CN215696721U - Remanufacturing-oriented bicycle disassembling robot system - Google Patents

Abstract

The utility model provides a remanufacturing-oriented bicycle disassembling robot system, which comprises: the device comprises a transportation device, an identification positioning device and a dismounting device; the transportation device receives a transportation control command and transports the bicycle to be disassembled to the disassembling device; the identification positioning device identifies the bicycles transported to the dismounting device, and screens and positions information of parts to be dismounted; and the dismounting device is used for dismounting the bicycle according to the positioned information of the part to be dismounted. The embodiment utilizes the computer to identify and position each position of waiting to dismantle parts on the bicycle, and the dismounting device is recycled to dismount the bicycle according to the positioned positions of the dismounting parts, so that the automatic dismounting of the bicycle is realized, the dismounted available resources are recycled, and unnecessary resource waste is avoided.

Description

Remanufacturing-oriented bicycle disassembling robot system

Technical Field

The utility model relates to the technical field of dismounting devices, in particular to a remanufacturing-oriented bicycle disassembling robot system.

Background

The sharing bicycle has the characteristics of high degree of freedom, low price, low carbon, environmental protection and the like, and is favored by young people due to high use frequency. Compared with the traditional bicycle leasing, the shared bicycle can be parked and moved in most areas because the shared bicycle does not need to be parked on a special parking pile, and the use freedom degree is higher; secondly, the price of the shared bicycle at the present stage is more advantageous than that of a few yuan under the traditional lease, even dozens of yuan in scenic spots; in addition, the sharing bicycle is responding to the current low-carbon, environment-friendly and green trip trend. The characteristics enable the shared bicycle to hopefully meet daily high-frequency use requirements and become a new travel fashion for young people. In order to solve the problem that the old shared bicycle is randomly stopped and randomly placed, the community costs funds to manually recycle the old shared bicycle around every year, and through investigation, the old shared bicycle is taken as waste product after violence disassembly, so that great resource waste is caused, and the requirement of resource recycling is not met.

Therefore, the prior art is subject to further improvement.

SUMMERY OF THE UTILITY MODEL

In view of the defects in the prior art, the utility model aims to provide a bicycle disassembling robot system for remanufacturing, which overcomes the defect of resource waste caused by violence disassembling of a waste shared bicycle in the prior art.

The embodiment of the utility model discloses the following scheme:

first aspect, this embodiment discloses a robot system is disassembled to bicycle towards refabrication, wherein, includes: the device comprises a transportation device, an identification positioning device and a dismounting device; the transportation device is connected with the dismounting device, and the identification positioning device is in communication connection with the dismounting device;

the transportation device is used for receiving a transportation control command and transporting the bicycle to be disassembled to the disassembling device;

the identification positioning device is used for identifying the bicycles transported to the dismounting device and screening and positioning information of the parts to be dismounted; wherein the to-be-detached component information includes: the type of the detachable member and the positional coordinate information of the detachable member;

the dismounting device is used for dismounting the bicycle according to the positioned information of the part to be dismounted

The utility model has the beneficial effects that the utility model provides a bicycle disassembly robot system facing remanufacturing, which comprises: the device comprises a transportation device, an identification positioning device and a dismounting device; the transportation device receives a transportation control command and transports the bicycle to be disassembled to the disassembling device; the identification positioning device identifies the bicycles transported to the dismounting device, and screens and positions information of parts to be dismounted; and the dismounting device is used for dismounting the bicycle according to the positioned information of the part to be dismounted. The embodiment utilizes the computer to identify and position each position of waiting to dismantle parts on the bicycle, and the dismounting device is recycled to dismount the bicycle according to the positioned positions of the dismounting parts, so that the automatic dismounting of the bicycle is realized, the dismounted available resources are recycled, and unnecessary resource waste is avoided.

Drawings

FIG. 1 is a schematic block diagram of a remanufacturing-oriented bicycle disassembly robot system provided by an embodiment of the present invention;

FIG. 2 is a schematic diagram of a bicycle disassembly robot system according to an embodiment of the present invention;

FIG. 3 is a flowchart illustrating steps of an embodiment of a method for implementing the bicycle disassembling robot system;

FIG. 4 is a schematic view showing the structure of the detaching device in the present embodiment;

FIG. 5 is a schematic view showing the construction of the frame of the dismounting device in this embodiment;

FIG. 6 is a first partial schematic view of the detaching device in the present embodiment;

FIG. 7 is a second partial schematic view of the detaching device in the present embodiment;

FIG. 8 is a schematic structural view of the bicycle to be disassembled being fixed to the disassembling device in this embodiment;

FIG. 9 is a schematic diagram illustrating the principle of identifying and locating the detachment position in the image according to the present embodiment;

fig. 10 is a schematic diagram illustrating the conversion of recognized positional information into spatial positional information in the present embodiment;

FIG. 11 is a diagram showing a hardware configuration of the system according to the present embodiment;

fig. 12 is a functional block diagram of an implementation method of a remanufacturing-oriented bicycle disassembling robot system according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer and clearer, the present invention is further described in detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

As used herein, the singular forms "a", "an", "the" and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. It will be understood that when an element is referred to as being "connected" or "coupled" to another element, it can be directly connected or coupled to the other element or intervening elements may also be present. Further, "connected" or "coupled" as used herein may include wirelessly connected or wirelessly coupled. As used herein, the term "and/or" includes all or any element and all combinations of one or more of the associated listed items.

It will be understood by those skilled in the art that, unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the prior art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

Since the birth of the sharing bicycle, after the sharing bicycle has the initial input amount, the turnover needs to be improved on the premise of total amount control. There is a need for cycle-based and life-cycle management-based innovations in bicycle technology, including the selection of durable and recyclable materials during design, enhanced maintenance during operation to increase the utilization of the bicycle, and classification for recycling and recycling when scrapped. Through the primary dismantling processes, the scrapped bicycle is finally subdivided into iron, aluminum, plastic and the like. After subdivision, metal materials such as the main body frame and the like are uniformly returned to the furnace to be made into metal ingots or metal products for recycling; the aluminum is made into aluminum ingots, and can be used for high-end aluminum products, aluminum alloy doors and windows, common aluminum products and the like according to different grades; the plastic of the car body can be processed into plastic particles for recycling, such as a plastic washbasin, an automobile interior trim and the like; the parts such as tires and cushions which cannot be completely decomposed are subjected to scientific harmless treatment.

In the embodiment, each part of the shared bicycle is automatically disassembled, and the shared bicycle is effectively classified and identified, so that useful parts are recycled; and recovering the failed parts by adopting the modes of crushing or smelting and the like.

Specifically, this embodiment provides a robot system is disassembled to bicycle towards refabrication, and this system has degree of automation height, utilizes machine identification, functions such as degree of depth study, can realize dismantling scrapping sharing bicycle is automatic, and sorts integratively. Its main functions include: (1) the waste bicycles can be fixed in the disassembly production line; (2) the nut position needing to be disassembled is identified by the image identification and positioning function; (3) through the recovery of each divided area, the classified recovery of the worn shared bicycle is realized. The system provided by the embodiment is used for recycling, disassembling and remanufacturing the shared bicycle, and sustainable use of resources is realized.

The disclosed system is explained in more detail below with reference to the drawings.

The utility model provides a remanufacturing-oriented bicycle disassembling robot system, as shown in fig. 1, comprising: the conveying device 110, the identification positioning device 120 and the dismounting device 130. The transportation device 100 is connected with a dismounting device 130, and the identification positioning device 120 is in communication connection with the dismounting device 130;

the conveying device 110 includes: and the conveying belt is used for conveying the bicycles to be disassembled into the disassembling device.

The identification and positioning device 120 includes: a the industrial camera for gathering the bicycle image, be used for handling the bicycle image of gathering, discern the location to each dismantlement part on the bicycle to the position that will discern each dismantlement part of location changes spatial position information into, with spatial position information propelling movement to dismounting device.

The detaching device 130 includes: the frame (as shown in fig. 5), the detaching robot that sets up on the frame, it is specific the detaching robot is the triaxial arm that utilizes the mounting panel to fix on the frame, and every arm of triaxial arm all corresponds and sets up a motor, and each motor drive moves rather than the arm that is connected. The mechanical arm performs the disassembling operation of the bicycle under the control.

The transporting device is used for transporting each bicycle to be disassembled to the disassembling device in sequence, so that the transporting device and the disassembling device are connected when in use. In one embodiment, the transport device may in particular use a conveyor belt, by means of which the bicycles are conveyed to the dismounting device, it being conceivable that the transport device can also be realized in other ways, as long as the bicycles are smoothly conveyed to the dismounting device, such as: the sequential delivery of the bicycles is realized by using a transport vehicle or a transport rail and the like.

The identifying and positioning device in the embodiment comprises: industrial camera, intelligent terminal and switch board. The picture of the bicycle fixed to the dismounting device is gathered to the industry camera to the bicycle picture that will gather is sent to intelligent terminal.

In combination with the control schematic diagram of the bicycle disassembly shown in fig. 2, the intelligent terminal can be a PC terminal, the PC terminal performs image recognition and spatial positioning on each disassembly part on the bicycle through an image recognition algorithm, converts position information of each disassembly part in the positioned image into spatial position information, realizes conversion from a two-dimensional coordinate to a three-dimensional spatial coordinate, and sends the three-dimensional spatial coordinate obtained through conversion to the industrial robot through the router. The industrial robot carries out motion control on the disassembling robot according to the received three-dimensional space coordinate, the disassembling robot carries out a disassembling task of a bicycle, meanwhile, a sensor carries out data acquisition on the bicycle during disassembly, an industrial camera carries out image acquisition and transmits acquired image data and acquired data in the sensor to a PC (personal computer) end, and the PC end carries out real-time monitoring on the disassembling condition of the bicycle.

Further, the system disclosed in this embodiment is further described with reference to fig. 3.

When the automatic bicycle disassembly is performed, initialization is performed on each device to ensure the accuracy of acquired data.

The method comprises the steps that an industrial camera, namely a vision module, collects images of a bicycle and transmits the collected images to a PC (personal computer) terminal, the PC terminal judges whether the images of the bicycle are received or not, if the images are not obtained, the industrial camera is controlled to obtain the images again, the obtained images are transmitted to the PC terminal, if the images are obtained, whether a network model is obtained or not is judged, if the network model is obtained, the obtained network model is used for carrying out target identification and positioning on the images, and the type of an object to be disassembled and two-dimensional coordinates of the target in the images are output. If the network model is not obtained, retraining to obtain the network model, wherein the step of training the network model comprises the following steps: and making a data set used by the training network model, training the target detection network model by using the training data set to obtain an optimal detection network model, and identifying and positioning the target image in the image on the received image by using the network model obtained by training.

After the initialization of the space positioning module is completed, the camera needs to be calibrated, the hand and the eye of the disassembling robot need to be calibrated, whether the received identification and positioning information of the image is received or not is judged, and if the identification and positioning information is received, the two-dimensional identification and positioning information is converted into space coordinate values of all parts of the bicycle to be disassembled and output to the execution module of the industrial robot.

And the execution module of the industrial robot receives the space coordinate values of all parts of the bicycle to be disassembled, and controls the mechanical claw to move to a specified target disassembling part to perform disassembling operation according to the received space coordinate values. And after the disassembly of all the disassembly parts is sequentially carried out in the disassembly process, the disassembly robot is restored to the initial position.

The detaching device of the present embodiment shown in fig. 4 to 8 includes: the robot comprises a frame, a single-shaft robot, a motor for driving the single-shaft robot to move, a chain for conveying the robot to move up and down, left and right, and the like. Wherein the chain of the up-and-down side-to-side motion of the conveying robot is fixed on the frame, and the chains of the single-shaft robot are respectively arranged on two sides in the frame. Specifically, the present embodiment employs a three-axis robot arm. The dismounting device comprises: and the disassembling robot 18 is fixed on the frame 11 and is correspondingly arranged left and right. The frame is provided with fixing members such as a mounting plate 14 and a fixing plate 15 for fixing the robot mounted on the frame, and a bracket 16. The frame is provided with a left chain, a right chain (a left chain 13 and a right chain 12) and a linear rail 17, so that the position of the machine can be adjusted on three axes conveniently. Each shaft is provided with a caterpillar linear motor 21. The end is a drill bit. Different drill bits can be replaced, and the operation of screws at different positions is realized. When the triaxial apparatus reaches the screw that needs to be dismantled, the drill bit is rotated, the screw will loosen, and then cause the part of this part to drop.

Referring to fig. 9, when the PC upper computer acquires a training set, the training set is input to the server, so that the server trains a preset network model according to the training set. The server receives an input training set image, inputs a bicycle picture in the training set as an input item into a pre-stored preset network model, and then acquires information of a part to be disassembled corresponding to the bicycle picture output by the pre-stored network model.

In one embodiment, in this step, a preset network model is created first, a training set is constructed, the constructed preset network model is trained by using the training set, the network model sequentially identifies and positions images to construct the training set, then a preset network model structure is constructed, the training set is used to train the preset network model, the network model is optimally trained according to the output result of the network model to obtain an optimal network model, finally, the parameters of the network model are determined, and the type and coordinates of a workpiece in an input image are determined according to the trained network model. And the PC upper computer software calculates the coordinates of the grabbing central point of the robot according to the determined workpiece type and the determined coordinates, sequentially selects the disassembly parts, and controls the disassembly robot to execute corresponding disassembly operation according to each position information of the to-be-disassembled parts, wherein the position information of the to-be-disassembled parts comprises the type information of the to-be-disassembled layout and the position coordinate information of the to-be-disassembled parts.

The system presented in this embodiment is explained in more detail further below with reference to fig. 1-11.

The bicycle disassembling robot system for remanufacturing provided by the embodiment is composed of a hardware part and a software part, is mainly divided into four parts, namely a conveying device, an image recognition positioning device, a space positioning device and a disassembling device.

Specifically, the conveying device comprises a conveyor belt. The image recognition positioning device comprises: industrial cameras, robot control cabinets and PCs. The waste bicycles are sequentially sent into a disassembling device by a conveyor belt to be directly disassembled. The industrial camera is used as the eyes of the industrial robot to observe the environment of the dismounting device and an object to be dismounted (namely, a bicycle to be dismounted), and acquires the acquired picture of the bicycle to be dismounted and transmits the picture to the PC terminal. The PC computer end is used for processing the picture information, and determining the structural composition of the object to be disassembled and the position information in the image, thereby setting the disassembling step and completing the transformation from the vision coordinates of the robot to the coordinates of the tail end point of the robot. Finally, the industrial robot is guided to complete the disassembling task through communication with the robot control cabinet.

Referring to fig. 3 to 11, the system of the present embodiment is mainly applied to disassemble a bicycle.

The system that this embodiment provided, at first with the automatic production line of placing of bicycle (the production line is including transporting the bicycle, discernment location out the dismantlement position and dismantle the bicycle according to the dismantlement position that discernment location), the dismantlement robot utilizes its arm to fix the bicycle in the frame. The three-axis mechanical arms respectively arranged at the left side and the right side in the frame fix the bicycle. In order to identify and locate the position of the disassembled component, the system of the embodiment is provided with an identification system, which comprises a camera, a radar, an ultrasonic sensor and the like, and identifies the position of the disassembled component, such as a nut and the like. Then, the corresponding dismounting terminal is installed by using the mechanical arm, the terminal is moved to the dismounting position, and the nut is dismounted by rotating the terminal. At this point, the bicycle parts will be scattered onto the conveyor belt.

In addition, in the disassembling process, the system provided by the embodiment disassembles according to the sequence, so that after each part is disassembled, the conveyor belt can convey the part out, the identification process after disassembly is simplified, and the classification problem after disassembly is realized.

The image acquisition module is mainly responsible for acquiring image information and displaying the image information in a source image window. The image acquisition mainly comprises two stages, wherein the first stage is a data set manufacturing stage, the relative positions of a camera and a workpiece need to be changed, different types of workpiece images are continuously acquired, and then all picture data are stored and manufactured into an industrial data set; the second stage is a detection stage, and the single frame is used for acquiring the pictures of the waste products appearing in the visual area of the camera so as to perform the identification and positioning processing of the image target.

The required picture form is obtained by setting the shooting mode and the picture size of the industrial camera. The data pictures under different industrial background environments are simulated through different illumination, light and shade, distance and image resolution, and the robustness of picture data is enhanced.

The identification and positioning device is one of core modules of the system and mainly comprises the steps of identifying the category and positioning the position of all target components in an image. The whole module can be divided into three major parts: firstly, constructing a network model, including a basic convolutional neural network and a connected regression classification network; secondly, training the network, including obtaining weight parameters of each layer and converging loss values; and thirdly, a target detection part, namely a final test part of the network. Inputting a picture which never appears, identifying and positioning a target object contained in the picture, finally outputting the categories of all target components in the picture and the corresponding picture coordinates thereof, and integrating the detection result into upper computer software.

As shown in fig. 9, when the trained model is used for detection, the upper computer detects the acquired image to obtain the detected target type and position information. For all components identified, a "select" button may be clicked on to select the component to be removed in the result area. And the background program calculates and selects the minimum external matrix of the identified part, namely selects the maximum and minimum horizontal and vertical coordinates as a boundary frame to obtain the central position of the selected part. Clicking a positioning button, jumping to a space positioning module interface by a page, and simultaneously completing the conversion of the central position coordinate from a two-dimensional space coordinate to a three-dimensional space coordinate.

The industrial robot converts two-dimensional image coordinates into world coordinates in a three-dimensional space through a space positioning module, and the process mainly involves two parts: firstly, calibrating a camera, and completing the conversion from image coordinates to world coordinates by taking the camera as a reference object; and secondly, calibrating the hands and eyes of the robot, and completing the conversion from a camera coordinate system to a robot tail end point coordinate system by taking a robot base as a basic coordinate system.

Fig. 10 is a schematic diagram illustrating the calibration process of unknown parameters of the circular target template to the industrial camera. Firstly, after an initial station is input, calibrating camera parameters according to the input initial station, then sequentially identifying the outline of a circular target, establishing central position points of all circular targets and calibrating the camera parameters and distortion parameters, thereby realizing space vision calibration, then carrying out manual calibration of robot eyes based on the space vision calibration, and inputting the acquired actual image type position information into an upper computer, and displaying the type position information by the upper computer through software.

Fig. 11 shows a running interface in a robot programming execution module, which shows the movement process of the robot between two points in space. And in the moving process of the robot, the controller also feeds back the real-time pose to the upper computer for visual display, so that data exchange between the two parties is realized, and the grabbing and monitoring operation in the disassembling process is completed.

On the basis of providing the remanufacturing-oriented bicycle disassembling robot system, the embodiment provides an implementation method of the remanufacturing-oriented bicycle disassembling robot system, as shown in fig. 12, including:

step S1, the transportation device receives the transportation control command and transports the bicycle to be disassembled to the disassembling device;

step S2, the identification and positioning device identifies the bicycles transported to the dismounting device, and screens and positions information of parts to be dismounted; wherein the to-be-detached component information includes: the type of the detachable member and the positional coordinate information of the detachable member;

and step S3, the dismounting device is used for dismounting the bicycle according to the positioned information of the part to be dismounted.

The control cabinet sends a control command to the detaching device according to the spatial position information of each detaching component obtained in the above step S2, and the detaching robot of the detaching device performs a desired detaching operation.

Specifically, a chain which is convenient for posture adjustment is further connected with the detaching robot, the detaching robot adjusts the posture to a target position under the driving of the chain, and corresponding detaching operation is executed. In order to realize the posture adjustment of three shafts in different directions, at least one pair of opposite disassembling robots are arranged on the frame and used for mutually matching to realize the disassembly of the bicycle.

The transportation device comprises a conveyor belt, and the identification and positioning device comprises: the system comprises an intelligent terminal and an image acquisition device; the detaching device includes: a frame and at least one pair of demolition robots arranged on the frame.

The step that discernment positioner discerns the bicycle of transporting to dismounting device, the part information is treated in screening location includes:

step S21, acquiring an image of the bicycle; in the step, the images of the bicycle to be disassembled can be collected in multiple directions, so that the disassembly parts can be accurately identified and positioned.

And step S22, recognizing the parts to be disassembled on the bicycle image, and positioning the position information of the parts to be disassembled.

The positions of the detachable components are identified by an image identification method, the detachable components are classified, and the discarded components and the reusable components are classified.

In order to realize better recognition of the image, the features contained in the image are processed by a deep learning method in the step, so that each feature of the image is accurately recognized.

Specifically, the identification and positioning device identifies the bicycle transported to the dismounting device, and before the step of screening and positioning the information of the part to be dismounted, the identification and positioning device further comprises:

the method comprises the steps that a preset network model generates information of a predicted part to be disassembled corresponding to a bicycle picture according to the bicycle picture in a training set, wherein the training set comprises a plurality of groups of training samples, and each group of training samples comprises the bicycle picture and the information of the part to be disassembled corresponding to the bicycle picture;

and the preset network model corrects model parameters according to the information of the part to be disassembled in the prediction mode corresponding to the bicycle picture and the information of the part to be disassembled corresponding to the bicycle picture, and continues to execute the step of generating the information of the part to be disassembled in the prediction mode corresponding to the bicycle picture according to the bicycle picture concentrated in the training mode until the training condition of the preset network model meets the preset condition so as to obtain the identification model of the position to be disassembled.

Further, the step of identifying the bicycle transported to the dismounting device by the identification and positioning device and screening and positioning the information of the part to be dismounted comprises the following steps:

and step S23, converting the position information of the part to be disassembled positioned in the bicycle image into the space position information of the bicycle part.

Since the identification and positioning are performed based on the image, the position information of each component to be disassembled in the image is obtained, and if the bicycle installed in the disassembling device is disassembled, the two-dimensional position information in the image needs to be converted into the position coordinates of the bicycle currently in the space.

And step S24, pushing the converted spatial position information to a dismounting device.

In order to detach the bicycle by using the detaching device, the bicycle needs to be detached by using the converted spatial position information, so that the converted spatial position information needs to be pushed to the detaching device, and the detaching device performs corresponding detaching operation according to the received spatial position information.

Further, the step of disassembling the bicycle by the disassembling device according to the information of the positioned component to be disassembled comprises the following steps:

sequentially positioning the disassembled parts of the bicycle according to the information of the parts to be disassembled;

and sequentially disassembling according to the position of each positioned disassembling component.

The detaching device includes: the step of sequentially disassembling according to the positioned positions of the disassembling parts comprises the following steps:

the disassembling robot receives the position information of each disassembling part;

determining each operation state information of disassembly according to the position information of each disassembly part; wherein the operation state information includes: the position and the rotation angle of the grabbing;

and disassembling the disassembling parts according to the preset disassembling sequence according to the operating state information.

The utility model provides a remanufacturing-oriented bicycle disassembling robot system, which comprises: the device comprises a transportation device, an identification positioning device and a dismounting device; the transportation device receives a transportation control command and transports the bicycle to be disassembled to the disassembling device; the identification positioning device identifies the bicycles transported to the dismounting device, and screens and positions information of parts to be dismounted; and the dismounting device is used for dismounting the bicycle according to the positioned information of the part to be dismounted. The embodiment utilizes the computer to identify and position each position of waiting to dismantle parts on the bicycle, and the dismounting device is recycled to dismount the bicycle according to the positioned positions of the dismounting parts, so that the automatic dismounting of the bicycle is realized, the dismounted available resources are recycled, and unnecessary resource waste is avoided.

It should be understood that the technical solutions and the inventive concepts according to the present invention may be equally replaced or changed by those skilled in the art, and all such changes or substitutions should fall within the protection scope of the appended claims.

Claims (7)

1. The utility model provides a robot system is disassembled to bicycle towards refabrication which characterized in that includes: the device comprises a transportation device, an identification positioning device and a dismounting device; the transportation device is connected with the dismounting device, and the identification positioning device is in communication connection with the dismounting device;

the transportation device is used for receiving a transportation control command and transporting the bicycle to be disassembled to the disassembling device;

the identification positioning device is used for identifying the bicycles transported to the dismounting device and screening and positioning information of the parts to be dismounted; wherein the to-be-detached component information includes: the type of the detachable member and the positional coordinate information of the detachable member;

and the dismounting device is used for dismounting the bicycle according to the positioned information of the part to be dismounted.

2. The bicycle dismantling robot system according to claim 1, wherein the transporting means includes a conveyor belt, and the identifying and positioning means includes: intelligent terminal, switch board and image acquisition device.

3. The bicycle dismantling robot system according to claim 2, wherein said dismantling device includes: the bicycle disassembling device comprises a frame and at least one pair of disassembling robots arranged on the frame, wherein the disassembling robots are used for receiving control commands and disassembling the bicycle.

4. The bicycle disassembling robot system according to claim 3, wherein the intelligent terminal is configured to identify and position each disassembling component included in the bicycle to be disassembled, which is acquired by the image acquisition device, and send the positioned position information to the control cabinet;

and the control cabinet is used for controlling the disassembling robot to execute corresponding disassembling operation according to the received position information.

5. The bicycle dismantling robot system according to claim 3, wherein said dismantling robot is a three-axis robot arm fixed to a frame by means of a mounting plate, and each of said three-axis robot arms is provided with a motor; each motor is used for driving the three-axis mechanical arm connected with the motor to move.

6. The bicycle disassembling robot system according to claim 5, wherein the frame is further provided with left and right symmetric chains; and the left chain and the right chain are used for conveying the three-axis mechanical arm to move up and down, left and right.

7. The bicycle disassembling robot system according to claim 5, wherein the intelligent terminal is a PC computer terminal.

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