UA116009U - WORKS FOR VISUAL AND OPTICAL INSPECTION OF THE PIPELINE WITH DETERMINATION OF GAS - Google Patents

Abstract

The robot for visual-optical inspection of the pipeline to determine the presence of gases includes a wheelchair, a sealed video camera to determine the direction of movement, a sealed video camera to inspect the inner surface of the pipeline in the transverse plane, data reception-reception unit, data transmission-reception unit orthogonal axis of the pipeline, lighting equipment, power supply. The wheelchair additionally includes gas sensors, an accelerometer, a wheel speed control unit and a pipe slope device. The data from the joystick is transmitted to the wheel speed control unit, due to which the specified direction of movement of the wheelchair is maintained and the drive rotates the video camera in a plane orthogonal to the axis of the pipeline. Tablet computer or smartphone with GPS module determines the geographical coordinates of wells at the beginning and end of the pipeline, displays and captures in memory images from the direction camera and viewing camera with information about the presence of gases, acceleration, length of wheel travel trolleys and the slope of the pipeline and automatically indicates the location of the pipeline on the map of the area with damage. The cable with the cable is placed on the spool for laying the cable with the cable.

Description

The utility model belongs to devices that are guided in pipes by means of actuators mounted on trolleys, and can be used for teleinspection of the internal surface of the pipeline to determine the presence of gases and can be used to verify liquid meters in various industries and utilities.

Currently, robots are used for teleinspection of pipes in the form of carts, which are equipped with one camera and are controlled from the operator's console by cable (Controlled teleinspection robot bieegarie rire hapdeg-pEr:/Lymly.2-ies.gy/Ipdeh/saiaiyudie/vpomyet.ryr? -416)

Iabogayugtua/hobroi-aIua-ieIeipzrekivii-yyib-ipuepiog-ipdivigev-yK.Ati). (Robot for teleinspection of the pipeline T 66-pyr://taviepooiv5-rgo.gy/mteNK/torbi!-paua-ieiIeipzrekivsioppaua-Iabogayutiua/go-roi-aIua-ieIeipzrekivsii-ipgyrorgomoda-1-66.piIti).

The advantage of these devices is the possibility of controlling the robot and carrying out teleinspection when the operator and recording equipment are located outside the pipeline.

The disadvantages of these devices are: insufficient quality of visualization of large diameters of inspected pipelines due to the use of one camera; low accuracy of determining the location of the defect in the pipeline wall, due to the fact that one camera simultaneously performs an inspection of the course of movement and an inspection of the pipeline wall, the device can be used only in an empty pipeline, it is not possible to automatically mark the pipeline on the map of the area, the presence of gases in the pipeline is not determined.

There is also a well-known method of on-the-road inspection and diagnosis of non-working main pipelines and a system for its implementation (patent of the Russian Federation for an invention Mo 2216685, date of publication 20.11.2003, Bul. Mo 32), which consists in teleinspection of the inspected object, while introducing into the pipeline moisture-proof, capable of withstanding pressure up to 25 atm., a video camera of the type МВ21С0-НЗб or КРО-1905М/ in a sealed titanium case with a viewing angle of 92 degrees, protected by polished glass of the KV type with a thickness of 15 mm and a bending strength of about 17.0 MPa, equipped with halogen lamps, installed on a horizontal platform made of softwood bars soaked in boiling industrial oil, at a distance of 5-15 cm from the front edge along its center line, and the platform has a thickness of 80 mm, and the ratio of length to width is 3: 11, and its volume has

From the ratio to the diameter of the pipeline as 1:14, the platform moves on four wheels, the front two of which are bladed, powered by an electric motor, and the rear two are supporting, and behind the platform moves a three-wire power cable connected to a video camera, which has double insulation and provides communication with a terrestrial recording digital video camera of the type YuOSV-TAM 17E bop with a 3.5-inch monitor or similar, and the information received by the terrestrial video camera is accompanied by comments through a microphone. In addition, the three-wire power cable contains signs of the length of the distance traveled.

The advantage of this method is: the possibility of controlling the robot and conducting an operational teleinspection of the pipeline with the possibility of recording on a protected digital video camera, which is mounted in the hermetic body of the cart, and the design of the cart allows the system to be used in pipelines partially filled with liquid.

The disadvantages of this method are: insufficient visualization quality of large diameters of inspected pipelines due to the impossibility of approaching the video camera to the inner surface of the pipeline; the low accuracy of determining the length of the distance traveled to the location of the defect in the pipeline wall is due to the fact that the distance length marks are printed on the cable, there is no possibility of automatically marking the location of the pipeline on the terrain map, the presence of gases in the pipeline is not determined.

The closest device for inspecting pipelines is a robotic pipeline inspection system (patent of the Russian Federation for a utility model Mo 133896, publication date 10.27.2013, Byul.Me30), which contains a means of movement in the form of a wheeled cart, cameras installed on the means of movement, lighting equipment, receiving-transmitting device. Transceiver device, control unit, registration unit, monitor, power supply unit are placed outside the pipeline. The transceiver and the transceiver are connected via a radio wave channel. The means of transportation is made in the form of a cart. One of the cameras is a course camera, installed with the possibility of inspecting the course of movement of the cart, and the other of the cameras is an inspection camera, installed with the possibility of inspecting the pipe wall in the transverse plane and equipped with a drive for its rotation. The running mechanisms of the cart are equipped with encoders and their output is connected to the information input of the receiving-transmitting device.

The advantage of this device is: improving the quality of visualization of the pipeline wall and the accuracy of determining the location of the defect for pipelines of large diameters, simplified design.

The disadvantages of this device are: impossibility of use in pipelines half-filled with liquid, for example, in working sewage collectors; does not have the ability to automatically indicate the location of the pipeline on the terrain map, the presence of gases in the pipeline is not determined, the slope of the pipeline is not determined.

This device, as the closest in terms of technical essence and functional purpose, is accepted as the closest analog.

The useful model is based on the task of creating a robot for the visual-optical inspection of the pipeline with the determination of the presence of gases by improving the design of the wheeled cart and control panel with an information processing system, which would allow, at the expense of video cameras, to conduct a tele-inspection of the internal surface of the pipeline both in empty and half-filled fluid in pipelines, for example, working gravity sewer collectors, determine the exact location and visual-optical inspection of the place of damage to the pipeline with the possibility of video recording and saving the obtained data, determine the slope of the pipeline, determine the presence of gases in the pipeline, for example, carbon, hydrogen sulfide or methane, which can lead to destruction of the internal surface of the pipeline due to gas corrosion and can be dangerous during work, as well as automatically mark the location of the pipeline on the map of the area with the location of damage.

The task is solved by a robot for the visual-optical examination of the pipeline with the determination of the presence of gases, which contains a wheeled cart, a hermetic video camera for determining the direction of movement, a hermetic video camera for examining the internal surface of the pipeline in the transverse plane, a data reception-transmission unit, a data transmission-reception unit, a drive rotation of the video camera in the plane, orthogonal axis of the pipeline, lighting equipment, power supply unit, in which, according to the utility model, the wheel cart additionally contains gas sensors, an accelerometer, a control unit for the speed of rotation of the wheels and a device for determining the slope of the pipeline, data from the control joystick is transmitted to the unit

By controlling the speed of rotation of the wheels, due to which the specified direction of movement of the wheeled cart is maintained, and by driving the rotation of the video camera in the plane, the orthogonal axis of the pipeline, a tablet computer or smartphone with an SRO module determines the geographical coordinates of the wells at the beginning and end of the pipeline, outputs on the screen and records in the memory the images from the video camera of the direction of movement and the surveillance video camera together with information about the presence of gases, acceleration of the movement, the length of the advance of the wheeled cart and the slope of the pipeline in and automatically marks the location of the pipeline on the map of the area with the location of damage, cable with cable is placed on a reel for laying a cable with a rope.

The body of the wheeled cart has the shape of a boat and is sealed. The lighting equipment is built into the housings of the video cameras.

The following are the general features of the closest analog and useful model that is claimed: - wheeled cart; - hermetic video camera for determining the direction of movement; - hermetic video camera for inspection of the internal surface of the pipeline in the transverse plane; - data reception-transmission block; - data transmission-reception block; - video camera rotation drive in the plane, orthogonal axis of the pipeline; - lighting equipment.

Distinctive features are the following: - the wheeled cart additionally contains gas sensors, an accelerometer, a wheel rotation speed control unit and a device for determining the slope of the pipeline; - data from the control joystick is transmitted to the wheel rotation speed control unit, due to which the specified direction of movement of the wheeled cart is maintained, and to the video camera rotation drive in the plane, orthogonal axis of the pipeline; - a tablet computer or smartphone with an SRO module determines the geographical coordinates of the wells at the beginning and end of the pipeline, displays on the screen and records images from the video camera of the direction of movement and the surveillance video camera together with information about the presence of gases, acceleration of movement, length of advancement of a wheeled cart and the slope of the pipeline and automatically marks the location of the pipeline on the terrain map with the location of 60 damages; - the cable with the rope is placed on the coil for laying the cable with the rope.

In addition, the body of the wheeled cart is boat-shaped and made airtight.

The lighting equipment is built into the housings of the video cameras.

The cause-and-effect relationship between the essential features of the useful model, which are sufficient in all cases, and the obtained final technical results provide new technical qualities, allowing, in combination with the known features, to obtain the technical results specified in the problem statement.

The claimed useful model is explained, but not limited to the drawing, which shows the functional scheme of the robot for the visual-optical examination of the pipeline with the determination of the presence of gases.

A useful robot model for the visual-optical inspection of the pipeline with the determination of the presence of gases includes a wheeled cart (1), a hermetic video camera of the direction of movement with lighting equipment (2), a hermetic inspection video camera with lighting equipment for examining the internal surface of the pipeline in the transverse plane (3), sensors gas (4), accelerometer (5), wheel speed control unit (6), data reception and transmission unit (7), video camera rotation drive in the plane, orthogonal axis of the pipeline (8), device for determining the slope of the pipeline (18), unit transmission-reception of data and information processing (9), control joystick (10), tablet computer or smartphone with SRO module (11), power supply unit (12), cable with cable (13), coil for laying cable with cable ( 14).

Preparation for work is carried out as follows: on the section of the inspected pipeline (15) using a tablet computer or smartphone with the ChSRB5 module (11), the geographical coordinates of the well at the beginning of the pipeline (16) and the well at the end of the pipeline (17) are determined, after which control joystick (10), power supply unit (12), tablet computer or smartphone with CRB5 module (11) and one end of the cable with a cable (13), the other end of which is connected to the data transmission-reception and information processing unit (9) to the wheeled cart (1), and the cable with the cable (13) is placed on the reel for laying the cable with the cable (14).

The robot works for the visual-optical examination of the pipeline with the determination of the presence of gases as follows: the wheeled cart (1) is introduced through the well at the beginning of the pipeline

From (16) to the inspected pipeline (15), then the movement of the wheeled cart (1) along the pipeline is controlled by the operator using the control joystick (10), while the image from the hermetic video camera of the direction of movement with lighting equipment (2) and the image from the hermetic inspection video camera with lighting equipment for examining the internal surface of the pipeline in the transverse plane (3) is displayed on the screen of a tablet computer or smartphone with an SRO module (11), in addition, from the data reception-transmission unit (7) to the data reception-transmission and information processing unit (9) information from gas sensors (4), which determine the presence of gases in the pipeline (15), from the device for determining the slope of the pipeline (18), which determines the slope, is received and displayed on the screen of a tablet computer or smartphone with a CRB5 module (11) of the pipeline, and from the accelerometer (5), which determines the acceleration and length of advancement of the wheeled cart (1), and the data from the control joystick (10), through the block in front data reception and information processing (9) and the data reception-transmission unit (7) are transmitted to the wheel rotation speed control unit (b), due to which the specified direction of movement of the wheeled cart (1) is maintained, and to the video camera rotation drive in the plane, orthogonal to the axis of the pipeline (8), due to which high quality visualization of the inner surface of the inspected pipelines is ensured. After the wheeled cart (1) reaches the well at the end of the pipeline (17), the pipeline survey is stopped. The data obtained during the examination are processed by a computer program and stored in the memory of a tablet computer or smartphone with

CRB5 module (11), and the location of the pipeline is automatically marked on the map of the area with the location of damage.

Thus, the proposed useful model has structural and operational advantages over the known closest analog design.

Claims (2)

USEFUL MODEL FORMULA 1. A robot for the visual-optical examination of the pipeline with the determination of the presence of gases, which contains a wheeled cart, a hermetic video camera for determining the direction of movement, a hermetic video camera for examining the internal surface of the pipeline in the transverse plane, a data reception-transmission unit, a data transmission-reception unit, a rotation drive because the video cameras in the plane, the orthogonal axis of the pipeline, the lighting equipment, the power supply unit, which is distinguished by the fact that the wheel cart additionally contains gas sensors, an accelerometer, the control unit for the speed of rotation of the wheels and the device for determining the slope of the pipeline, the data from the control joystick are transmitted to the control unit for the speed of rotation wheels, due to which the specified direction of movement of the wheeled cart is maintained and by driving the rotation of the video camera in the plane, the orthogonal axis of the pipeline, a tablet computer or smartphone with (RO module) determines the geographical coordinates of the wells at the beginning and end of the pipeline, displays on the screen and records in memory the images from the video camera of the direction of travel and the surveillance video camera together with information about the presence of gases, acceleration of the movement, the length of the advance of the wheeled cart and the slope of the pipeline and automatically marks the location of the pipeline on the map of the area with the location of damage, the cable with the cable is placed on the reel for laying a cable with a rope. 2. The device according to claim 1, which is characterized by the fact that the body of the wheeled cart has the shape of a boat and is sealed. Q. The device according to claim 1, which is characterized by the fact that the lighting equipment is mounted in the housings of the video cameras. yu M pen o i peasants sk dey, Zh v, l mesh SHE a Z V z she ny Ka MY IN seevi ! ше чи ши шеч и ншще ШЕ Ж I ru I rn dia и dy ; min ; ; ikri vek: Y i Z 4 Zeneniai SHE and Z M 415 in Mo