roller shaft are arranged between the door posts in an elastic structure and can move up and down under the elastic structure; the lower part of the transverse roller shaft is also provided with a contact type micro switch, and a cable passes through the transverse roller shaft to press the lower part of the transverse roller shaft to move downwards, and is contacted with and triggered by the contact type micro switch.

Further, the contact type micro-movement switch comprises an elastic arm, the tail end of the elastic arm is connected with a micro-movement switch body, the micro-movement switch body is arranged on a door post, the other end of the elastic arm is provided with a contact roller, the contact roller can rotate along with the contact of the contact roller with a lower transverse roller shaft, and the elastic arm is not contacted with the lower transverse roller shaft in a normal state;

further, the door-shaped frame also comprises two vertical roll shafts which are vertically arranged, and the two vertical roll shafts are vertically arranged at two sides of the transverse roll shafts to form a cross beam of the door-shaped frame, and the two door-shaped frames are respectively arranged at an inlet and an outlet of the power track device; the door-shaped frame is provided with an inward photoelectric sensor which can monitor whether the cable is in place.

Further, a lateral pressure sensor is arranged between the inner sides of the tracks of each power track device and is in contact with the inner side surfaces of the tracks on one side of the clamping end, and the lateral pressure sensor is used for detecting lateral pressure data of the two power track devices on the clamping cable.

Further, the side pressure sensor is arranged on the inner side wall of the conveying track, the side pressure sensor is arranged on a fixed plate in the middle of the conveying track, the fixed plate is arranged on a bottom plate, the front end of the side pressure sensor is provided with a contact rod, the tail end of the contact rod is contacted with the side pressure sensor, and the other end of the contact rod is contacted with the inner side surface of the track through a contact roller. When the cable passes through, the conveyor tracks on two sides clamp the cable and provide conveying power, meanwhile, the contact roller is contacted with the cable through the belt, acting force generated by the contact roller is transmitted to the lateral pressure sensor, so that pressure data for laterally compacting the cable is obtained, the pressure data are fed back to the control terminal to monitor the cable, once the pressure value is overlarge, an alarm is given out, the machine is stopped, damage to the cable due to overlarge pressure is avoided, and the lateral pressure sensor is arranged singly or in a pair of opposite arrangement.

The working principle of the utility model is introduced: the conveyor is self-powered, the same-speed and same-direction operation of the double conveyor tracks is realized, the constant-speed synchronous transmission of the cables is realized by matching with the elastic components, the distance between the conveyor devices is provided with manual and self-adaptive double functions, the common various thick and thin cable arrangements can be met, the cables can be clamped under the pressure which the cables bear and power is supplied for conveying, the lateral pressure and the conveying speed which the cables bear can be detected by the conveyor devices in the process, the state monitoring of the cable conveying is realized, meanwhile, the conveyor devices are provided with the photoelectric sensor and the micro-motion mechanical sensor, the synchronous in-place transmission of the cables can be realized when the cables reach the conveyor devices, the conveyor devices which do not detect signals keep silent waiting, and modularized equipment is formed, so that the installation and arrangement of the equipment of the devices are concise and convenient, the structure of the conveyor devices is reduced, the conveyor devices can be stably placed and fixed in a horizontal and vertical mode, the door-type frame is arranged at the front and back of the inlet end of the conveyor devices, the conveyor devices can be slightly different in height or offset from left to right as far as possible, the cable is not damaged by the conveyor devices, the same line can be prevented from being damaged due to the fact that the conveyor devices can be laid down in a certain line, and the same speed can be prevented from being damaged, and the conveyor device can be simultaneously, and the skid-free from being caused by the conveyor device can be simultaneously, and the conveyor device can reach the line can reach the same speed.

The beneficial effects of the utility model are introduced as follows: the conveying device of the system has the function of multi-sensor detection, can determine that the cable is in place through the combination of the photoelectric sensor and the mechanical sensor, starts the conveying device, realizes synchronous constant-speed conveying, avoids unnecessary friction damage to the cable, has the function of adjustable interval, can adaptively meet the conveying of cables with various thickness and size, can acquire data of lateral pressure of the cable, realizes the speed and lateral pressure of monitoring the cable, can send out alarm, stop protection and the like if the lateral pressure is overlarge, can also receive the integral control of the controller, carries out overall adaptability control on the conveying speed, achieves uniform-speed conveying, and further improves the protection of the cable.

Drawings

FIG. 1 is a perspective view of the structure of the conveying device of the present utility model;

FIG. 2 is a bottom perspective view of the conveyor of the present utility model;

FIG. 3 is a structural perspective view of the door frame;

FIG. 4 is a schematic view of the structure of the door frame in which the transverse roller shaft is pressed down after contacting the cable;

FIG. 5 is a front elevational view of the side elevational structure of the conveyor of the present utility model;

FIG. 6 is a front view of a top plan view of the conveyor of the present utility model;

FIG. 7 is a top perspective view of the conveyor of the present utility model;

FIG. 8 is a schematic view showing the installation position of a side pressure sensor of the conveying device of the present utility model;

wherein:

411 door type frame, 412 horizontal roller, 420 contact type micro-action switch, 421 elastic arm, 422 micro-action switch body, 423 contact roller, 424 vertical roller shaft, 425 photoelectric induction sensor, 426 power track device, 427 frame, 428 guide rod, 429 conveying track, 430 side pressure sensor, 431 fixing plate, 432 contact rod, 434 gear box, 435 slide block, 436 adjusting screw, 437 manual rocker, 438 driving motor, 439 bottom plate, 440 spring element.

Detailed Description

The objects, technical solutions and advantages of the present utility model will become more apparent by the following detailed description of the present utility model with reference to the accompanying drawings. It should be understood that the description is only illustrative and is not intended to limit the scope of the utility model. In addition, in the following description, descriptions of well-known structures and techniques are omitted so as not to unnecessarily obscure the present utility model.

Example 1: the nondestructive cable applying and conveying device comprises a rack 427 for mounting and supporting and symmetrically distributed power crawler devices 426 arranged on the rack 427, wherein the two power crawler devices 426 are arranged above the rack 427 in a movable mode capable of adjusting the distance, the two power crawler devices 426 are connected and arranged on a mounting frame through elastic components and two guide rods 428, the two power crawler devices 426 can adaptively clamp cables along the guide rods 428 within the adjusting range of the elastic components according to the thickness of the passing cables, and the cables can be driven to be conveyed forwards by the rotation of the same-direction and same-speed crawler; the power track device 426 comprises a conveying track 429 for clamping the cable, the conveying track 429 rotates under the drive of the driving motor 438, the driving force for forward conveying of the cable can be provided, and the conveying sensor is arranged on the stand 427 and can detect whether the cable is in place or not and acquire current lateral pressure data of the cable and feed the lateral pressure data back to the master control module.

Specifically, the bottom of the power track device 426 is mounted on a base plate 439, a driving motor 438 and a gearbox 434 are mounted at the bottom of the base plate 439, the gearbox 434 is connected to the power track in a transmission mode, a sliding block 435 is arranged at the bottom of the base plate 439, the sliding block 435 is sleeved on two guide rods 428, an elastic component is transversely arranged between the sliding blocks 435 of the two power track devices 426, the elastic component is a spring member 440, the base plate 439 can drive the respective power track devices 426 to adaptively adjust the distance under the action of the spring member 440 between the guide rods 428, threaded holes are reversely formed in the two sliding blocks 435, an adjusting screw 436 penetrates through the two threaded holes, a manual rocker 437 is mounted at one side of the end head, and the distance between the two power track devices 426 can be manually adjusted under the rotation of the adjusting screw 436. In actual use, the conveying device is arranged and installed, then according to the specification of the cable applied at this time, the distance between the two power crawler devices 426 is manually adjusted in advance, the manual rocker 437 is manually rocked to drive the adjusting screw 436 to rotate, the threaded hole on the sliding block 435 drives the sliding block 435 and the bottom plate 439 to oppositely shorten the distance or reversely expand the distance to achieve a general preset effect, but the distance which is required to be manually adjusted is slightly smaller than the diameter of the cable. Before the cable passes, the power tracks are not started, the cable is started after reaching, and simultaneously the cable passes through the two power tracks to prop the two power tracks outwards a little, but under the action of the tension of the spring element 440, the two power tracks always have a tension which is extruded inwards in opposite directions, so that the two power tracks can clamp the cable to provide necessary clamping force, the cable can be self-adaptively clamped according to the specific situation of the thickness of the cable, the situation of slipping and idle running of the conveying device can be effectively prevented, and the cable is conveyed at the same speed, so that a key protection effect is achieved;

at the inlet side of the power crawler 426, a door frame 411 is further provided, and the door frame 411 includes: two door posts mounted on the frame 427 or the frame, and two horizontal roller shafts 412 are transversely mounted between the door posts, wherein both ends of the lower horizontal roller shaft 412 are mounted between the door posts in an elastic structure, and can be vertically displaced under the elastic structure; a contact type micro switch 420 is also arranged below the lower transverse roller shaft 412, and a cable passes through the transverse roller shaft 412, presses the lower transverse roller shaft 412 to move downwards, and contacts and triggers the contact type micro switch 420. The door frame 411 is mainly used for guiding an entrance into which a cable enters, and a cross bar which can be opened when necessary is arranged above the door frame. When the cable passes through the gate 411, the lower horizontal roller 412 contacts the cable first, after being pressed down by the weight of the cable, the elastic structure of the horizontal roller 412 is stretched after being pressed down, and the horizontal roller 412 contacts and presses down the contact type micro-switch 420, so that the switch signal is fed back, after the system obtains the signal, the cable is known to be in place, a signal for starting the power track is sent to the conveying device, and the power track is started. The contact type micro-switch 420 comprises an elastic arm 421, the tail end of the elastic arm 421 is connected with a micro-switch body 422, the micro-switch body 422 is arranged on a door post, the other end of the elastic arm 421 is provided with a contact roller, the contact roller can rotate along with the contact of the contact roller with the lower transverse roller shaft 412, and the elastic arm 421 is not contacted with the lower transverse roller shaft 412 in a normal state. The elastic structure is built-in springs, the built-in springs are arranged between door posts, when a cable passes through the lower transverse roller shaft 412, the cable is pressed to the lower transverse roller shaft 412 by self weight to enable the cable to move downwards under the stretching of the built-in springs, and the built-in springs are contacted with the contact type micro-switch 420 to send a mechanical induction signal that the cable is in place; a lateral pressure sensor 430 is also provided within the conveyor track 429 in contact with the inner side of the conveyor track 429 for detecting lateral pressure data of the conveyor track 429 against the cable.

Preferably, the door-shaped frame 411 further includes two vertical roller shafts 424 vertically disposed on two sides of the horizontal roller shaft 412 to form a beam of the door-shaped frame 411, and the door-shaped frame 411 is two parts, each of which is disposed at an inlet and an outlet of the power crawler 426; the door-shaped frame 411 is provided with the inward photoelectric sensing sensor 425, so that whether the cable is in place or not can be monitored, namely, the door-shaped frame 411 is surrounded by the vertical roller shaft 424 and the horizontal roller shaft 412 to form a frame-shaped structure, the cable can be guided to rectify from multiple directions, the cable can enter the conveying device in the normal position as far as possible, meanwhile, the cable can further rotate along with the conveying of the cable, the friction force to the outer surface of the cable is reduced, scratch and collision to the outer layer of the cable are avoided, and the protection effect of nondestructive conveying is achieved. The photo-sensor 425 may also be used as a detection signal sensor for detecting whether a cable is arriving.

Preferably, a lateral pressure sensor 430 is further arranged between the inner sides of the tracks of each power track device 426 and is contacted with the inner sides of the tracks on one side of the clamping ends, and the lateral pressure sensor 430 is used for detecting lateral pressure data of the two power track devices 426 on the clamping cables; the lateral pressure sensor 430 is arranged on the inner side wall of the conveying crawler 429, the lateral pressure sensor is arranged on a fixed plate 431 in the middle of the conveying crawler 429, the fixed plate 431 is arranged on a base plate 439, the front end of the lateral pressure sensor is provided with a contact rod 432, the tail end of the contact rod 432 is contacted with the lateral pressure sensor, and the other end of the contact rod 432 is contacted with the inner side surface of the crawler through a contact roller 423. When the cable passes through, the conveying tracks 429 on two sides clamp the cable and provide conveying power, meanwhile, the contact roller 423 is contacted with the cable through a belt, acting force generated by the contact roller is transmitted to the lateral pressure sensor, so that pressure data for laterally compacting the cable is obtained, the pressure data are fed back to the control terminal to monitor the cable, once the pressure value is overlarge, an alarm is given and the cable is stopped, damage to the cable due to overlarge pressure is avoided, and the lateral pressure sensor 430 is arranged singly or in a pair of opposite positions.

The lateral pressure sensor 430 is arranged on the inner side wall of the conveying crawler 429, the lateral pressure sensor is arranged on a fixed plate 431 in the middle of the conveying crawler 429, the fixed plate 431 is connected with a side plate of the conveying crawler 429, a contact rod 432 is arranged at the front end of the lateral pressure sensor, the tail end of the contact rod 432 is contacted with the lateral pressure sensor, the other end of the contact rod is contacted with the inner side surface of the belt through a contact roller 423, when a cable passes through, the conveying crawler 429 on two sides clamps the cable and provides conveying power, meanwhile, the contact roller 423 is contacted with the cable through the belt, the acting force generated by the contact roller is transmitted to the lateral pressure sensor, so that the lateral pressure data of the cable is obtained, fed back to a control terminal to monitor the cable, and once the pressure value is too large, an alarm is given and the cable is stopped, so that the damage condition that the cable is possibly generated due to the too large pressure is avoided, and the lateral pressure sensor 430 is arranged singly or in a pair of opposite arrangement.

It is to be understood that the above-described embodiments of the present utility model are merely illustrative of or explanation of the principles of the present utility model and are in no way limiting of the utility model. Accordingly, any modification, equivalent replacement, improvement, etc. made without departing from the spirit and scope of the present utility model should be included in the scope of the present utility model. Furthermore, the appended claims are intended to cover all such changes and modifications that fall within the scope and boundary of the appended claims, or equivalents of such scope and boundary.

Claims

1. A nondestructive cable applying and conveying device is provided with a frame for mounting and supporting and symmetrically distributed power caterpillar devices mounted on the frame, and is characterized in that,

the two power crawler devices are arranged above the frame in a movable mode capable of adjusting the distance, are connected and arranged on the mounting frame through the elastic component and the two guide rods, can adaptively clamp the cable along the guide rods within the adjusting range of the elastic component according to the thickness of the passed cable, and can rotate with the same direction and speed to drive the cable to be conveyed forwards;

the power track device comprises a conveying track for clamping the cable, the conveying track rotates under the drive of a driving motor and can provide driving force for forward conveying of the cable,

the conveying sensor is arranged on the rack, and can detect whether the cable is in place or not, acquire the current lateral pressure data of the cable and feed back the lateral pressure data to the master control module.

2. The nondestructive cable applying and conveying device according to claim 1, wherein the bottom of the power track device is arranged on a bottom plate, a driving motor and a gearbox are arranged at the bottom of the bottom plate, the gearbox is connected to the power track in a transmission mode, a sliding block is arranged on the bottom of the bottom plate and sleeved on two guide rods, an elastic part is transversely arranged between the sliding blocks of the two power track devices, the elastic part is a spring part, and the bottom plate can drive the respective power track devices to adaptively adjust the distance between the guide rods under the action of the spring part.

3. The non-destructive cable dispensing and conveying device according to claim 2, wherein the two sliding blocks are further provided with threaded holes in opposite directions, an adjusting screw rod penetrates through the two threaded holes, a manual rocker is arranged at one side at the end, and the two power caterpillar devices can manually adjust the distance under the rotation of the adjusting screw rods.

4. A non-destructive cable dispensing delivery device according to claim 2 or 3, wherein a gate is provided at the inlet side of the power track device, the gate comprising: two door posts arranged on the frame or the framework, and two transverse roller shafts are transversely arranged between the door posts, wherein two ends of the lower transverse roller shaft are arranged between the door posts in an elastic structure and can move up and down under the elastic structure; the lower part of the transverse roller shaft is also provided with a contact type micro switch, and a cable passes through the transverse roller shaft to press the lower part of the transverse roller shaft to move downwards, and is contacted with and triggered by the contact type micro switch.

5. The nondestructive cable applying and conveying device according to claim 4, wherein the contact type micro switch comprises an elastic arm, the tail end of the elastic arm is connected with a micro switch body, the micro switch body is arranged on a door post, the other end of the elastic arm is provided with a contact roller, the contact roller can rotate in a follow-up manner after being contacted with a lower transverse roller shaft, and the elastic arm is not contacted with the lower transverse roller shaft in a normal state.

6. The nondestructive cable application and conveying device according to claim 5, wherein the door-shaped frame further comprises two vertical roll shafts which are vertically arranged, and the two vertical roll shafts are vertically arranged on two sides of the transverse roll shafts to form a transverse beam of the door-shaped frame, and the two door-shaped frames are respectively arranged at an inlet and an outlet of the power caterpillar device; the door-shaped frame is provided with an inward photoelectric sensor which can monitor whether the cable is in place.

7. The non-destructive cable dispensing and conveying device according to claim 1, wherein a lateral pressure sensor is further arranged between the inner sides of the tracks of each power track device and is in contact with the inner sides of the tracks on one side of the clamping end, and the lateral pressure sensor is used for detecting lateral pressure data of the two power track devices on the clamping cable.

8. The nondestructive cable applying and conveying device according to claim 7, wherein the lateral pressure sensor is arranged on the inner side wall of the conveying track, the lateral pressure sensor is arranged on a fixed plate in the middle of the conveying track, the fixed plate is arranged on a bottom plate, the front end of the lateral pressure sensor is provided with a contact rod, the tail end of the contact rod is contacted with the lateral pressure sensor, and the other end of the contact rod is contacted with the inner side surface of the track through a contact roller.