CN112517673A - Intelligent pipeline straightening equipment - Google Patents

Abstract

The invention relates to a pipeline straightening device, in particular to an intelligent pipeline straightening device which comprises a compression conveying mechanism, a linkage rust removal mechanism and a heat conduction mechanism, wherein the device can straighten a pipeline, can remove rust for the pipeline after the pipeline is straightened, can coat rust-proof liquid for the pipeline after the pipeline is straightened, can heat a bend point of the pipeline to help the straightening function, can heat the pipeline to help the solidification of the rust-proof liquid after the pipeline is coated with the rust-proof liquid, is connected with the linkage rust removal mechanism, is connected with a conduction mechanism, and is connected with the compression conveying mechanism.

Description

Intelligent pipeline straightening equipment

Technical Field

The invention relates to sampling equipment, in particular to intelligent pipeline straightening equipment.

Background

In the process of pipeline alignment, the bend point within the elastic range of the pipeline often appears and can not be effectively aligned, but no well-taught pipeline alignment equipment exists in the market, so the intelligent pipeline alignment equipment is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing intelligent pipeline straightening equipment, the equipment can straighten a pipeline, the equipment can remove rust for the pipeline after the pipeline is straightened, the equipment can paint antirust liquid on the pipeline after the pipeline is straightened, the equipment can heat a bent point of the pipeline to help straightening, and the equipment can heat the pipeline to help the solidification of the antirust liquid after the pipeline is painted with the antirust liquid.

In order to solve the technical problems, the invention relates to a pipeline straightening device, and particularly relates to an intelligent pipeline straightening device which comprises a compression conveying mechanism, a linkage rust removing mechanism and a heat conduction mechanism.

The pressing and conveying mechanism is connected with the linkage rust removing mechanism, the linkage rust removing mechanism is connected with the conduction mechanism, and the conduction mechanism is connected with the pressing and conveying mechanism.

As a further optimization of the technical scheme, the intelligent pipeline straightening device comprises a motor, a motor shaft, a belt a, a connecting shaft a, a friction wheel a, a connecting shaft b, a belt b, a connecting shaft c, a limiting ring, a belt c, a conveying block, a fixed limiting block, a sliding limiting block, a pressing shaft, a pressing spring, a sealing plate, a limiting strip of the sealing plate, a connecting plate a, a connecting plate b, a connecting plate c and a connecting plate d, wherein the motor is connected with the motor shaft, the motor shaft is connected with the connecting plate b, the motor shaft is in friction connection with the belt a, the belt a is in friction connection with the connecting shaft a, the connecting shaft a is connected with the friction wheel a, the connecting shaft a is in bearing connection with the connecting plate b, the connecting shaft a is in friction connection with the belt c, the friction wheel a is in friction connection with the connecting shaft b, the connecting shaft b is connected with a limiting ring, the connecting shaft b is connected with a fixed limiting block bearing, the connecting shaft b is connected with a sliding limiting block in a sliding manner, the connecting shaft b is connected with a sealing plate bearing, the connecting shaft b is connected with a connecting plate b in a sliding manner, the belt b is connected with the connecting shaft c in a friction manner, the connecting shaft c is connected with the limiting ring, the connecting shaft c is connected with the fixed limiting block bearing, the connecting shaft c is connected with the sliding limiting block in a sliding manner, the connecting shaft c is connected with the sealing plate bearing, the connecting shaft c is connected with the connecting plate b in a sliding manner, the connecting shaft c is connected with the connecting plate c in a sliding manner, the limiting ring is connected with the connecting plate b in a sliding manner, the fixed limiting block is connected with the connecting plate c, the sliding limiting block is, the sealing plate is connected with the sealing plate limiting strip in a sliding mode, the sealing plate is connected with the connecting plate c in a sliding mode, the sealing plate limiting strip is connected with the connecting plate c, the connecting plate a is connected with the connecting plate c, the connecting plate b is connected with the connecting plate d, and the connecting plate c is connected with the connecting plate d.

As a further optimization of the technical scheme, the invention relates to intelligent pipeline straightening equipment, wherein a linkage rust removing mechanism comprises a first belt, a first connecting shaft, a large gear, a small gear with a shaft, a propeller, a conical water inlet ring, a water tank, a water pipe joint, a water pipe sleeve, a fixed rotating ring, a connecting ring a, a connecting ring b, a cotton ring, a rust removing ring, a mounting column, a feed pipe, a conical feed pipe, a friction ring a, a second connecting shaft, a second friction ring, a first connecting plate, a water tank sealing plate, a second belt, a third connecting shaft and a third belt, wherein the first belt is in friction connection with a motor shaft, the first belt is in friction connection with the first connecting shaft, the first connecting shaft is connected with the large gear, the first connecting shaft is connected with a water tank bottom bearing, the first connecting shaft is connected with a water tank sealing plate bearing, the large gear is meshed with the small gear with, the propeller is connected with a shaft on the pinion with the shaft, the conical water inlet ring is connected with a water tank sealing plate, the conical water inlet ring is connected and communicated with a water pipe joint, the water tank is connected with a connecting plate b, the water tank is connected with the water tank sealing plate, the water pipe joint is connected and communicated with a water pipe, the water pipe is connected and communicated with a water pipe sleeve, the water pipe sleeve is connected and communicated with a fixed rotating ring, the fixed rotating ring is connected with a connecting ring a bearing, the fixed rotating ring is connected with a connecting ring b bearing, the fixed rotating ring is connected with a mounting column, the connecting ring a is connected with the connecting ring b, the connecting ring a is in friction connection with a friction ring II, one connecting ring b is connected with a cotton ring, the other connecting ring is connected with a rust removing ring, the rust removing ring is connected with a feed pipe, the upper mounting column is connected with the connecting plate b, the lower mounting column is connected with a, the friction ring a is in friction connection with the belt II, the connecting shaft II is connected with the friction ring II, the connecting shaft II is connected with the connecting plate I, the upper side of the connecting plate I is connected with the connecting plate B, the lower side of the connecting plate I is connected with the connecting plate C, the belt II is in friction connection with the connecting shaft III, the connecting shaft III is in friction connection with the belt III, the connecting shaft III is connected with the connecting plate B, the connecting shaft III is in bearing connection with the connecting plate C, and the connecting plate C is in.

As a further optimization of the technical scheme, the invention relates to intelligent pipeline straightening equipment, wherein a conducting mechanism comprises a large gear a, a small gear a, a transmission shaft a, a propeller, an electric heater, an air leakage plate, a mounting seat, an air inlet ring, a conical air inlet ring, a mounting plate a, an air outlet pipe, an air delivery pipe, an air sealing plate a, an air sealing plate b, an air inlet pipe a, a mounting plate b, a sliding shaft of the mounting plate b, a linkage spring, an air sealing strip, a mounting plate c, a mounting plate d, an air inlet pipe b and an air inlet pipe c, the large gear a is meshed with the small gear, the large gear a is connected with a connecting shaft III, the small gear a is connected with the transmission shaft a, a gap is arranged between the transmission shaft a and the electric heater for air circulation, the transmission shaft a is connected with the air leakage plate bearing, the transmission shaft a, the air leakage plate is connected with the mounting seat, the mounting seat is connected with a connecting plate b, the mounting seat is connected with an air inlet ring, the air inlet ring is connected with a conical air inlet ring, the conical air inlet ring is connected with a mounting plate a, the mounting plate a is connected with and communicated with an air outlet pipe, the air outlet pipe is connected with and communicated with an air delivery pipe, two ends of the air outlet pipe are respectively connected with a gas sealing plate a and a gas sealing plate b, the air outlet pipe is connected with an air inlet pipe a, the air inlet pipe a is connected with and communicated with a gas sealing strip, the mounting plate b is connected with a mounting plate b sliding shaft, the mounting plate b is connected with a connecting plate c, the mounting plate b sliding shaft is connected with a gas sealing strip, the linkage spring is in a normal state that the spring is not stressed, the linkage spring is sleeved on the mounting plate b sliding shaft and limited on the gas sealing, mounting panel c is connected with mounting panel d, and mounting panel c is connected and is communicate with intake pipe b, and mounting panel d is connected with connecting plate c, and intake pipe c one end is connected and is communicated with the gas-supply pipe, and the other end passes connecting plate c.

As a further optimization of the technical scheme, the intelligent pipeline straightening device is characterized in that a large number of resistors are arranged in the electric heater, and after the power supply is switched on, the circular metal heat conduction layer on the upper portion of the electric heater can emit heat.

The intelligent pipeline straightening equipment has the beneficial effects that:

according to the intelligent pipeline straightening equipment, the pipeline can be straightened by the equipment, the pipeline can be derusted by the equipment after being straightened, the pipeline can be coated with the antirust liquid after being straightened by the equipment, the bend point of the pipeline can be heated and helped to be straightened by the equipment, and the pipeline can be heated and helped to be solidified by the antirust liquid after being coated with the antirust liquid.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic structural diagram of an intelligent pipeline straightening device according to the present invention.

Fig. 2 is a schematic structural diagram of an intelligent pipeline straightening device according to the present invention.

Fig. 3 is a schematic structural diagram of a pressing transmission mechanism 1 of an intelligent pipe straightening device according to the present invention.

Fig. 4 is a schematic structural diagram of a second compression transmission mechanism 1 of the intelligent pipe straightening device according to the present invention.

Fig. 5 is a third schematic structural diagram of the pressing transmission mechanism 1 of the intelligent pipe straightening device of the present invention.

Fig. 6 is a fourth schematic structural diagram of the pressing transmission mechanism 1 of the intelligent pipe straightening device of the present invention.

Fig. 7 is a fifth schematic structural diagram of the pressing transmission mechanism 1 of the intelligent pipe straightening device of the present invention.

Fig. 8 is a first structural schematic diagram of a linkage rust removing mechanism 2 of the intelligent pipeline straightening device.

Fig. 9 is a structural schematic diagram II of a linkage rust removing mechanism 2 of the intelligent pipeline straightening device.

Fig. 10 is a third structural schematic diagram of a linkage rust removing mechanism 2 of the intelligent pipeline straightening device.

Fig. 11 is a fourth structural schematic diagram of the linkage rust removing mechanism 2 of the intelligent pipeline straightening device.

Fig. 12 is a fifth structural schematic diagram of the linkage rust removing mechanism 2 of the intelligent pipeline straightening device.

Fig. 13 is a sixth schematic structural diagram of the linkage rust removing mechanism 2 of the intelligent pipeline straightening device.

Fig. 14 is a schematic structural diagram of water tanks 2-7 of an intelligent pipe straightening device according to the present invention.

Fig. 15 is a schematic structural diagram of a heat conduction mechanism 3 of an intelligent pipe straightening device according to the first embodiment of the present invention.

Fig. 16 is a schematic structural diagram of a heat conduction mechanism 3 of an intelligent pipe straightening device according to the second embodiment of the present invention.

Fig. 17 is a third schematic structural diagram of a heat conduction mechanism 3 of an intelligent pipe straightening device according to the present invention.

Fig. 18 is a fourth schematic structural diagram of the heat conduction mechanism 3 of the intelligent pipe straightening device according to the present invention.

In the figure: a pressing transmission mechanism 1; a motor 1-1; a motor shaft 1-2; belt a 1-3; connecting shaft a 1-4; friction wheel a 1-5; connecting shaft b 1-6; belt b 1-7; connecting shaft c 1-8; 1-9 parts of a limiting ring; belt c 1-10; transfer blocks 1-11; fixing a limiting block 1-12; a sliding stopper 1-13; pressing the shafts 1-14; pressing the springs 1-15; sealing plates 1 to 16; sealing plate limit strips 1-17; web a 1-18; connecting plate b 1-19; connecting plates c 1-20; connecting plates d 1-21; a linkage rust removal mechanism 2; 2-1 of a first belt; a first connecting shaft 2-2; 2-3 of a bull gear; pinion 2-4 with shaft; 2-5 of a propeller; 2-6 of a conical water inlet ring; 2-7 of a water tank; 2-8 of water pipe joint; 2-9 parts of a water pipe; 2-10 parts of water pipe sleeve; 2-11 parts of a fixed rotating ring; a connecting ring a 2-12; a connecting ring b 2-13; 2-14 parts of cotton rings; 2-15 parts of derusting ring; mounting posts 2-16; a feed pipe 2-17; a conical feed pipe 2-18; friction rings a 2-19; 2-20 parts of a connecting shaft II; 2-21 parts of a friction ring II; 2-22 of a first connecting plate; 2-23 parts of a water tank sealing plate; 2-24 parts of a second belt; connecting shafts III 2-25; a third belt 2-26; a heat conduction mechanism 3; gearwheel a 3-1; pinion a 3-2; a transmission shaft a 3-3; 3-4 parts of a propeller; 3-5 parts of an electric heater; 3-6 of an air leakage plate; 3-7 of a mounting seat; 3-8 parts of an air inlet ring; 3-9 parts of a conical air inlet ring; mounting plate a 3-10; 3-11 parts of an air outlet pipe; 3-12 gas transmission pipes; gas sealing plate a 3-13; gas sealing plate b 3-14; an inlet pipe a 3-15; mounting plate b 3-16; mounting plate b sliding shafts 3-17; linkage springs 3-18; 3-19 parts of gas sealing strips; mounting plate c 3-20; mounting plate d 3-21; intake pipes b 3-22; and an intake pipe c 3-23.

Detailed Description

The first embodiment is as follows:

the present invention relates to a pipe straightening device, and more particularly, to an intelligent pipe straightening device, which includes a pressing and conveying mechanism 1, a linkage rust removing mechanism 2, and a heat conduction mechanism 3, and is capable of straightening a pipe, removing rust from the pipe after the pipe is straightened, applying a rust preventing liquid to the pipe after the pipe is straightened, heating the bend point of the pipe, assisting and straightening, and heating the pipe after applying the rust preventing liquid to the pipe, and solidifying the rust preventing liquid.

The pressing and conveying mechanism 1 is connected with the linkage rust removing mechanism 2, the linkage rust removing mechanism 2 is connected with the conducting mechanism 3, and the conducting mechanism 3 is connected with the pressing and conveying mechanism 1.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18, and the embodiment further describes the embodiment, where the pressing transmission mechanism 1 includes a motor 1-1, a motor shaft 1-2, a belt a1-3, a connecting shaft a1-4, a friction wheel a1-5, a connecting shaft b1-6, a belt b1-7, a connecting shaft c1-8, a limit ring 1-9, a belt c1-10, a transmission block 1-11, a fixed limit block 1-12, a sliding limit block 1-13, a pressing shaft 1-14, a pressing spring 1-15, a seal plate 1-16, a seal plate limit bar 1-17, a connecting plate a1-18, a seal plate a seal block, A connecting plate b1-19, a connecting plate c1-20 and a connecting plate d1-21, wherein a motor 1-1 is connected with a motor shaft 1-2, the motor 1-1 is connected with a connecting plate b1-19, the motor shaft 1-2 is in friction connection with a belt a1-3, the belt a1-3 is in friction connection with a connecting shaft a1-4, a connecting shaft a1-4 is connected with a friction wheel a1-5, a connecting shaft a1-4 is in bearing connection with a connecting plate b1-19, a connecting shaft a1-4 is in friction connection with a belt c1-10, a friction wheel a1-5 is in friction connection with a connecting shaft b1-6, a b1-6 and a belt b1-7 are in friction connection, a connecting shaft b1-6 is connected with a limiting ring 1-9, a connecting shaft b1-6 is connected with a limiting ring 1-9, a connecting shaft b1-6 is, connecting shaft b1-6 is connected with sliding limiting blocks 1-13 in a sliding mode, connecting shaft b1-6 is connected with sealing plates 1-16 in a bearing mode, connecting shaft b1-6 is connected with connecting plates b1-19 in a sliding mode, connecting shaft b1-6 is connected with connecting plates c1-20 in a sliding mode, belt b1-7 is connected with connecting shaft c1-8 in a friction mode, connecting shaft c1-8 is connected with limiting rings 1-9, connecting shaft c1-8 is connected with limiting rings 1-9, connecting shaft c1-8 is connected with fixed limiting blocks 1-12 in a bearing mode, connecting shaft c1-8 is connected with sliding limiting blocks 1-13 in a sliding mode, connecting shaft c1-8 is connected with sealing plates 1-16 in a bearing mode, connecting shaft c1-8 is connected with connecting plates b1-19 in a sliding mode, connecting shaft c1-8 is connected with, limiting rings 1-9 are connected with connecting plates b1-19 in a sliding manner, fixed limiting blocks 1-12 are connected with connecting plates c1-20, sliding limiting blocks 1-13 are connected with pressing shafts 1-14, sliding limiting blocks 1-13 are connected with connecting plates c1-20 in a sliding manner, pressing shafts 1-14 are connected with connecting plates a1-18 in a sliding manner, pressing springs 1-15 are sleeved on the pressing shafts 1-14 and limited on the sliding limiting blocks 1-13 and the connecting plates a1-18, sealing plates 1-16 are connected with sealing plate limiting strips 1-17 in a sliding manner, sealing plates 1-16 are connected with connecting plates c1-20 in a sliding manner, sealing plate limiting strips 1-17 are connected with connecting plates c1-20, connecting plates a1-18 are connected with connecting plates c1-20, connecting plates b1-19 are connected with connecting plates d1-21, the connecting plate c1-20 is connected with the connecting plate d1-21, the device can straighten the pipeline, the motor 1-1 works to drive the motor shaft 1-2 to rotate anticlockwise, the motor shaft 1-2 rotates to drive the connecting shaft a1-4 close to the motor 1-1 to rotate through the belt a1-3, the connecting shaft a1-4 rotates to drive the friction wheel a1-5 to rotate, the friction wheel a1-5 rotates to drive the connecting shaft b1-6 to rotate in the opposite direction, the connecting shaft b1-6 rotates to drive the connecting shaft c1-8 to rotate through the belt b1-7, the other connecting shaft a1-4 is driven to rotate through the belt c1-10 in the rotating process of the connecting shaft a1-4, and the connecting shafts a1-4 are driven to rotate one by one under the action of all the belts c1, after all the connecting shafts a1-4 rotate, all the connecting shafts b1-6 and the connecting shafts c1-8 are conducted and rotated, when the connecting shafts b1-6 and the connecting shafts c1-8 rotate, the conveying blocks 1-11 rotate along with the rotating, a group of two conveying blocks 1-11 rotate reversely at the same time, at the moment, a pipeline to be straightened is placed in circular grooves on the group of two conveying blocks 1-11, the pipe grooves are conveyed towards the direction of the motor 1-1, when a bent point of the pipeline is contacted with any one conveying block 1-11, the conveying blocks 1-11 are pressed, and under the action of the sliding limiting blocks 1-13, the pressing shafts 1-14 and the pressing springs 1-15, the connecting shafts b1-6 of the conveying blocks 1-11 or the connecting shafts c1-8 slide on the connecting plates b1-19 and the connecting plates c1-20, and the pipe is straightened during the transfer of the transfer blocks 1-11 at the pipe bending point portion under the pressure of the pressure springs 1-15.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18, and the embodiment further describes the embodiment, and the linkage rust removing mechanism 2 comprises a belt I2-1, a connecting shaft I2-2, a gear wheel 2-3, a shaft pinion 2-4, a propeller 2-5, a conical water inlet ring 2-6, a water tank 2-7, a water pipe joint 2-8, a water pipe 2-9, a water pipe sleeve 2-10, a fixed rotating ring 2-11, a connecting ring a2-12, a connecting ring b2-13, a cotton ring 2-14, a rust removing ring 2-15, a mounting column 2-16, a feed pipe 2-17, a conical feed pipe 2-18, a rust removing ring 2-18, A friction ring a2-19, a connecting shaft II 2-20, a friction ring II 2-21, a connecting plate I2-22, a water tank sealing plate 2-23, a belt II 2-24, a connecting shaft III 2-25 and a belt III 2-26, wherein the belt I2-1 is in friction connection with a motor shaft 1-2, the belt I2-1 is in friction connection with the connecting shaft I2-2, the connecting shaft I2-2 is connected with a gearwheel 2-3, the connecting shaft I2-2 is connected with a bearing at the bottom of the water tank 2-7, the connecting shaft I2-2 is connected with a bearing of the water tank sealing plate 2-23, the gearwheel 2-3 is meshed with a pinion 2-4 with a shaft, a shaft on the pinion 2-4 with a shaft is connected with a bearing at the bottom of the water tank 2-7, a shaft on the pinion 2-4 with a, the propeller 2-5 is connected with a shaft on a pinion 2-4 with a shaft, the conical water inlet ring 2-6 is connected with a water tank sealing plate 2-23, the conical water inlet ring 2-6 is connected and communicated with a water pipe connector 2-8, the water tank 2-7 is connected with a connecting plate b1-19, the water tank 2-7 is connected with the water tank sealing plate 2-23, the water pipe connector 2-8 is connected and communicated with a water pipe 2-9, the water pipe 2-9 is connected and communicated with a water pipe sleeve 2-10, the water pipe sleeve 2-10 is connected with a connecting plate b1-19, the water pipe sleeve 2-10 is connected and communicated with a fixed rotating ring 2-11, the fixed rotating ring 2-11 is connected with a2-12 bearing, the fixed rotating ring 2-11 is connected with a connecting ring b2-13 bearing, the fixed rotating ring 2-11 is connected with a mounting column 2-16, connecting rings a2-12 are connected with connecting rings b2-13, connecting rings a2-12 are connected with friction rings II 2-21 in a friction mode, one connecting ring b2-13 is connected with cotton rings 2-14, the other connecting ring is connected with a derusting ring 2-15, the derusting ring 2-15 is connected with a feeding pipe 2-17, upper side mounting columns 2-16 are connected with connecting plates b1-19, lower side mounting columns 2-16 are connected with connecting plates c1-20, the feeding pipe 2-17 is connected with a tapered feeding pipe 2-18, friction rings a2-19 are connected with connecting shafts II 2-20, friction rings a2-19 are connected with belts II 2-24 in a friction mode, connecting shafts II 2-20 are connected with friction rings II 2-21, connecting shafts II 2-20 are connected with connecting plates I2-22 in a bearing mode, the upper sides of connecting plates I2-22 are connected with connecting plates b1-19, and the lower sides of connecting plates I2-22 are Then, the belt II 2-24 is in friction connection with the connecting shaft III 2-25, the connecting shaft III 2-25 is in friction connection with the belt III 2-26, the connecting shaft III 2-25 is in bearing connection with the connecting plate b1-19, the connecting shaft III 2-25 is in bearing connection with the connecting plate c1-20, the connecting plate c1-20 is in friction connection with the motor shaft 1-2, the device can remove rust for the pipeline after straightening the pipeline, the device can apply rust-proof liquid for the pipeline after straightening the pipeline, the motor 1-1 works to drive the motor shaft 1-2 to rotate anticlockwise, the motor shaft 1-2 rotates to drive the connecting shaft I2-2 to rotate through the belt I2-1, the connecting shaft I2-2 rotates to drive the bull gear 2-3 to rotate, the bull gear 2-3 rotates to drive the belt shaft pinion gear 2-, the small gear 2-4 with a shaft rotates to drive the propeller 2-5 to rotate, when the propeller 2-5 rotates, the derusting liquid in the water tank 2-7 is conveyed into the conical water inlet ring 2-6 at the upper side, the derusting liquid is injected into the water pipe sleeve 2-10 under the guidance of the conical water inlet ring 2-6, the water pipe joint 2-8 and the water pipe 2-9, the derusting liquid in the water pipe sleeve 2-10 directly falls onto the cotton ring 2-14, when the motor shaft 1-2 rotates, the connecting shaft III 2-25 is driven to rotate through the belt III 2-26, the connecting shaft III 2-25 rotates and drives the other connecting shaft III 2-25 to rotate through the belt II 2-24, when the connecting shaft II 2-24 follows the movement, the friction ring a2-19 also rotates, when the friction ring a2-19 rotates, the two friction ring II 2-21 rotates through the belt II 2-20, the second friction ring 2-21 drives the connecting ring a2-12 to rotate when rotating, the connecting ring a2-12 rotates to drive the connecting ring b2-13 to rotate, the two connecting rings b2-13 respectively drive the cotton rings 2-14 and the derusting rings 2-15 to rotate when rotating, when the equipment straightens the pipeline, the straightened pipeline is conveyed into the conical feed pipe 2-18 and enters the cotton rings 2-14 and the derusting rings 2-15 under the guide of the feed pipe 2-17, under the action of the derusting rings 2-15, the embroidery on the pipeline is removed, and under the action of the cotton rings 2-14 invaded by the derusting liquid, the pipeline is coated with the derusting liquid.

The fourth concrete implementation mode:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18, and the present embodiment further describes the present embodiment, where the conducting mechanism 3 includes a large gear a3-1, a small gear a3-2, a transmission shaft a3-3, a propeller 3-4, an electric heater 3-5, an air leakage plate 3-6, a mounting seat 3-7, an air inlet ring 3-8, a tapered air inlet ring 3-9, a mounting plate a3-10, an air outlet pipe 3-11, an air inlet pipe 3-12, a gas sealing plate a3-13, a gas sealing plate b3-14, an air inlet pipe a3-15, a mounting plate b3-16, a mounting plate b sliding shaft 3-17, a linkage spring 3-, 3-19 parts of gas sealing strips, c3-20 parts of mounting plates, d3-21 parts of mounting plates, b3-22 parts of gas inlet pipes, c3-23 parts of gas inlet pipes, a gearwheel a3-1 is meshed with a pinion 3-2 part of the gas inlet pipes, a gearwheel a3-1 part of the gas inlet pipes is connected with a connecting shaft III 2-25 part of the connecting shaft, a pinion 3-2 part of the gas inlet pipes is connected with a driving shaft a3-3 part of the driving shaft a3-3 part of the electric heater 3-5 part of the electric heater, a driving shaft a3-3 part of the driving shaft is connected with a wind leaking plate 3-6 bearing, a driving shaft a3-3 part of the driving shaft is connected with a 1-19 bearing, a driving shaft a3-3 part of the electric heater is connected with a propeller 3-4 part of the wind leaking plate 3-6 part of the electric heater, the mounting seat 3-7 is connected with the air inlet ring 3-8, the air inlet ring 3-8 is connected with the conical air inlet ring 3-9, the conical air inlet ring 3-9 is connected with the mounting plate a3-10, the mounting plate a3-10 is connected and communicated with the air outlet pipe 3-11, the air outlet pipe 3-11 is communicated with the air pipe 3-12, two ends of the air outlet pipe 3-11 are respectively connected with the air sealing plate a3-13 and the air sealing plate b3-14, the air outlet pipe 3-11 is connected with the air inlet pipe a3-15, the air inlet pipe a3-15 is connected with the air sealing strip 3-19 in a sliding manner, the air inlet pipe a3-15 is connected and communicated with the connecting plate c1-20, the mounting plate b3-16 is connected with the mounting plate b sliding shaft 3-17, the mounting plate b3-16 is, the sliding shaft 3-17 of the mounting plate b is connected with the gas sealing strip 3-19, the linkage spring 3-18 is in a normal state that the spring is not stressed, the linkage spring 3-18 is sleeved on the sliding shaft 3-17 of the mounting plate b and limited on the gas sealing strip 3-19 and the connecting plate a1-18, the gas sealing strip 3-19 is in sliding connection with the mounting plate c3-20, the gas sealing strip 3-19 is in sliding connection with the mounting plate d3-21, the mounting plate c3-20 is connected with the mounting plate d3-21, the mounting plate c3-20 is connected and communicated with the air inlet pipe b3-22, the mounting plate d3-21 is connected with the connecting plate c1-20, one end of the air inlet pipe c3-23 is connected and communicated with the air pipe 3-12, the other end of the air inlet pipe passes through the connecting plate c1-20, the equipment can heat the pipeline to help the solidification of the antirust liquid after the pipeline is coated with the antirust liquid, in the process of removing rust on the pipeline by the equipment, a connecting shaft III 2-25 is in a rotating state, the connecting shaft III 2-25 rotates to drive a large gear a3-1 to rotate, the large gear a3-1 rotates to drive a small gear a3-2 to rotate in an accelerated manner, the small gear a3-2 rotates to drive a transmission shaft a3-3 to rotate, the transmission shaft a3-3 rotates to drive a propeller 3-4 to rotate, the propeller 3-4 rotates to blow heat generated by an electric heater 3-5 which is connected with a power supply to the direction of a3-10 of a mounting plate a, hot air is blown into an air delivery pipe 3-12 under the guide of an air outlet pipe 3-11, a part of hot air in the air delivery pipe 3-12 is discharged through an air inlet pipe c3-23, and hot air discharged by the air inlet pipe c 36, when the conveying blocks 1-11 are pressed at the bend point of the pipeline, the conveying blocks 1-11 are pressed, the conveying blocks 1-11 drive the connecting shafts b1-6 or the connecting shafts c1-8 to slide on the connecting plates b1-19 and the connecting plates c1-20, the connecting shafts b1-6 or the connecting shafts c1-8 move to drive the sliding limit blocks 1-13 at the same side, the sliding limit blocks 1-13 press the mounting plates b3-16 through the pressing shafts 1-14, the mounting plates b3-16 move to drive the mounting plates b sliding shafts 3-17, the mounting plates b sliding shafts 3-17 move to drive the gas sealing strips 3-19 to move, and holes below the gas sealing strips 3-19 leak when the gas sealing strips 3-19 move, at the moment, hot air in the air delivery pipes 3-12 passes through the air inlet pipes a3-15 and the air inlet pipes b3-22 at the positions of the air sealing strips 3-19 to blow the hot air to the pipelines.

The fifth concrete implementation mode:

in the following, referring to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17 and 18, the present embodiment will be described, wherein a plurality of resistors are disposed in the electric heater 3-5, and the upper circular metal heat conductive layer of the electric heater 3-5 can emit heat after power is turned on.

The working principle of the device is as follows: the device can straighten the pipeline, the motor 1-1 works to drive the motor shaft 1-2 to rotate anticlockwise, the motor shaft 1-2 rotates to drive the connecting shaft a1-4 close to the motor 1-1 to rotate through the belt a1-3, the connecting shaft a1-4 rotates to drive the friction wheel a1-5 to rotate, the friction wheel a1-5 rotates to drive the connecting shaft b1-6 to rotate reversely, the connecting shaft b1-6 rotates to drive the connecting shaft c1-8 to rotate through the belt b1-7, the connecting shaft a1-4 also drives the other a1-4 to rotate through the belt c1-10 in the rotating process, the connecting shaft a1-4 is driven to rotate one by the action of all the belts c1-10, all the connecting shafts b1-6 and the connecting shaft c1-8 are conducted to rotate after all the connecting shafts a1-4 rotate, when the connecting shaft b1-6 and the connecting shaft c1-8 rotate, the conveying blocks 1-11 rotate along with the rotation, one group of two conveying blocks 1-11 rotate reversely, at the same time, a pipeline to be straightened is placed in circular grooves on one group of two conveying blocks 1-11, pipe grooves are conveyed towards the direction of the motor 1-1, when a bent point of the pipeline is contacted with any one conveying block 1-11, the conveying blocks 1-11 are pressed, under the action of the sliding limiting blocks 1-13, the pressing shafts 1-14 and the pressing springs 1-15, the connecting shaft b1-6 or the connecting shaft c1-8 connected with the conveying blocks 1-11 slides on the connecting plates b1-19 and the connecting plates c1-20, and under the pressing of the pressing springs 1-15, the bent point part of the pipeline is pressed by the pressing springs 1-15, in the conveying process of the conveying blocks 1-11, the pipeline is straightened, the device can remove rust for the pipeline after the pipeline is straightened, the device can brush rust-proof liquid for the pipeline after the pipeline is straightened, the motor 1-1 works to drive the motor shaft 1-2 to rotate anticlockwise, the motor shaft 1-2 rotates to drive the connecting shaft I2-2 to rotate through the belt I2-1, the connecting shaft I2-2 rotates to drive the big gear 2-3 to rotate, the big gear 2-3 rotates to drive the small gear 2-4 with the shaft to rotate reversely, the small gear 2-4 with the shaft rotates to drive the propeller 2-5 to rotate, when the propeller 2-5 rotates, the rust-removing liquid in the water tank 2-7 is transmitted to the conical water inlet ring 2-6 at the upper side, the rust-removing liquid is injected into the water pipe sleeve 2-10 under the guidance of the conical water inlet ring 2-6, the water pipe joint 2-8 and the water pipe, the derusting liquid in the water pipe sleeve 2-10 directly falls onto the cotton ring 2-14, when the motor shaft 1-2 rotates, the belt III 2-26 drives the connecting shaft III 2-25 to rotate, the connecting shaft III 2-25 rotates and drives the other connecting shaft III 2-25 to rotate through the belt II 2-24, when the belt II 2-24 follows the movement, the friction ring a2-19 is also driven to rotate, when the friction ring a2-19 rotates, the connecting shaft II 2-20 drives the two friction rings II 2-21 to rotate, when the friction ring II 2-21 rotates, the connecting ring a2-12 is driven to rotate, when the connecting ring a2-12 rotates, the connecting ring b2-13 rotates, when the two connecting rings b2-13 rotate, the cotton ring 2-14 and the derusting ring 2-15 are respectively driven to rotate, when the device straightens the pipeline, the straightened pipeline is conveyed into the conical feed pipe 2-18 and enters the cotton ring 2-14 and the derusting ring 2-15 under the guide of the feed pipe 2-17, the embroidery on the pipeline is removed under the action of the derusting ring 2-15, the pipeline is coated with the derusting liquid under the action of the cotton ring 2-14 soaked by the derusting liquid, the device can heat the bend point of the pipeline to help straightening, the device can heat the pipeline after being coated with the derusting liquid to help the solidification of the derusting liquid, in the process of derusting the pipeline by the device, the connecting shaft three 2-25 is in a rotating state, the connecting shaft three 2-25 rotates to drive the large gear a3-1 to rotate, the large gear a3-1 rotates to drive the small gear a3-2 to accelerate to rotate, the small gear a3-2 rotates to drive the transmission shaft a3-3 to rotate, the propeller 3-4 is driven to rotate by the rotation of the transmission shaft a3-3, when the propeller 3-4 rotates, heat generated by an electric heater 3-5 which is connected with a power supply is blown towards the direction of a mounting plate a3-10, hot air is blown into an air pipe 3-12 under the guide of an air outlet pipe 3-11, part of the hot air in the air pipe 3-12 is discharged through an air inlet pipe c3-23, the hot air discharged by the air inlet pipe c3-23 is directly blown to a pipeline which is brushed with rust removing liquid, when a pipeline bending point presses the conveying block 1-11, the conveying block 1-11 is pressed, the conveying block 1-11 drives the connecting shaft b1-6 or the connecting shaft c1-8 to slide on the connecting plate b1-19 and the connecting plate c1-20, the connecting shaft b1-6 or the connecting shaft c1-8 moves to drive the sliding limiting blocks 1-13 on the same, the sliding limiting blocks 1-13 press the mounting plates b3-16 through the pressing shafts 1-14, the mounting plates b3-16 move to drive the mounting plates b sliding shafts 3-17, the mounting plates b sliding shafts 3-17 move to drive the gas sealing strips 3-19 to move, holes below the gas sealing strips 3-19 leak when the gas sealing strips 3-19 move, and at the moment, hot gas in the gas pipes 3-12 blows the hot gas to the pipelines through the gas inlet pipes a3-15 and the gas inlet pipes b3-22 at the positions of the gas sealing strips 3-19.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (5)

1. The utility model provides an intelligence pipeline alignment equipment, includes oppression transport mechanism (1), linkage rust cleaning mechanism (2), heat-conduction mechanism (3), its characterized in that: the pressing conveying mechanism (1) is connected with the linkage rust removing mechanism (2), the linkage rust removing mechanism (2) is connected with the conduction mechanism (3), and the conduction mechanism (3) is connected with the pressing conveying mechanism (1).

2. The intelligent pipeline straightening device according to claim 1, characterized in that: the compression conveying mechanism (1) comprises a motor (1-1), a motor shaft (1-2), a belt a (1-3), a connecting shaft a (1-4), a friction wheel a (1-5), a connecting shaft b (1-6), a belt b (1-7), a connecting shaft c (1-8), a limiting ring (1-9), a belt c (1-10), a conveying block (1-11), a fixed limiting block (1-12), a sliding limiting block (1-13), a compression shaft (1-14), a compression spring (1-15), a sealing plate (1-16), a sealing plate limiting strip (1-17), a connecting plate a (1-18), a connecting plate b (1-19), a connecting plate c (1-20) and a connecting plate d (1-21), the motor (1-1) is connected with the motor shaft (1-2), the motor (1-1) is connected with the connecting plate b (1-19), the motor shaft (1-2) is connected with the belt a (1-3) in a friction mode, the belt a (1-3) is connected with the connecting shaft a (1-4) in a friction mode, the connecting shaft a (1-4) is connected with the friction wheel a (1-5), the connecting shaft a (1-4) is connected with the connecting plate b (1-19) in a bearing mode, the connecting shaft a (1-4) is connected with the belt c (1-10) in a friction mode, the friction wheel a (1-5) is connected with the connecting shaft b (1-6) in a friction mode, the connecting shaft b (1-6) is connected with the belt b (1-7) in a friction mode, the connecting shaft b (1-6) is connected with the limiting ring, a connecting shaft b (1-6) is connected with a limiting ring (1-9), the connecting shaft b (1-6) is in bearing connection with a fixed limiting block (1-12), the connecting shaft b (1-6) is in sliding connection with a sliding limiting block (1-13), the connecting shaft b (1-6) is in bearing connection with a sealing plate (1-16), the connecting shaft b (1-6) is in sliding connection with a connecting plate b (1-19), the connecting shaft b (1-6) is in sliding connection with a connecting plate c (1-20), a belt b (1-7) is in friction connection with a connecting shaft c (1-8), the connecting shaft c (1-8) is connected with the limiting ring (1-9), the connecting shaft c (1-8) is in bearing connection with the fixed limiting block (1-12), a connecting shaft c (1-8) is connected with a sliding limiting block (1-13) in a sliding manner, the connecting shaft c (1-8) is connected with a sealing plate (1-16) through a bearing, the connecting shaft c (1-8) is connected with a connecting plate b (1-19) in a sliding manner, the connecting shaft c (1-8) is connected with a connecting plate c (1-20) in a sliding manner, a limiting ring (1-9) is connected with a connecting plate b (1-19) in a sliding manner, a fixed limiting block (1-12) is connected with a connecting plate c (1-20), a sliding limiting block (1-13) is connected with a pressing shaft (1-14), the sliding limiting block (1-13) is connected with the connecting plate c (1-20) in a sliding manner, the pressing shaft (1-14) is connected with a connecting plate a (1-18) in a sliding manner, and a pressing spring (1-15) is sleeved on the pressing shaft (1- The sealing plate structure comprises connecting plates a (1-18), sealing plates (1-16) are in sliding connection with sealing plate limiting strips (1-17), the sealing plates (1-16) are in sliding connection with connecting plates c (1-20), the sealing plate limiting strips (1-17) are connected with the connecting plates c (1-20), the connecting plates a (1-18) are connected with the connecting plates c (1-20), the connecting plates b (1-19) are connected with connecting plates d (1-21), and the connecting plates c (1-20) are connected with the connecting plates d (1-21).

3. The intelligent pipeline straightening device according to claim 1, characterized in that: the linkage rust removing mechanism (2) comprises a first belt (2-1), a first connecting shaft (2-2), a large gear (2-3), a small gear with a shaft (2-4), a propeller (2-5), a conical water inlet ring (2-6), a water tank (2-7), a water pipe joint (2-8), a water pipe (2-9), a water pipe sleeve (2-10), a fixed rotating ring (2-11), a connecting ring a (2-12), a connecting ring b (2-13), a cotton ring (2-14), a rust removing ring (2-15), a mounting column (2-16), a feeding pipe (2-17), a conical feeding pipe (2-18), a friction ring a (2-19), a second connecting shaft (2-20), a second friction ring (2-21), A first connecting plate (2-22), a water tank sealing plate (2-23), a second belt (2-24), a third connecting shaft (2-25) and a third belt (2-26), wherein the first belt (2-1) is in friction connection with a motor shaft (1-2), the first belt (2-1) is in friction connection with the first connecting shaft (2-2), the first connecting shaft (2-2) is connected with a large gear (2-3), the first connecting shaft (2-2) is connected with a bottom bearing of a water tank (2-7), the first connecting shaft (2-2) is in bearing connection with the water tank sealing plate (2-23), the large gear (2-3) is meshed with a small gear with a shaft (2-4), a shaft on the small gear with a shaft (2-4) is connected with the bottom bearing of the water tank (2-7), a shaft on the small gear with a shaft (2-4) is in bearing connection with the water tank sealing plate (, the propeller (2-5) is connected with a shaft on a pinion (2-4) with a shaft, a conical water inlet ring (2-6) is connected with a water tank sealing plate (2-23), the conical water inlet ring (2-6) is connected and communicated with a water pipe joint (2-8), a water tank (2-7) is connected with a connecting plate b (1-19), the water tank (2-7) is connected with the water tank sealing plate (2-23), the water pipe joint (2-8) is connected and communicated with a water pipe (2-9), the water pipe (2-9) is connected and communicated with a water pipe sleeve (2-10), the water pipe sleeve (2-10) is connected with the connecting plate b (1-19), the water pipe sleeve (2-10) is connected and communicated with a fixed rotating ring (2-11), the fixed rotating ring (2-11) is in bearing connection with a connecting ring a (2-12), the fixed rotating ring (2-11) is connected with a connecting ring b (2-13) through a bearing, the fixed rotating ring (2-11) is connected with a mounting column (2-16), a connecting ring a (2-12) is connected with a connecting ring b (2-13), a connecting ring a (2-12) is in friction connection with a friction ring II (2-21), one connecting ring b (2-13) is connected with a cotton ring (2-14), the other connecting ring is connected with a derusting ring (2-15), the derusting ring (2-15) is connected with a feeding pipe (2-17), an upper mounting column (2-16) is connected with a connecting plate b (1-19), a lower mounting column (2-16) is connected with a connecting plate c (1-20), and the feeding pipe (2-17) is connected with a conical feeding pipe (2-18), the friction ring a (2-19) is connected with the connecting shaft II (2-20), the friction ring a (2-19) is in friction connection with the belt II (2-24), the connecting shaft II (2-20) is connected with the friction ring II (2-21), the connecting shaft II (2-20) is in bearing connection with the connecting plate I (2-22), the upper side of the connecting plate I (2-22) is connected with the connecting plate b (1-19), the lower side of the connecting plate I (2-19) is connected with the connecting plate c (1-20), the belt II (2-24) is in friction connection with the connecting shaft III (2-25), the connecting shaft III (2-25) is in friction connection with the belt III (2-26), the connecting shaft III (2-25) is in bearing connection with the connecting plate b (1-19), and the connecting shaft III (2-25) is in bearing connection with the connecting plate c (, the connecting plate c (1-20) is in friction connection with the motor shaft (1-2).

4. The intelligent pipeline straightening device according to claim 1, characterized in that: the conduction mechanism (3) comprises a large gear a (3-1), a small gear a (3-2), a transmission shaft a (3-3), a propeller (3-4), an electric heater (3-5), a wind leaking plate (3-6), a mounting seat (3-7), a gas inlet ring (3-8), a conical gas inlet ring (3-9), a mounting plate a (3-10), a gas outlet pipe (3-11), a gas pipe (3-12), a gas sealing plate a (3-13), a gas sealing plate b (3-14), a gas inlet pipe a (3-15), a mounting plate b (3-16), a mounting plate b sliding shaft (3-17), a linkage spring (3-18), a gas sealing plate (3-19), a mounting plate c (3-20), a mounting plate d (3-21), An air inlet pipe b (3-22) and an air inlet pipe c (3-23), wherein a gearwheel a (3-1) is engaged with a pinion (3-2), the gearwheel a (3-1) is connected with a connecting shaft III (2-25), the pinion a (3-2) is connected with a transmission shaft a (3-3), a gap is arranged between the transmission shaft a (3-3) and an electric heater (3-5) for gas circulation, the transmission shaft a (3-3) is connected with an air leakage plate (3-6) in a bearing manner, the transmission shaft a (3-3) is connected with a connecting plate b (1-19) in a bearing manner, the transmission shaft a (3-3) is connected with a propeller (3-4), the electric heater (3-5) is connected with the air leakage plate (3-6), and the air leakage plate (3-6) is connected with a mounting seat (3-7), the mounting base (3-7) is connected with the connecting plate b (1-19), the mounting base (3-7) is connected with the air inlet ring (3-8), the air inlet ring (3-8) is connected with the conical air inlet ring (3-9), the conical air inlet ring (3-9) is connected with the mounting plate a (3-10), the mounting plate a (3-10) is connected and communicated with the air outlet pipe (3-11), the air outlet pipe (3-11) is communicated with the air delivery pipe (3-12), two ends of the air outlet pipe (3-11) are respectively connected with the air sealing plate a (3-13) and the air sealing plate b (3-14), the air outlet pipe (3-11) is connected with the air inlet pipe a (3-15), the air inlet pipe a (3-15) is connected with the air sealing strip (3-19) in a sliding mode, the air inlet pipe a (3-15) is connected and communicated with the connecting plate c (1-20), the mounting plate b (3-16) is connected with a sliding shaft (3-17) of the mounting plate b, the mounting plate b (3-16) is in sliding connection with a connecting plate c (1-20), the sliding shaft (3-17) of the mounting plate b is connected with a gas sealing strip (3-19), a linkage spring (3-18) is in a normal state that the spring is not stressed, the linkage spring (3-18) is sleeved on the sliding shaft (3-17) of the mounting plate b and limited on the gas sealing strip (3-19) and the connecting plate a (1-18), the gas sealing strip (3-19) is in sliding connection with the mounting plate c (3-20), the gas sealing strip (3-19) is in sliding connection with a mounting plate d (3-21), the mounting plate c (3-20) is connected and communicated with a gas inlet pipe b (3-22), the mounting plate d (3-21) is connected with the connecting plate c (1-20), one end of the air inlet pipe c (3-23) is connected and communicated with the air delivery pipe (3-12), and the other end of the air inlet pipe c passes through the connecting plate c (1-20).

5. The intelligent pipeline straightening device according to claim 1, characterized in that: a large number of resistors are arranged in the electric heaters (3-5), and the circular metal heat conduction layer on the upper parts of the electric heaters (3-5) can emit heat after the power supply is switched on.

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