CN111810763A - Automatic sealing mechanism of non-excavation petroleum pipeline damage prosthetic devices - Google Patents

Abstract

The invention discloses an automatic sealing mechanism of a non-excavation petroleum pipeline damage repair device, which comprises a telescopic adjusting mechanism, a repair liquid spraying mechanism and a cleaning glue coating mechanism, wherein the repair liquid spraying machine body comprises a main shaft shell, an air pump, a power supply, an air bag and glass fiber felt cloth, the telescopic adjusting mechanism comprises a lead screw lifting assembly, a rotating roller wheel is arranged at the end part of the lead screw lifting assembly, the cleaning glue coating mechanism comprises a cleaning turntable and a glue coating turntable, a rotating brush is arranged on the cleaning turntable, a glue opening is arranged on the glue coating mechanism, the glass fiber felt cloth is coated on the outer wall of the air bag, repair liquid is arranged on the glass fiber felt cloth, the glass fiber felt cloth is adhered to the damage position of a pipeline, the repair effect on the inner wall of the pipeline can be greatly improved, and the inner wall of the pipeline can be cleaned through the cleaning mechanism, and meanwhile, the sealant is coated, so that the repairing effect of the inner wall of the pipeline can be greatly ensured.

Description

Automatic sealing mechanism of non-excavation petroleum pipeline damage prosthetic devices

Technical Field

The invention relates to the technical field of pipeline maintenance and repair, in particular to an automatic sealing mechanism of a trenchless petroleum pipeline damage repairing device.

Background

With the development of the oil industry, more and more pipelines are applied to the field of oil transportation, and the pipelines are difficult to avoid corrosion and cracking in long-term use, and at this time, the repair of the pipelines is very important. The repair of pipelines is divided into an excavation type repair method and a non-excavation type repair method, wherein the excavation type repair method is high in repair cost, and the non-excavation type repair method can effectively save the cost.

The existing trenchless repairing method mainly comprises an ultraviolet curing repairing technology, a point repairing technology, a folding lining repairing technology and a high polymer material repairing technology.

1. Ultraviolet curing repair technology (for whole repair)

The ultraviolet curing CIPP repairing technology is characterized in that under the condition that the position of a pipeline to be repaired is not changed, a hose soaked with resin is tightly attached to the inner wall of the pipeline to be repaired in a stretching and compressed air mode or process, then the characteristic that the resin in the hose is cured when meeting ultraviolet rays is utilized, an ultraviolet lamp is placed into an inflated hose and is controlled to run in the hose at a certain speed, the hose is gradually cured from one end to the other end and is tightly attached to the inner wall of the pipeline to be repaired, a hard pipe-in-pipe structure is formed, and therefore an underground pipeline which is damaged or loses the conveying function is repaired in situ.

2. Point repair technology (for local repair)

The trenchless spot repairing method for urban pipelines, also called local resin curing method (felt tube air bag local forming method), is a trenchless repairing method in which when emergency repair is required due to local damage of a pipeline in the case of local crack, leakage and damage of the pipeline, a glass fiber felt cloth coated with a resin mixed solution is pressed against the inner wall of the pipeline by an air bag, and curing is realized by means of normal temperature, heating or ultraviolet irradiation, etc., so that a new lining pipe is formed in a repairing point pipe. The point-like repair technology has the characteristics of strong pertinence, high construction speed and the like, does not need to repair the whole section, only needs to repair the damaged part, and can greatly reduce the economic cost by adopting the method, so the technology is widely applied to foreign pipeline repair engineering.

3. Folding lining repair technology (for integral repair)

The Primeris lining system consists of Kevlar reinforced lining pipes and specially designed connectors, the PE pipes are folded into a U shape and pulled into the mother pipes by binding with adhesive tapes, and then the pipes are inflated to form a circle.

4. Polymer material repair technology (for local repair)

The high polymer material repairing technology adopts a concrete repairing material imported from America Annaikang, and mainly aims at pipelines with the diameter of more than 700 mm. After the damaged position is determined, constructors can complete the procedures of quick leaking stoppage, filling, bridging, reinforcing and the like at one time, the construction is simple, the material has quick curing time, the compressive strength after curing is 5 times of that of concrete, the cohesive strength of the material and the original pipe wall is greater than that of the concrete, and the material has good chemical corrosion resistance.

The existing point-like repair technology needs to guide a device entering the pipeline for operation by arranging a traction mechanism, and the device cannot be conveniently and efficiently adjusted in adaptability aiming at pipelines with different diameters;

meanwhile, in the process of sealing the pipeline, because the inner wall of the pipeline has more impurities, the repairing effect of repairing modes such as gluing and the like is poor, and meanwhile, after the repairing is finished, certain impact can be caused to the repaired position due to the flowing process of the petroleum in the pipeline, so that the repairing effect is low.

Disclosure of Invention

The technical problem to be solved by the invention is to provide an automatic sealing mechanism of a trenchless petroleum pipeline damage repairing device, and the technical scheme solves the problems, the pipeline can be automatically sealed through the automatic sealing mechanism, meanwhile, the repaired position can be coated with sealant through cleaning the gluing mechanism, and the sealing effect on the pipeline is greatly improved.

In order to solve the technical problems, the invention provides the following technical scheme:

an automatic sealing mechanism of a trenchless petroleum pipeline damage repairing device comprises a telescopic adjusting mechanism, a repairing liquid spraying mechanism and a cleaning and gluing mechanism;

the repair liquid spraying machine body comprises a main shaft shell, an air pump, a power supply, an air bag and glass fiber felt cloth;

the telescopic adjusting mechanism comprises a lead screw lifting assembly, and a rotating roller wheel is arranged at the end part of the lead screw lifting assembly;

the cleaning and gluing mechanism comprises a cleaning turntable and a gluing turntable, wherein a rotating brush is arranged on the cleaning turntable, and a glue opening is formed in the gluing mechanism;

the telescopic adjusting mechanisms are arranged at two ends of the main shaft shell and are coaxial with the main shaft shell, and the moving direction of the telescopic adjusting mechanisms is arranged along the radial direction of the main shaft shell;

the air bag is wrapped on the outer wall of the main shaft shell and is coaxially arranged with the main shaft shell;

the air pump and the power supply are arranged in the spindle shell, and the air pump extends out of the spindle shell and is connected with the air bag;

the air pump supplies air to the gluing turntable and the cleaning turntable and controls the gluing turntable and the cleaning turntable to work;

the glass fiber felt cloth is wrapped on the outer wall of the air bag, and the glass fiber felt cloth is provided with the repairing liquid.

Preferably, the spindle shell is further provided with air holes and a limiting plate; the air holes are formed in the spindle shell to enable the air pump to be communicated with the outside, and the limiting plate is installed in the spindle shell and is rotatably connected with the connecting parts at the two ends of the telescopic adjusting mechanism.

Preferably, the telescopic adjusting mechanism comprises a rotary driving component and a synchronous transmission component; synchronous drive assembly sets up in main shaft housing both ends and runs through main shaft housing department and rotate with main shaft housing and be connected, the rotation driving subassembly is installed on synchronous drive assembly and is located main shaft housing's rear end, the rotation driving subassembly output is connected with the synchronous drive assembly input, at least three lead screw lifting unit around synchronous drive assembly axis setting on synchronous drive assembly and output direction of motion along main shaft housing radial setting, the setting that running gear working end is outwards is on lead screw lifting unit output, the rotation driving subassembly is connected with the controller electricity.

Preferably, the rotary driving assembly comprises a first rotary driver, a driver protection shell and a heat dissipation hole; the first rotary driver is fixedly connected with the synchronous transmission assembly and located on the rear side of the spindle shell, the output end of the first rotary driver is fixedly connected with the input end of the synchronous transmission assembly, the driver protection shell covers the first rotary driver and is fixedly connected with the synchronous transmission assembly, the heat dissipation holes are formed in the driver protection shell, and the first rotary driver is electrically connected with the controller.

Preferably, the synchronous transmission assembly comprises a supporting shell, a driving shaft, a driven shaft, a driving right-angle bevel gear and a driven right-angle bevel gear; support housing sets up a pair ofly for the hexagon structure and in main shaft housing both ends, the drive shaft runs through a pair of support housing and rotates with main shaft housing to be connected, the driven shaft that matches with lead screw lifting unit quantity rotates with the support housing lateral wall to be connected and outer end and lead screw lifting unit input end fixed connection, a pair of drive right angle bevel gear cup joints in the drive shaft and lies in a pair of support housing respectively, driven right angle bevel gear installs one of driven shaft near the drive shaft and serves, drive right angle bevel gear and driven right angle bevel gear meshing transmission, the drive shaft is installed on first rotary actuator and input and rotary drive subassembly output fixed connection.

Preferably, the screw lifting assembly comprises a guide shell, a driving screw, a sliding block and a connecting rod; the guide shell is fixedly connected with the synchronous transmission assembly and extends along the radial direction of the main shaft shell, two ends of a driving lead screw are rotatably connected with two ends of the guide shell, the driving lead screw is fixedly connected with the output end of the synchronous transmission assembly, a sliding block is connected with the guide shell in a sliding way and is in threaded connection with the driving lead screw, a connecting rod is fixedly connected with the part of a driven shaft, which is positioned outside the driving shaft, and the bottom of the connecting rod is fixedly connected with the walking mechanism;

the connecting rod is provided with a guide part which is in sliding connection with four edges of the guide shell, and the guide part is a pair of strip-shaped plates which are vertical to each other.

Preferably, the cleaning gluing mechanism further comprises an installation shaft, the cleaning turntable and the gluing turntable are respectively arranged on the installation shaft, the cleaning turntable is provided with a turntable rotating groove, a supporting rotating ring is arranged in the turntable rotating groove, a rotating ring is arranged in the rotating groove of the rotating disc, a plurality of first rotating shafts are arranged on the inner ring of the rotating ring, the first rotating shafts are respectively provided with a rotating roller which rotates on the supporting rotating rings, a circle of air exhaust holes are arranged on the rotating ring, the air exhaust holes are arranged in an inclined shape, the brush is fully distributed on the rotating ring, a plurality of air injection holes are arranged on one side of the rotary table rotary groove, an exhaust groove is arranged on the other side of the rotary table rotary groove, a connecting air hole is formed in the cleaning turntable, and a first air hole pipe correspondingly communicated with the connecting air hole is arranged on the cleaning turntable;

a plurality of glue cavities are formed in the glue coating turntable, the glue openings are correspondingly communicated with the glue cavities respectively, a glue head is arranged on each glue opening, a rubber air bag is arranged in each glue cavity, and a second air pipe is arranged on each rubber air bag;

the installation epaxial be provided with a joint groove, install the epaxial still be provided with one with the corresponding mounting hole in joint groove.

Preferably, the application also comprises a trenchless petroleum pipeline damage repairing device, and the automatic sealing mechanism comprises the trenchless petroleum pipeline damage repairing device.

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

the damaged position of the pipeline can be repaired through the repair liquid spraying mechanism, and the air bag is inflated through the air pump arranged on the plant continent shell, so that the stripped fiber felt cloth can be further pressed at the damaged position of the pipeline, the aim of automatic repair is fulfilled, the trouble caused by pipeline excavation is avoided, and the repair efficiency is greatly improved;

the glass fiber felt cloth can be further fixed through the automatic sealing mechanism, the main shaft shell can be controlled to slide in the pipeline through the telescopic adjusting mechanism, and the main shaft shell can be further supported through the lead screw lifting assembly, so that the machine body can automatically slide in the pipeline, and the pipeline repairing efficiency is greatly improved;

after the air is supplied to the first air pipe through the air pump, the rotation of the rotating ring can be further blown and cleaned under the action of the atmospheric pressure, so that the brush can be driven to clean the inner wall of the pipeline, the cleanness of the inner wall of the pipeline can be further ensured, the attaching effect of the glass fiber felt cloth can be ensured, the problem of falling off is avoided, and the sealing effect is greatly improved;

give through the air pump behind the second trachea air feed, aerify the inflation through rubber air bag, can make and extrude sealed glue to on can extruding glass fiber felt cloth after extruding out through gluey mouth, can go on further sealedly to glass fiber felt cloth through sealed glue, great improvement the repair effect of pipeline damage position.

Drawings

FIG. 1 is a perspective view of the present invention 1;

FIG. 2 is a perspective view of the present invention 2;

FIG. 3 is a front view of the present invention;

FIG. 4 is a sectional view taken along line A-A of FIG. 3;

FIG. 5 is an enlarged view of a portion of FIG. 4 at C;

FIG. 6 is a sectional view taken along line B-B of FIG. 3;

FIG. 7 is a partial perspective view of the present invention of FIG. 1;

FIG. 8 is an exploded perspective view of FIG. 7;

FIG. 9 is a partial perspective view of the present invention FIG. 2;

FIG. 10 is an exploded perspective view of FIG. 9;

FIG. 11 is a schematic view of the overall structure of the cleaning and gluing mechanism of the present invention;

fig. 12 is a schematic view of the overall structure of the rotating ring of the present invention.

The reference numbers in the figures are:

1. a spindle housing; 1a, air holes; 1b, a limiting plate;

2. a vision monitoring mechanism; 2a, a fixing frame; 2b, an infrared ball head camera;

3. a telescopic adjusting mechanism; 3a, a rotation driving component; 3a1, first rotary drive; 3a2, drive protection housing; 3a3, heat dissipation holes; 3b, a synchronous transmission component; 3b1, support housing; 3b2, drive shaft; 3b3, driven shaft; 3b4, drive right angle bevel gear; 3b5, driven right angle bevel gear; 3c, a screw lifting assembly; 3c1, guide housing; 3c2, drive screw; 3c3, slider; 3c4, connecting rod;

4. a traveling mechanism; 4a, a supporting foot frame; 4b, a roller bracket; 4c, rolling; 4d, a driving component; 4d1, second rotary drive; 4d2, first sync wheel; 4d3, second synchronizing wheel; 4d4, timing belt;

5. an air pump;

6. a power source;

7. an air bag;

8. glass fiber felt cloth;

9. cleaning a gluing device; 9a1, mounting shaft; 9a2, a clamping groove; 9a3, mounting holes; 9b1, cleaning turntable; 9b2, turntable and rotary groove; 9b3, rotating ring; 9b4, air exhaust holes; 9b5, gas injection holes; 9b6, connecting air holes; 9b7, first trachea; 9b8, a first rotating shaft; 9b9, support swivel; 9b10, roller; 9b11, exhaust groove; 9b12, brush; 9c1, a gluing turntable; 9c2, glue cavity; 9c3, rubber bladder; 9c4 gluing mouth; 9c5, second trachea.

Detailed Description

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

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

As shown in fig. 1 and 4, the device for repairing the damage of the trenchless petroleum pipeline comprises a visual monitoring mechanism 2, an automatic sealing mechanism, a traveling mechanism 4 and a controller;

the automatic sealing mechanism comprises a telescopic adjusting mechanism 3, a repairing liquid spraying mechanism and a cleaning and gluing mechanism 9;

the repair liquid spraying machine body comprises a main shaft shell 1, an air pump 5, a power supply 6, an air bag 7 and glass fiber felt cloth 8;

the telescopic adjusting mechanism 3 comprises a lead screw lifting component 3c, and a rotating roller 4c is arranged at the end part of the lead screw lifting component 3 c;

the cleaning gluing mechanism 9 comprises a cleaning turntable 9b1 and a gluing turntable 9c1, a rotating brush 9b12 is arranged on the cleaning turntable 9b1, and a gluing opening 9c4 is arranged on the gluing mechanism 9c 1;

the telescopic adjusting mechanisms 3 are arranged at two ends of the main shaft shell 1 and are coaxially arranged with the main shaft shell 1, and the moving direction of the telescopic adjusting mechanisms 3 is arranged along the radial direction of the main shaft shell 1;

the visual monitoring mechanism 2 is arranged on one side of the telescopic adjusting mechanism 3, which is positioned at the head end of the main shaft shell 1, and is fixedly connected with the telescopic adjusting mechanism 3;

the air bag 7 is wrapped on the outer wall of the main shaft shell 1 and is coaxially arranged with the main shaft shell 1;

the air pump 5 and the power supply 6 are both arranged in the main shaft shell 1, and the air pump 5 extends out of the main shaft shell 1 and is connected with the air bag 7;

the air pump 5 supplies air to the gluing turntable 9c1 and the cleaning turntable 9b1, and controls the gluing turntable 9c1 and the cleaning turntable 9b1 to work;

the glass fiber felt cloth 8 is wrapped on the outer wall of the air bag 7, and the glass fiber felt cloth 8 is provided with a repairing liquid;

the running mechanism 4 is arranged at the end part of the telescopic adjusting mechanism 3, the running mechanism 4 drives the roller 4c to rotate, and the telescopic adjusting mechanism 3 controls the running mechanism 4 to stretch and slide;

the parts of the vision monitoring mechanism 2 at the two ends of the spindle housing 1 are mutually connected, the air pump 5 and the power supply 6 are respectively provided with a via hole avoiding the connecting part of the vision monitoring mechanism 2, and the vision monitoring mechanism 2, the telescopic adjusting mechanism 3, the travelling mechanism 4, the air pump 5 and the power supply are electrically connected with the controller.

The power supply is used for independently supplying power for the visual monitoring mechanism 2, the telescopic adjusting mechanism 3, the travelling mechanism 4 and the air pump, and can also supply power in a mode of external wires. The operator soaks the slurry for repairing with the glass fiber felt cloth 8, and then wraps the glass fiber felt cloth 8 outside the air bag 7. The staff places the device to the one end of the petroleum pipeline that needs to be repaired earlier, then sends the signal to flexible adjustment mechanism 3 through the controller. After receiving the signal, the telescopic adjusting mechanism 3 drives the parts of the telescopic adjusting mechanism located at the two ends of the main shaft shell 1 to synchronously extend outwards in the radial direction until the tail end of the visual monitoring mechanism 2 abuts against the inner wall of the petroleum pipeline and is located on the same axis with the petroleum pipeline. The controller then sends a signal to the travelling mechanism 4, and the travelling mechanism 4 starts to work as the whole device to provide driving force for advancing in the pipeline after receiving the signal. The visual signal is sent to the controller by observation of the visual monitoring mechanism 2 which has an infrared function and can rotate. The controller accurately positions the internal damage of the petroleum pipeline according to the data sent by the vision monitoring mechanism 2. When the spindle housing 1 moves to the damaged part of the pipeline, the controller sends a signal to the air pump 5, the air pump 5 injects air into the air bag 7 after receiving the signal, and the air bag 7 expands and gradually enables the external glass fiber felt cloth 8 to abut against the damaged part of the pipeline. When the glass fiber felt cloth 8 is bonded with the damaged part of the pipeline, the controller sends a signal to the air pump 5, the air pump 5 pumps out the air in the air bag 7 to enable the air bag to contract so as to be separated from the glass fiber felt cloth 8, and the glass fiber felt cloth 8 is left at the damaged part of the inner wall of the pipeline to finish the repairing task. Then the controller sends a signal to the traveling mechanism 4, and the traveling mechanism 4 receives the signal and then the whole driving device climbs out of the petroleum pipeline;

the damaged position of the pipeline can be repaired through the repair liquid spraying mechanism, and the air bag is inflated through the air pump arranged on the plant continent shell, so that the stripped fiber felt cloth can be further pressed at the damaged position of the pipeline, the aim of automatic repair is fulfilled, the trouble caused by pipeline excavation is avoided, and the repair efficiency is greatly improved;

can carry out cleaning operation to pipeline inner wall through the clearance carousel, guarantee the cleanness of pipeline inner wall, through sealed glue of spraying that the rubber coating carousel can be automatic, through sealed glue coating on glass fiber felt cloth, great improvement the repair effect of pipeline.

As shown in fig. 2 and 4, the spindle housing 1 is further provided with an air hole 1a and a limit plate 1 b; the air holes 1a are arranged on the main shaft shell 1 to enable the air pump 5 to be communicated with the outside, and the limiting plates 1b are arranged in the main shaft shell 1 and are rotatably connected with the joints at the two ends of the telescopic adjusting mechanism 3.

The inside of the main shaft shell 1 is communicated with the atmosphere by arranging the air holes 1a, so that the normal ventilation of the air pump 5 is ensured, and the stability of the structure is ensured. Connecting portion between 3 both ends of flexible adjustment mechanism need set up with spindle housing 1 assorted length, for preventing that it from taking place skew or vibrations in the transmission process, carry on spacingly to it through limiting plate 1b, have further improved the stability of structure.

As shown in fig. 3, the vision monitoring mechanism 2 includes a fixing frame 2a and an infrared ball head camera 2 b; the fixing frame 2a is fixedly connected with the telescopic adjusting mechanism 3 and is positioned at the front end of the main shaft shell 1, and the infrared ball head camera 2b is electrically connected with the controller.

The infrared ball head camera 2b has a three-hundred-sixty-degree rotation function, can observe the condition of any angle in the pipeline in the advancing process, and is favorable for accurately positioning the damaged part in the petroleum pipeline and timely sending the damaged part to the controller. The fixing frame 2a provides support for the infrared ball head camera 2b and enables the infrared ball head camera 2b and the telescopic adjusting mechanism 3 to keep a certain distance, and certain negative effects on the visual field of the infrared ball head camera 2b caused by the tail end of the telescopic adjusting mechanism 3 are prevented.

As shown in fig. 2 and 7, the telescopic adjusting mechanism 3 includes a rotary driving assembly 3a, a synchronous transmission assembly 3b and a lead screw lifting assembly 3 c; synchronous drive assembly 3b sets up in spindle housing 1 both ends and runs through spindle housing 1 department and is connected with spindle housing 1 rotation, rotary drive assembly 3a installs on synchronous drive assembly 3b and is located spindle housing 1's rear end, rotary drive assembly 3a output is connected with synchronous drive assembly 3b input, at least three lead screw lifting unit 3c sets up on synchronous drive assembly 3b and output direction of motion along spindle housing 1 radially around synchronous drive assembly 3b axis, walking mechanism 4 work end setting outwards is on lead screw lifting unit 3c output, rotary drive assembly 3a is connected with the controller electricity.

The controller sends a signal to the rotary driving component 3a, the output end of the rotary driving component 3a drives the synchronous transmission components 3b at the two ends of the main shaft shell 1 to rotate after receiving the signal, and the synchronous transmission components 3b synchronously send torque to at least six screw lifting components 3c in front of and behind the main shaft shell 1 so that the movable end of each screw lifting component is synchronously far away from or close to the main shaft shell 1 in the radial direction, thereby adjusting the length of the travelling mechanism 4.

As shown in fig. 8, the rotary drive assembly 3a includes a first rotary driver 3a1, a driver protection housing 3a2 and a heat dissipation opening 3a 3; the first rotary driver 3a1 is fixedly connected with the synchronous transmission assembly 3b and is located at the rear side of the main shaft housing 1, the output end of the first rotary driver 3a1 is fixedly connected with the input end of the synchronous transmission assembly 3b, the driver protection housing 3a2 covers the first rotary driver 3a1 and is fixedly connected with the synchronous transmission assembly 3b, the heat dissipation hole 3a3 is formed in the driver protection housing 3a2, and the first rotary driver 3a1 is electrically connected with the controller.

The first rotary driver 3a1 is a servo motor. The controller drives the synchronous transmission component 3b to work through the first rotary driver 3a 1. The first rotary driver 3a1 is protected by the driver protection shell 3a2, so that the first rotary driver 3a1 can work in a petroleum pipeline better, the first rotary driver 3a1 is prevented from being polluted by petroleum adhered to the pipe wall, and the service life of the first rotary driver 3a1 is prolonged. And the first rotary driver 3a1 is assisted in better heat dissipation by arranging the heat dissipation hole 3a 3.

As shown in fig. 5, 6 and 8, the synchronous drive assembly 3b comprises a support housing 3b1, a drive shaft 3b2, a driven shaft 3b3, a drive bevel pinion 3b4 and a driven bevel pinion 3b 5; the support housing 3b1 is of a hexagonal structure and is provided with a pair at two ends of the spindle housing 1, the driving shaft 3b2 penetrates through the pair of support housings 3b1 and is rotatably connected with the spindle housing 1, the driven shaft 3b3 matched with the number of the lead screw lifting assemblies 3c is rotatably connected with the side wall of the support housing 3b1, the outer end of the driven shaft is fixedly connected with the input end of the lead screw lifting assembly 3c, the pair of driving right-angle bevel gears 3b4 are sleeved on the driving shaft 3b2 and are respectively positioned in the pair of support housings 3b1, the driven right-angle bevel gear 3b5 is installed at one end of the driven shaft 3b3 close to the driving shaft 3b2, the driving right-angle bevel gear 3b4 is in meshing transmission with the driven right-angle bevel gear 3b5 b, the driving shaft 3b2 is installed on.

The rotary driving assembly 3a transmits torque to a driver protection shell 3a2, the driver protection shell 3a2 drives a pair of driving right-angle bevel gears 3b4 at two ends of the spindle shell 1 to rotate, each driving right-angle bevel gear 3b4 drives a plurality of driven right-angle bevel gears 3b5 in meshed transmission with the driving right-angle bevel gears, and the driven right-angle bevel gears 3b5 finally transmit torque to the screw rod lifting assembly 3 c. The telescopic adjusting mechanisms 3 at the two ends of the main shaft shell 1 are synchronously operated under the transmission action of the synchronous transmission assembly 3b, so that the operation is convenient and the structural stability is strong.

As shown in fig. 9 and 10, the lead screw lifting assembly 3c includes a guide housing 3c1, a driving lead screw 3c2, a slide block 3c3 and a connecting rod 3c 4; the guide housing 3c1 is fixedly connected with the synchronous transmission assembly 3b and extends along the radial direction of the main shaft housing 1, two ends of a driving lead screw 3c2 are rotatably connected with two ends of the guide housing 3c1, the driving lead screw 3c2 is fixedly connected with the output end of the synchronous transmission assembly 3b, a sliding block 3c3 is slidably connected with the guide housing 3c1 and is in threaded connection with a driving lead screw 3c2, a connecting rod 3c4 is fixedly connected with the part of a driven shaft 3b3, which is positioned outside a driving shaft 3b2, and the bottom of the connecting rod 3c4 is fixedly connected with the walking mechanism 4.

The synchronous transmission assembly 3b transmits the torque of the rotary driving assembly 3a to the plurality of driving lead screws 3c2 synchronously. Under the screw connection of the driving lead screw 3c2 and the limit action of the guide housing 3c1, the slide block 3c3 can do linear motion along the radial direction of the main shaft housing 1. The slider 3c3 drives the traveling mechanism 4 to perform linear motion through the connecting rod 3c 4. The driving structure formed by the guide shell 3c1, the driving lead screw 3c2 and the slide block 3c3 has certain self-locking capability, so that the working end of the walking mechanism 4 can tightly abut against the inner wall of the pipeline, and the control is accurate.

As shown in fig. 10, the link lever 3c4 is provided with guide portions slidably connected to four sides of the guide housing 3c1, and the guide portions are a pair of strip-shaped plates perpendicular to each other.

The structural stability of the drive of the screw lifting assembly 3c to the running gear 4 is further improved by providing the guide portion on the connecting rod 3c 4.

As shown in fig. 9, the walking mechanism 4 includes a foot rest 4a, a roller bracket 4b, a roller 4c and a driving component 4 d; foot rest 4a and 3 output end fixed connection of flexible adjustment mechanism, foot rest 4a are inside hollow structure, and running roller support 4b installs the one end of keeping away from flexible adjustment mechanism 3 at foot rest 4a, and running roller 4c rotationally installs on running roller support 4b, and drive assembly 4d installs in foot rest 4a and output and running roller 4c fixed connection, and drive assembly 4d is connected with the controller electricity.

The telescopic adjusting mechanisms 3 at the two ends of the spindle housing 1 only need to be provided with the driving component 4d on the running mechanism 4 on the telescopic adjusting mechanism 3 at one end, and the front drive or the rear drive can be flexibly selected. The foot rest 4a provides support for the roller bracket 4b and the drive assembly 4 d. The controller sends a signal to the driving component 4d, and the driving component 4d drives the roller wheel 4c to rotate after receiving the signal, so that the whole driving device advances in the pipeline.

As shown in fig. 10, the driving assembly 4d includes a second rotary driver 4d1, a first timing wheel 4d2, a second timing wheel 4d3 and a timing belt 4d 4; the second rotary driver 4d1 is installed in the foot rest 4a and the output end stretches out the foot rest 4a, the first synchronizing wheel 4d2 is sleeved on the output end of the second rotary driver 4d1, the second synchronizing wheel 4d3 is sleeved on the rotating shaft of the roller wheel 4c extending out of the roller wheel support 4b, two ends of the synchronizing belt 4d4 are in transmission connection with the first synchronizing wheel 4d2 and the second synchronizing wheel 4d3 respectively, the diameter of the first synchronizing wheel 4d2 is smaller than that of the second synchronizing wheel 4d3, and the second rotary driver 4d1 is electrically connected with the controller.

Second rotary actuator 4d1 is the servo motor who installs the speed reducer, improves the moment of torsion through the speed reducer and makes second rotary actuator 4d1 have the auto-lock ability, and running roller 4c adopts the great material of frictional force, and the device can not slide by oneself in the pipeline when second rotary actuator 4d1 does not work. The controller drives the first synchronous wheel 4d2 to rotate through the second rotary driver 4d1, and transmits torque to the second synchronous wheel 4d3 through the transmission action of the synchronous belt 4d4, and the second synchronous wheel 4d3 finally drives the roller wheel 4c to rotate, so that the driving device moves in the pipeline. The first synchronizing wheel 4d2 having a smaller diameter than the second synchronizing wheel 4d3 can amplify torque in a diameter ratio.

As shown in fig. 11 and 12, the cleaning glue mechanism 9 further includes a mounting shaft 9a1, the cleaning turntable 9b1 and the glue turntable 9c1 are respectively disposed on the mounting shaft 9a1, the cleaning turntable 9b1 is provided with a turntable rotation slot 9b2, a supporting rotation ring 9b9 is disposed in the turntable rotation slot 9b2, a rotating rotation ring 9b3 is disposed in the turntable rotation slot 9b2, an inner ring of the rotation ring 9b3 is provided with a plurality of first rotation shafts 9b8, a rotating roller 9b10 is disposed on each first rotation shaft 9b8, the roller 9b10 rotates on the supporting rotation ring 9b9, a ring of exhaust holes 9b4 is disposed on the rotation ring 9b3, the exhaust holes 9b4 are disposed in a shape, the brush 639 b12 is fully distributed on the rotation ring 9b3, a plurality of inclined air injection holes 5 b 9b 68628 are disposed on one side of the rotation slot 9b3, an exhaust groove 9b11 is formed in the other side of the rotary disc rotary groove 9b2, a connecting air hole 9b6 is formed in the cleaning rotary disc 9b1, and a first air hole pipe 9b7 which is correspondingly communicated with the connecting air hole 9b6 is formed in the cleaning rotary disc 9b 1;

a glue cavity 9c2 is arranged in the glue coating turntable 9c1, a plurality of glue ports 9c4 are arranged and are respectively communicated with the glue cavity 9c2 correspondingly, a glue head is arranged on each glue port 9c4, a rubber air bag 9c3 is arranged in the glue cavity 9c2, and a second air pipe 9c5 is arranged on the rubber air bag 9c 3;

the mounting shaft 9a1 is provided with a clamping groove 9a2, and the mounting shaft 9a1 is further provided with a mounting hole 9a3 corresponding to the clamping groove 9a 2.

The cleaning glue spreader can be arranged on the supporting shell 3b1 through the clamping groove 9a2, the cleaning glue spreader 9 can be conveniently mounted and dismounted, the air pump 5 can supply air to the first air pipe 9b7 and the second air pipe 9c5, the first air pipe 9b7 and the second air pipe 9c5 are controlled to be closed and communicated through the control device, after the first air pipe 9b7 supplies air, high-pressure air can be discharged from the air jetting hole 9b5, and then the high-pressure air is blown into the air beating hole 9b4 through the flowing of the high-pressure air, so that the cleaning turntable 9b1 can be blown, the brush 9b12 can rotate on the inner wall of the pipeline, impurities on the inner wall of the pipeline can be cleaned through the brush 9b12, and the self-rotation effect of the glass fiber felt cloth can be greatly improved;

after the inflation of the second air pipe, the rubber air bag 9c3 can be inflated to expand, so that the sealant is further pushed to slide, the sealant can be extruded out from the rubber opening 9c4, the sealant can be extruded onto the glass fiber felt, and the connecting effect of the glass fiber felt is greatly improved.

The glass fiber felt cloth can be further fixed through the automatic sealing mechanism, the main shaft shell can be controlled to slide in the pipeline through the telescopic adjusting mechanism, and the main shaft shell can be further supported through the lead screw lifting assembly, so that the machine body can automatically slide in the pipeline, and the pipeline repairing efficiency is greatly improved;

the cleaning and gluing mechanism 9 can be used for coating the glass fiber felt cloth stuck on the pipeline with sealant, so that the sealing effect of the glass fiber felt cloth can be greatly improved;

after the air pump 5 supplies air to the first air pipe 9b7, the rotation of the rotating ring 9b3 can be further blown and cleaned under the action of the atmospheric pressure, so that the brush 9b12 can be driven to clean the inner wall of the pipeline, the cleanness of the inner wall of the pipeline is further ensured, the attaching effect of the glass fiber felt cloth can be ensured, the problem of falling off is avoided, and the sealing effect is greatly improved;

give through air pump 5 after the air feed of second trachea 9c5, aerify the inflation through rubber gasbag 9c3, can make and extrude sealed glue to on can extruding glass fiber felt cloth after extruding out through gluey mouth 9c2, can go on further sealing to glass fiber felt cloth through sealed glue, great improvement the repair effect of pipeline damage position.

The working principle of the invention is as follows:

the power supply is used for independently supplying power for the visual monitoring mechanism 2, the telescopic adjusting mechanism 3, the travelling mechanism 4 and the air pump, and can also supply power in a mode of external wires.

The operator soaks the slurry for repairing with the glass fiber felt cloth 8, and then wraps the glass fiber felt cloth 8 outside the air bag 7. The staff places the device to the one end of the petroleum pipeline that needs to be repaired earlier, then sends the signal to flexible adjustment mechanism 3 through the controller.

After receiving the signal, the telescopic adjusting mechanism 3 drives the parts of the telescopic adjusting mechanism located at the two ends of the main shaft shell 1 to synchronously extend outwards in the radial direction until the tail end of the visual monitoring mechanism 2 abuts against the inner wall of the petroleum pipeline and is located on the same axis with the petroleum pipeline.

The controller then sends a signal to the travelling mechanism 4, and the travelling mechanism 4 starts to work as the whole device to provide driving force for advancing in the pipeline after receiving the signal. The visual signal is sent to the controller by observation of the visual monitoring mechanism 2 which has an infrared function and can rotate.

The controller accurately positions the internal damage of the petroleum pipeline according to the data sent by the vision monitoring mechanism 2. When the spindle housing 1 moves to the damaged part of the pipeline, the controller sends a signal to the air pump 5, the air pump 5 injects air into the air bag 7 after receiving the signal, and the air bag 7 expands and gradually enables the external glass fiber felt cloth 8 to abut against the damaged part of the pipeline.

When the glass fiber felt cloth 8 is bonded with the damaged part of the pipeline, the controller sends a signal to the air pump 5, the air pump 5 pumps out the air in the air bag 7 to enable the air bag to contract so as to be separated from the glass fiber felt cloth 8, and the glass fiber felt cloth 8 is left at the damaged part of the inner wall of the pipeline to finish the repairing task. Then the controller sends a signal to the travelling mechanism 4, and the travelling mechanism 4 receives the signal and then the whole driving device climbs out of the petroleum pipeline.

Can carry out further fixed to glass fiber felt through automatic sealing mechanism, can control main shaft housing through flexible adjustment mechanism and slide in the pipeline, can further support main shaft housing through lead screw lifting unit to can make the automatic slip of organism in the pipeline, great improvement to pipeline prosthetic efficiency.

Can carry out sealed glue coating to pasting the glass fiber felt cloth on the pipeline through clearance rubber coating mechanism 9, improvement glass fiber felt cloth's that can be great sealed effect.

Be provided with a pivoted brush 9b12 on clearance carousel 9b1, can clear up in the pipeline through the rotation of brush 9b12, clear up the sealed effect of the improvement glass fiber felt that the back can be great with the impurity clearance of pipeline inner wall, can be with sealed automatic coating on glass fiber felt through the rubber coating carousel, improvement glass fiber felt that can be great is to the sealed effect of pipeline damage position.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (8)

1. The utility model provides a damaged prosthetic devices's of non-excavation petroleum pipeline automatic sealing mechanism which characterized in that:

the automatic sealing mechanism comprises a telescopic adjusting mechanism (3), a repairing liquid spraying mechanism and a cleaning and gluing mechanism (9);

the repair liquid spraying machine body comprises a main shaft shell (1), an air pump (5), a power supply (6), an air bag (7) and glass fiber felt cloth (8);

the telescopic adjusting mechanism 3 comprises a lead screw lifting component (3 c), and a rotating roller (4 c) is arranged at the end part of the lead screw lifting component 3 c;

the cleaning and gluing mechanism (9) comprises a cleaning turntable (9 b 1) and a gluing turntable (9 c 1), a rotating brush (9 b 12) is arranged on the cleaning turntable (9 b 1), and a glue opening (9 c 4) is formed in the gluing mechanism (9 c 1);

the telescopic adjusting mechanisms (3) are arranged at two ends of the main shaft shell (1) and are coaxially arranged with the main shaft shell (1), and the moving direction of the telescopic adjusting mechanisms (3) is arranged along the radial direction of the main shaft shell (1);

the air bag (7) is wrapped on the outer wall of the main shaft shell (1) and is coaxially arranged with the main shaft shell (1);

the air pump (5) and the power supply (6) are both arranged in the main shaft shell (1), and the air pump (5) extends out of the main shaft shell (1) and is connected with the air bag (7);

an air pump (5) supplies air to the gluing turntable (9 c 1) and the cleaning turntable (9 b 1) to control the gluing turntable (9 c 1) and the cleaning turntable (9 b 1) to work;

the glass fiber felt cloth (8) is wrapped on the outer wall of the air bag (7), and the glass fiber felt cloth (8) is provided with the repairing liquid.

2. The automatic sealing mechanism of the trenchless petroleum pipeline damage repairing device as claimed in claim 1, wherein the main shaft housing (1) is further provided with a vent hole (1 a) and a limiting plate (1 b); the air holes (1 a) are formed in the spindle shell (1) to enable the air pump (5) to be communicated with the outside, and the limiting plates (1 b) are installed in the spindle shell (1) and are rotatably connected with the joints at the two ends of the telescopic adjusting mechanism (3).

3. The automatic sealing mechanism of the trenchless petroleum pipeline damage repairing apparatus as claimed in claim 1, wherein the telescopic adjusting mechanism (3) comprises a rotary driving assembly (3 a), a synchronous transmission assembly (3 b); synchronous drive subassembly (3 b) set up in main shaft housing (1) both ends and run through main shaft housing (1) department and rotate with main shaft housing (1) and be connected, install on synchronous drive subassembly (3 b) and be located the rear end of main shaft housing (1) rotation drive subassembly (3 a), rotation drive subassembly (3 a) output is connected with synchronous drive subassembly (3 b) input, at least three lead screw lifting unit (3 c) set up on synchronous drive subassembly (3 b) and output direction of motion along main shaft housing (1) radially around synchronous drive subassembly (3 b) axis, running gear (4) work end setting outwards is on lead screw lifting unit (3 c) output, rotation drive subassembly (3 a) are connected with the controller electricity.

4. The automatic sealing mechanism of the trenchless petroleum pipeline damage repair apparatus of claim 3, wherein the rotary drive assembly (3 a) comprises a first rotary drive (3 a 1), a drive protection housing (3 a 2) and a heat dissipation hole (3 a 3); the first rotary driver (3 a 1) is fixedly connected with the synchronous transmission assembly (3 b) and is positioned at the rear side of the spindle housing (1), the output end of the first rotary driver (3 a 1) is fixedly connected with the input end of the synchronous transmission assembly (3 b), the driver protection housing (3 a 2) covers the outside of the first rotary driver (3 a 1) and is fixedly connected with the synchronous transmission assembly (3 b), the heat dissipation hole (3 a 3) is formed in the driver protection housing (3 a 2), and the first rotary driver (3 a 1) is electrically connected with the controller.

5. The automatic sealing mechanism of the trenchless petroleum pipeline damage repair apparatus of claim 3, wherein the synchronous drive assembly (3 b) comprises a support housing (3 b 1), a driving shaft (3 b 2), a driven shaft (3 b 3), a driving right angle bevel gear (3 b 4) and a driven right angle bevel gear (3 b 5); the support shells (3 b 1) are hexagonal structures, a pair of support shells are arranged at two ends of the main shaft shell (1), the driving shaft (3 b 2) penetrates through the pair of support shells (3 b 1) and is rotationally connected with the main shaft shell (1), driven shafts (3 b 3) matched with the number of the screw lifting assemblies (3 c) are rotatably connected with the side walls of the supporting shells (3 b 1), the outer ends of the driven shafts are fixedly connected with the input ends of the screw lifting assemblies (3 c), a pair of driving right-angle bevel gears (3 b 4) are sleeved on the driving shafts (3 b 2) and are respectively positioned in the pair of supporting shells (3 b 1), driven right-angle bevel gears (3 b 5) are installed on one ends, close to the driving shafts (3 b 2), of the driven shafts (3 b 3), the driving right-angle bevel gears (3 b 4) are in meshing transmission with the driven right-angle bevel gears (3 b 5), the driving shafts (3 b 2) are installed on first rotary drivers (3 a 1), and the input ends of the driving shafts are fixedly connected with the output ends of the rotary driving.

6. The automatic sealing mechanism of the trenchless petroleum pipeline breakage repairing apparatus of claim 1, wherein the lead screw lifting assembly (3 c) comprises a guide housing (3 c 1), a driving lead screw (3 c 2), a slide block (3 c 3) and a connecting rod (3 c 4); the guide shell (3 c 1) is fixedly connected with the synchronous transmission assembly (3 b) and extends along the radial direction of the main shaft shell (1), two ends of a driving lead screw (3 c 2) are rotatably connected with two ends of the guide shell (3 c 1), the driving lead screw (3 c 2) is fixedly connected with the output end of the synchronous transmission assembly (3 b), a sliding block (3 c 3) is slidably connected with the guide shell (3 c 1) and is in threaded connection with the driving lead screw (3 c 2), a connecting rod (3 c 4) is fixedly connected with the part of a driven shaft (3 b 3) which is positioned outside a driving shaft (3 b 2), and the bottom of the connecting rod (3 c 4) is fixedly connected with the travelling mechanism (4);

the connecting rod (3 c 4) is provided with a guide part which is connected with four sides of the guide shell (3 c 1) in a sliding way, and the guide part is a pair of strip-shaped plates which are vertical to each other.

7. The automatic sealing mechanism for the trenchless petroleum pipeline damage repairing apparatus of claim 1, wherein the cleaning and gluing mechanism (9) further comprises a mounting shaft (9 a 1), the cleaning and gluing mechanism (9 b 1) and the gluing mechanism (9 c 1) are respectively disposed on the mounting shaft (9 a 1), a turntable rotating groove (9 b 2) is disposed on the cleaning and gluing mechanism (9 b 1), a supporting rotating ring (9 b 9) is disposed in the turntable rotating groove (9 b 2), a rotating ring (9 b 3) is disposed in the turntable rotating groove (9 b 2), a plurality of first rotating shafts (9 b 8) are disposed in an inner ring of the rotating ring (9 b 3), a rotating roller (9 b 10) is disposed on each first rotating shaft (9 b 8), the rollers (9 b 10) respectively rotate on the supporting rotating ring (9 b 9), and a circle of exhaust holes (4) are disposed in each rotating ring (9 b 3), the exhaust holes (9 b 4) are arranged in an inclined manner, the brush (9 b 12) is distributed on the rotating ring (9 b 3), one side of the rotating disc rotating groove (9 b 2) is provided with a plurality of air injection holes (9 b 5), the other side of the rotating disc rotating groove (9 b 2) is provided with an exhaust groove (9 b 11), the cleaning rotating disc (9 b 1) is internally provided with a connecting air hole (9 b 6), and the cleaning rotating disc (9 b 1) is provided with a first air hole pipe (9 b 7) correspondingly communicated with the connecting air hole (9 b 6);

a glue cavity (9 c 2) is arranged in the glue coating turntable (9 c 1), a plurality of glue openings (9 c 4) are arranged and are respectively communicated with the glue cavity (9 c 2) correspondingly, a glue head is arranged on each glue opening (9 c 4), a rubber air bag (9 c 3) is arranged in the glue cavity (9 c 2), and a second air pipe (9 c 5) is arranged on each rubber air bag (9 c 3);

the mounting shaft (9 a 1) is provided with a clamping groove (9 a 2), and the mounting shaft (9 a 1) is also provided with a mounting hole (9 a 3) corresponding to the clamping groove (9 a 2).

8. An apparatus for repairing a damaged portion of a trenchless petroleum pipeline comprising an automatic sealing mechanism for an apparatus for repairing a damaged portion of a trenchless petroleum pipeline as claimed in any one of claims 1 to 7.

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