CN112901908A

CN112901908A - Pipeline fixed mounting system based on energy recovery

Info

Publication number: CN112901908A
Application number: CN202110084327.1A
Authority: CN
Inventors: 曹亚鹏; 李国玉; 穆彦虎; 陈之祥; 吴刚; 熊猛
Original assignee: Northwest Institute of Eco Environment and Resources of CAS
Current assignee: Northwest Institute of Eco Environment and Resources of CAS
Priority date: 2021-01-21
Filing date: 2021-01-21
Publication date: 2021-06-04
Anticipated expiration: 2041-01-21
Also published as: CN112901908B

Abstract

The invention discloses a pipeline fixing and mounting system based on energy recovery, wherein a pipeline is fixed on a heat insulation mounting plate through a heat insulation fixing component, the heat insulation mounting plate is fixed above a permafrost layer through an anti-freezing support leg, the heat insulation fixing component comprises an upper positioning mounting part and a lower positioning mounting part, the two positioning mounting parts are butted to form a circular channel for a crude oil pipeline to pass through, and each positioning mounting part comprises an outer shell plate internally forming a sealed cavity; the energy recovery assembly is arranged on the fixed mounting part and comprises a semiconductor power generation piece fixed at the bottom of the outer shell plate and capable of being tightly attached to the outer wall of the pipeline, the top of the semiconductor power generation piece is connected with the cold plate at the top of the outer shell plate through a heat conducting rod, and the semiconductor power generation piece is electrically connected with a battery in the data acquisition protection box. The invention is environment-friendly and has high fixation stability.

Description

Pipeline fixed mounting system based on energy recovery

Technical Field

The invention relates to the technical field of frozen soil, in particular to a pipeline fixing and mounting system based on energy recovery.

Background

The permafrost refers to soil or rock which has a temperature of 0 ℃ or below 0 ℃, contains ice and has a freezing time lasting for more than two years. The area of which is about 1/4 of the land area of the northern hemisphere. Abundant oil and gas resources are stored in the vast areas, and with the further exploitation and utilization of the global oil and gas resources, oil and gas pipeline engineering in permafrost areas is increased for many years. However, buried pipeline engineering is affected by the temperature of oil and gas and the external environment, and pipeline engineering constructed in permafrost regions can face various permafrost disasters. When a high-temperature crude oil pipeline is buried in a permafrost region, frozen soil on the lower portion of the pipeline melts, uneven settlement can cause displacement of the pipe body, and the risk of pipe body fracture and instability can occur in severe cases. When the object of laying is natural gas line, pipeline negative temperature operation can cause normal position and segregation frost heaving to lead to body warp deformation, can threaten the safety and stability operation of pipeline equally, building pipeline engineering in permafrost region has always been the many years difficult problem of puzzlement academic world.

The conventional buried laying pipeline generally adopts measures such as adding an insulating layer to cool the pipe foundation soil, but the adding of the insulating layer cannot change the general trend of frozen soil degradation. And the conventional hot oil pipeline erection type measures, such as the U.S. Trans-Alaska pipeline engineering, adopt steel structure erection supports, and because the pipeline is overhead above the ground surface, natural disaster risks such as fire disasters and the like can be met in the pipeline operation process. Meanwhile, the lower supporting structure can generate a frozen-out lifting phenomenon due to the fact that the outer wall surface is smooth, and therefore the instability risk of the upper supporting pipe body is caused. Therefore, it is urgently needed to develop a set of measures which are simple in construction and multifunctional, can solve the frost heaving problem of the buried natural gas pipeline in the frozen soil area and can solve the thawing and sinking problem of the buried hot oil pipeline in the frozen soil area.

In addition, the pipeline monitoring system arranged in the perennial frozen soil area can early warn frozen soil disasters in real time, collect key parameter information such as frozen soil and pipelines and play an extremely important role in maintaining the safe and stable operation of pipelines, but most of the data acquisition boxes used for monitoring at present are supplied with power through solar energy, are greatly influenced by weather, are unstable in the solar energy power supply system, have the risk of power failure and cause the problem of untimely data acquisition. Therefore, a set of safe and stable monitoring power supply system needs to be developed.

Disclosure of Invention

The invention aims to provide a pipeline fixing and installing system based on energy recovery, aiming at the problems that in the prior art, a pipeline with an internal heat source (such as a crude oil pipeline) is thawed and sunk due to heat exchange with frozen soil, a pipeline with low-temperature materials therein (such as a natural gas pipeline) is frozen and swelled due to heat exchange with the frozen soil, and the solar power supply is unstable.

The technical scheme adopted for realizing the purpose of the invention is as follows:

a pipeline fixing and mounting system based on energy recovery is characterized in that a pipeline is fixed on a heat insulation mounting plate through a heat insulation fixing assembly, the heat insulation mounting plate is fixed above a permafrost layer through an anti-freezing support leg, the heat insulation fixing assembly comprises an upper positioning mounting part and a lower positioning mounting part, the two positioning mounting parts are in butt joint to form a circular channel for a crude oil pipeline to pass through, and each positioning mounting part comprises an outer shell plate internally forming a sealed cavity;

the energy recovery assembly is arranged on the fixed mounting part and comprises a semiconductor power generation piece fixed at the bottom of the outer shell plate and capable of being tightly attached to the outer wall of the pipeline, the top of the semiconductor power generation piece is connected with the cold plate at the top of the outer shell plate through a heat conducting rod, and the semiconductor power generation piece is electrically connected with a battery in the data acquisition protection box.

In the technical scheme, a sealing ring is embedded between the bottom surface of the cold plate and the top surface of the shell plate.

In the technical scheme, the heat insulation mounting plate comprises two layers of mounting plates and a heat insulation plate clamped between the two layers of mounting plates.

In the above technical scheme, the mounting plate is a metal plate, and the heat insulation plate is a hard polyethylene fiber plate.

In the technical scheme, each positioning and installing part comprises an outer shell plate, a sealing cavity is formed inside the outer shell plate, the sealing cavity is formed by two or more than two air bins at intervals through a supporting partition plate, any two adjacent air bins are communicated through a one-way valve, an air injection port and an air output port are arranged on the outer shell plate, the air injection port is communicated with one of the air bins, and the air output port is communicated with one of the air bins.

In the technical scheme, the connecting plate is fixed at the butt joint position of the two positioning installation parts, and the two positioning installation parts are fixedly connected through the connecting plate after being butt jointed.

In the technical scheme, the top of the heat insulation mounting plate is fixed with a mounting seat, a mounting screw hole is formed in the mounting seat, a matching screw is fixed on the heat insulation mounting plate, and the heat insulation fixing component is fixedly clamped in the mounting seat.

In the above technical scheme, the supporting partition plate is arranged in a groined shape, and the gas cabin is a square cavity.

In the technical scheme, the anti-freezing support leg is assembled at the bottom of the heat insulation mounting plate through a support leg mounting opening; the anti-freezing pulling support leg comprises a support leg body and an expansion inner core, wherein a hollow channel is formed in the support leg body, at least one side wall through hole is formed in the side wall of the support leg body, and a freezing pulling nail is assembled in each side wall through hole; the expansion inner core comprises a fixed transparent cover which is detachably assembled at the top of the supporting leg body, an embedded insulating thread sleeve which is fixed in a central opening of the fixed transparent cover, a frozen-drawn nail pushing sleeve which is fixed at the bottom of the insulating thread sleeve and is positioned in a hollow channel, and a frozen-drawn nail pushing rod which is matched with the frozen-drawn nail pushing sleeve; the freeze-drawn nail push rod comprises a push rod part and a conical part, wherein the push rod part is partially sleeved in the freeze-drawn nail push sleeve, the conical part is fixed at the bottom end of the push rod part, the outer diameter of the push rod part is smaller than the inner diameter of the freeze-drawn nail push sleeve, the diameter of the large end of the conical part is larger than the inner diameter of the freeze-drawn nail push sleeve, and the top of the push rod part penetrates out of the central opening; when the frozen-drawn nail push rod moves upwards, the conical part pushes the frozen-drawn nail push sleeve to expand, and the frozen-drawn nail push sleeve pushes the tail end of the frozen-drawn nail to enable the head end of the frozen-drawn nail to penetrate through the side wall through hole;

the top of freezing nail push rod of pulling out is equipped with first power terminal, it is fixed to cover thoroughly and is equipped with second power terminal, first power terminal, freeze the nail push rod of pulling out, freeze the nail push sleeve of pulling out, freeze the lateral wall of pulling out nail, supporting leg body, fix and cover thoroughly, second power terminal constitution electric loop, it is the electricity material that generates heat to freeze the nail of pulling out.

In the technical scheme, the push rod part is in threaded connection with the insulating thread sleeve, and the top of the push rod part is provided with a hexagonal opening.

In the technical scheme, the bottom of the supporting leg body is in a pointed cone shape, and the threaded plate is fixed outside the side wall of the supporting leg body.

In the technical scheme, the top of the supporting leg body is in threaded connection with the fixed transparent cover.

In the above technical solution, the anti-freeze drawing support leg further includes a support rod that can be inserted into the hollow passage in a matching manner.

In the technical scheme, the through hole of the side wall is internally fixed with a frozen pull nail bushing vertical to the supporting leg body, and the frozen pull nail is embedded in the frozen pull nail bushing.

In the technical scheme, the tail end of the frozen pull nail is fixed with the anti-drop pin, so that the frozen pull nail is prevented from dropping out from the frozen pull nail bushing.

In the technical scheme, the nail pushing sleeve is formed by enclosing a plurality of groups of arc-shaped plates, the top of each arc-shaped plate is fixed on the bottom of the insulating wire sleeve, expansion slots are formed between the arc-shaped plates, a nail fixing groove is formed in the arc-shaped plates corresponding to the nail to be frozen and pulled, the tail end of the nail to be frozen and pulled is located in the nail fixing groove to be frozen and pulled, when the nail pushing rod of the nail to be frozen and pulled moves upwards, the arc-shaped plates are bent, the nail pushing sleeve to be frozen and pulled expands, and in the expanding process, the nail fixing groove to be frozen and pulled pushes the nail to be frozen and move out of the nail lining to.

In the technical scheme, the supporting leg mounting port is in threaded connection with the supporting leg body, after the supporting leg body is arranged in the permafrost layer, the supporting leg mounting port is assembled at the top of the supporting leg body, and then the supporting leg mounting port is welded at the bottom end of the heat insulation mounting plate.

In the above technical scheme, each pipeline fixed mounting system includes that two and above prevents frostbite and pulls out the supporting leg, prevent frostbite pull out the supporting leg symmetry assemble in thermal-insulated mounting panel bottom, two and above prevent frostbite pull out the supporting leg and constitute by the supporting leg body and the inflation inner core of corresponding number.

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

1. the pipeline engineering in permafrost regions inevitably crosses the fields with different earth surface conditions such as forest regions, grasslands and the like for many years, and the device is buried underground and laid, so that natural disaster risks such as forest fires and the like can be effectively avoided.

2. The device has various functions, can solve the thaw collapse disaster caused by the hot oil pipeline in the permafrost region, and can be applied to the frost heaving disaster prevention and control of the natural gas pipeline in the permafrost region.

3. This device lower part bearing structure adopts prevents frostbite and pulls out bearing structure, can effectively avoid the pipe body unstability risk that pipeline operation in-process lower part bearing structure freezes to pull out and brings.

4. This device is based on energy recuperation principle, ingenious application pipeline self heat, utilizes thermoelectric generation, for frozen soil district pipeline monitoring system provides lasting, stable electric energy, accords with green, sustainable development principle.

5. The device is simple and easy to assemble and high in integration degree. Can be pertinently applied to frozen soil sections with different meltdown properties and frost heaving properties. The instability of the pipe body caused by uneven thawing and frost heaving is avoided.

Drawings

Fig. 1 is a cross-sectional view of an energy recovery based pipe fixing system.

FIG. 2 is a diagram of the relationship between the gas bins.

Fig. 3 is a perspective view of the fixed mounting portion (a part of the check valve is omitted and only one check valve is indicated).

FIG. 4 is a cross-sectional view of the freeze-pull resistant support leg.

FIG. 5 is a side view of the support leg body.

Fig. 6 is a cross-sectional view taken along the plane a-a in fig. 4.

FIG. 7 is a side view of the cryo-plucked pin collar.

In the figure: 1-power supply terminal, 2-hexagonal opening, 3-fixed transparent cover, 4-frozen nail, 5-support leg body, 6-frozen nail pushing sleeve, 7-nail pushing rod, 8-insulating thread sleeve, 9-frozen nail bushing, 10-anti-drop pin, 11-expansion slot, 12-frozen nail fixing groove, 13-thread plate, 14-pipeline, 15-support clapboard, 16-one-way valve, 17-gas cabin, 18-gas injection opening, 19-mounting plate, 20-frozen nail support leg, 21-thermal insulation plate, 22-support leg mounting opening, 23-mounting seat, 24-mounting screw hole, 25-housing plate, 26-connecting plate, 27-semiconductor power generation sheet, 28-heat conducting rod, 29-cold plate, 30-a data acquisition protection box, 31-a battery, 32-a sealing ring and 33-a solar power generation assembly.

6-1-arc plate, 7-1-push rod part and 7-2 arc plate.

a-an active layer and b-a permafrost layer.

Detailed Description

The invention is described in further detail below with reference to the figures and specific examples. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Example 1

A pipeline fixing and mounting system based on energy recovery is characterized in that a pipeline is fixed on a heat insulation mounting plate through a heat insulation fixing assembly, the heat insulation mounting plate is fixed above a permafrost layer through an anti-freezing support leg, the heat insulation fixing assembly comprises an upper positioning mounting part and a lower positioning mounting part, and the two positioning mounting parts are butted to form a circular channel for a pipeline 14 to pass through;

each location installation department includes inside outer skin 25 that forms sealed cavity, the last energy recuperation subassembly that is equipped with of fixed mounting portion, the energy recuperation subassembly is including being fixed in outer skin 25 bottom and can closely laminate with the semiconductor power generation piece 27 of pipeline 14 outer wall, the top of semiconductor power generation piece 27 is passed through the heat-conducting rod 28 and is fixed in the cold plate 29 at outer skin 25 top is connected, cold plate 29 bottom surface with sealing washer 32 has been inlayed between the outer skin 25 top surface, the battery 31 electricity in semiconductor power generation piece 27 and the data acquisition protection box 30 is connected.

A channel for the heat conducting rod 28 to penetrate out is formed in the positioning installation part, a lead electrically connected with the semiconductor power generation sheet 27 also penetrates out through the channel and then penetrates out through a gap between the bottom surface of the cold plate 29 and the top surface of the shell plate 25, and the seal ring 32 extrudes the lead to form sealing.

The energy recovery assembly is arranged on the fixed installation part above, and because the cold plate 29 has temperature difference with the heat conducting rod on the outer wall of the fixed installation part, namely, the heat exchange is carried out through the heat conducting rod to meet the power generation condition (the temperature difference is generated on the front side and the back side) of the semiconductor power generation sheet 27, the semiconductor power generation sheet 27 charges the battery 31 in the data acquisition protection box 30.

When the pipeline with the internal heat source is fixed by the system, the temperature of the bottom surface of the semiconductor power generation sheet 27 is higher than that of the top surface, and the temperature difference is generated, and when the pipeline with the internal low-temperature material is fixed by the system, the temperature of the bottom surface of the semiconductor power generation sheet 27 is lower than that of the top surface, and the generated temperature difference meets the power generation condition.

The crude oil pipeline fixing and mounting system is buried under the ground, earth is dug to be exposed to a permafrost layer, when the crude oil pipeline fixing and mounting system is used, an anti-freezing support leg 20 is firstly mounted in the permafrost layer, then a heat insulation mounting plate is mounted at the top of the anti-freezing support leg 20, and the heat insulation mounting plate and the parts above the heat insulation mounting plate are buried in a movable layer.

The pipeline fixing and mounting systems are arranged at intervals along the length direction of the pipeline, and the pipeline is fixed at multiple points.

As preferred, prevent frostbite and pull out supporting leg 20 through supporting leg installing port 22 assemble in the bottom of thermal-insulated mounting panel, as preferred, supporting leg installing port 22 with supporting leg body 5 passes through threaded connection, packs into supporting leg body 5 after the permafrost layer into, with supporting leg installing port 22 assemble in the top of supporting leg body 5, weld supporting leg installing port 22 in the bottom of thermal-insulated mounting panel again. Make from this and form the screw assembly between supporting leg body 5 and the thermal-insulated mounting panel, the assembly stability is high, avoids the body unstability.

Preferably, the heat-conducting member includes a heat-conducting rod 28 passing through the fixed mounting portion and a heat-conducting plate 32 fixed to the top of the fixed mounting portion, and the cold plate 29 is closely attached to the upper surface of the heat-conducting plate 32.

Preferably, the battery 31 is electrically connected to the solar power module 33, and the solar power module and the energy recovery module alternately store electricity for the battery 31 or simultaneously store electricity for the battery 31 as required. The semiconductor power generation piece 27 and the solar power generation assembly simultaneously supply power for the data acquisition protection box 30, the defect that a photovoltaic panel cannot work in cloudy days is overcome, pipeline heat is utilized, energy is greatly saved, and the advocate of green development is met.

Example 2

Preferably, the insulated mounting plate comprises two layers of mounting plates 19 and an insulated plate 21 sandwiched between the two layers of mounting plates 19. The heat insulation mounting plate can prevent heat of the crude oil pipeline from being transferred into the frozen soil, so that the frozen soil contacted with the crude oil pipeline is degraded.

Preferably, the mounting plate 19 is a metal plate, and the heat insulation plate 21 is a hard polyethylene fiber plate. The strength and the heat insulation performance of the heat insulation mounting plate are ensured.

Preferably, the connecting plate 26 is fixed at the position where the two fixing and mounting portions are butted, and after the two fixing and mounting portions are butted, the two fixing and mounting portions are fixedly connected through the connecting plate, here, the bolt and the screw are matched and fixed, and after the two connecting plates 26 are fastened together, the shell plate 25 can be ensured to be tightly jointed with the pipeline 14.

Preferably, a mounting seat 23 is fixed to the top of the heat insulation mounting plate, a mounting screw hole 24 is formed in the mounting seat 23, a matching screw is fixed to the heat insulation mounting plate, and the heat insulation positioning assembly is clamped and fixedly mounted in the mounting seat 23, so that the heat insulation mounting plate is convenient to detach and maintain.

Preferably, the supporting partition 15 is arranged in a shape like a Chinese character jing, and the gas bin 17 is a square chamber, so that the processing is convenient.

Preferably, the sealed chamber is partitioned by a support partition 15 to form two or more gas chambers 17, any two adjacent gas chambers 17 are communicated through a one-way valve 16, the housing plate 25 is provided with a gas inlet 18 and a gas outlet, the gas inlet 18 is communicated with one of the gas chambers 17, and the gas outlet is communicated with one of the gas chambers 17.

The inert gas with the heat conductivity coefficient lower than that of air is injected through the gas injection port 18, the gas bins 17 are inflated one by one through the one-way valve 16, when a single gas bin 17 is damaged due to external force, the use of the whole device cannot be influenced, and the inflated inert gas bin 17 has a good heat insulation function and prevents heat exchange between the pipeline 14 and frozen soil. In the process of injecting the inert gas, the air originally located in the gas cabin 17 is output from the gas output port until all the gas cabins 17 are filled with the inert gas, and the gas injection port 18 and the gas output port are closed.

Or the gas inlet 18 is closed, the gas outlet is vacuumized from the gas outlet, and when the gas bin 17 is in a vacuumized state, the gas outlet is closed, so that the vacuum structure also has good heat insulation performance, and heat exchange between the pipeline 14 and frozen soil is prevented. When a single air chamber 17 is in a vacuum breaking state due to external force damage, the vacuum loading state of other air chambers 17 is not influenced.

Example 3

Preferably, the support leg comprises a support leg body 5 and an expansion inner core, wherein a hollow channel is formed inside the support leg body 5, at least one side wall through hole is formed in the side wall of the support leg body 5, and a freeze-drawing nail 4 is assembled in each side wall through hole; the expansion inner core comprises a fixed transparent cover 3 which is detachably assembled at the top of the supporting leg body 5, an embedded insulating thread sleeve 8 which is fixed in a central opening of the fixed transparent cover 3, a frozen-drawn nail pushing sleeve 6 which is fixed at the bottom of the insulating thread sleeve 8 and is positioned in a hollow channel, and a frozen-drawn nail pushing rod 7 which is matched with the frozen-drawn nail pushing sleeve 6; the frozen pull nail push rod 7 comprises a push rod part 7-1 partially sleeved in the frozen pull nail push sleeve 6 and a conical part 7-2 fixed at the bottom end of the push rod part 7-1, the outer diameter of the push rod part 7-1 is smaller than the inner diameter of the frozen pull nail push sleeve 6, the diameter of the large end of the conical part 7-2 is larger than the inner diameter of the frozen pull nail push sleeve 6, and the top of the push rod part 7-1 penetrates out of the central opening; when the frozen extracted nail push rod 7 moves upwards, the conical part 7-2 pushes the frozen extracted nail push sleeve 6 to expand, and the frozen extracted nail push sleeve 6 pushes the tail end of the frozen extracted nail 4 to enable the head end of the frozen extracted nail to penetrate through the side wall through hole;

the top of pulling out nail push rod 7 is frozen and is equipped with first power terminal 1, it is fixed to be equipped with second power terminal on covering 3 thoroughly, first power terminal 1, freeze and pull out nail push rod 7, freeze and pull out nail push sleeve 6, freeze and pull out nail 4, supporting leg body 5's lateral wall, fixed covering 3, second power terminal constitute electric circuit, the resistance that freezes to pull out nail 4 material is greater than to freeze and pulls out nail push rod 7, freeze and pull out nail push sleeve 6, supporting leg body 5 and fixed resistance of covering 3 thoroughly, freezes to pull out nail 4 and can adopt big resistance materials such as chromium-aluminum alloy, makes when first power terminal 1, second power terminal connect the electricity, freezes to pull out nail 4 and generates heat. In order to improve the safety performance, the outer wall of the fixed transparent cover 3 is coated with an insulating layer.

The anti-freezing pulling method for the anti-freezing pulling supporting leg comprises the following steps: the anti-freezing support leg is characterized in that the anti-freezing support leg shown in the figure 1 is installed in a frozen soil area, a power supply is connected to a power supply terminal 1, meanwhile, a force is applied to a freezing nail push rod 7, the freezing nail push sleeve 6 is driven to expand and expand, the freezing nail 4 starts to move outwards, meanwhile, a first power supply terminal 1 and a second power supply terminal are respectively connected with the positive pole and the negative pole of the power supply, when the freezing nail push rod 7 moves upwards, the large end of a conical part 7-2 contacts the freezing nail push sleeve 6, the freezing nail push sleeve 6 contacts the freezing nail 4, the freezing nail 4 contacts the side wall of a support leg body 5, and the side wall of the support leg body 5 contacts a fixed transparent cover 3 to form an electric circuit, because the freezing nail 4 has larger resistance, the freezing nail 4 generates heat, the freezing soil outside the support leg body 5 is melted during outward movement, so that the freezing nail 4 smoothly penetrates out, after all freeze and pull out nail 4 and wear out, the power supply is cut off, take off the inflation inner core (fixed cover 3 that passes through, inlay insulating screw cover 8, freeze and pull out nail push sleeve 6, freeze and pull out nail push rod 7), supporting leg body 5 with freeze and pull out nail 4 and stay in the permafrost soil in situ, wait that the frozen soil freezes again for form good fixed between supporting leg body 5 and the frozen soil, then assemble thermal-insulated mounting panel and rather than fixed thermal-insulated fixed subassembly in the top of supporting leg body 5 through supporting leg installing port 22.

Preferably, the anti-freezing nail pulling support leg further comprises a support rod capable of being inserted into the hollow channel in a matched mode, the nail freezing pulling push rod 7 is pulled down, the support rod is inserted into the hollow channel, and dislocation of the freezing nail pulling support leg in the using process is prevented.

Preferably, the freeze-drawn nails 4 are arranged in a row on the side wall of the support leg body 5.

Preferably, the supporting leg installing port 22 is in threaded connection with the supporting leg body 5, and after the supporting leg body 5 is installed in the permafrost layer, the supporting leg installing port 22 is assembled at the top of the supporting leg body 5, and then the supporting leg installing port 22 is welded at the bottom end of the heat insulation installing plate. Make from this and form the screw assembly between supporting leg body 5 and the thermal-insulated mounting panel, assembly stability is high, avoids the body unstability.

Preferably, the buried pipeline fixing device comprises two or more than two anti-freezing support legs 20, the anti-freezing support legs 20 are symmetrically assembled at the bottom of the heat insulation mounting plate, and the two or more than two anti-freezing support legs 20 consist of support leg bodies 5 with corresponding numbers and an expansion inner core. During the use at every turn, with the assembly of inflation inner core on a supporting leg body 5, freeze and pull out the installation back that nail 4 bloated out and accomplish a supporting leg body 5, dismantle the inflation inner core and get off the reassembling on another supporting leg body 5, install a plurality of supporting leg bodies 5 in proper order. So reduced the use cost who prevents frostbite and pull out the supporting leg.

Preferably, the push rod part 7-1 is in threaded connection with the insulating thread sleeve 8, the top of the push rod part 7-1 is a hexagonal opening 2, and the push rod part 7-1 moves upwards by rotating the push rod part 7-1 through the hexagonal opening 2. Besides, the push rod part 7-1 and the insulating thread sleeve 8 can be in clearance fit, and when the device is used, the push rod part 7-1 is directly pulled upwards.

Preferably, the bottom of the supporting leg body 5 is in a sharp cone shape, and a thread plate 13 is fixed on the outer portion of the side wall of the supporting leg body 5, so that the supporting leg body 5 can be conveniently and rotatably installed in frozen soil.

Preferably, the top of the supporting leg body 5 is in threaded connection with the fixed transparent cover 3, and when the expansion inner core is disassembled and assembled, the fixed transparent cover 3 only needs to be rotated.

Preferably, be fixed with in the lateral wall through-hole and freeze and pull out nail bush 9 with supporting leg body 5 vertically, it inlays and adorns to freeze and pulls out nail 4 in freeze and pull out nail bush 9, this because freeze and pull out nail push rod 7 and freeze and pull out nail 4 and can produce a yawing force messenger and freeze and pull out nail 4 skew when the effect, freeze and pull out setting up of nail bush 9, reducible yawing force, it is electrically conductive when freezing and pulling out between the nail 4, freezing and pulling out the lateral wall of nail bush 9 and supporting leg body 5.

Preferably, a separation-preventing pin 10 is fixed at the tail end of the freeze-drawn nail 4 to prevent the freeze-drawn nail 4 from separating from the freeze-drawn nail bushing 9.

Preferably, the frozen nail pulling sleeve 6 is formed by enclosing a plurality of groups of arc-shaped plates 6-1, the top of each arc-shaped plate 6-1 is fixed at the bottom of the insulating screw sleeve 8, an expansion slot 11 is formed between the arc-shaped plates 6-1, a frozen nail pulling fixing groove 12 is formed on the arc-shaped plate 6-1 corresponding to the frozen nail pulling 4, and the tail end of the frozen nail pulling 4 is positioned in the frozen nail pulling fixing groove 12. When the frozen extracted nail push rod 7 moves upwards, the arc-shaped plate 6-1 bends, the frozen extracted nail push sleeve 6 expands, and in the expanding process, the frozen extracted nail fixing groove 12 pushes the frozen extracted nail 4 to move out of the frozen extracted nail bushing 9.

Spatially relative terms, such as "upper," "lower," "left," "right," and the like, may be used in the embodiments for ease of description to describe one element or feature's relationship to another element or feature as illustrated in the figures. It will be understood that the spatial terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as "below" other elements or features would then be oriented "above" the other elements or features. Thus, the exemplary term "lower" can encompass both an orientation of upper and lower. The device may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

Moreover, relational terms such as "first" and "second," and the like, may be used solely to distinguish one element from another element having the same name, without necessarily requiring or implying any actual such relationship or order between such elements.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims

1. The pipeline fixing and mounting system based on energy recovery is characterized in that a pipeline is fixed on a heat insulation mounting plate through a heat insulation fixing assembly, the heat insulation mounting plate is fixed above a permafrost layer through an anti-freezing support leg, the heat insulation fixing assembly comprises an upper positioning mounting part and a lower positioning mounting part, the two positioning mounting parts are in butt joint to form a circular channel for a crude oil pipeline to pass through, and each positioning mounting part comprises an outer shell plate internally forming a sealed cavity;

2. The energy recovery-based pipe fixing and mounting system according to claim 1, wherein a sealing ring is embedded between the bottom surface of the cold plate and the top surface of the outer casing plate, preferably, the heat insulation mounting plate comprises two layers of mounting plates and a heat insulation plate sandwiched between the two layers of mounting plates, preferably, the mounting plate is a metal plate, and the heat insulation plate is a hard polyethylene fiber plate.

3. The energy recovery-based pipe fixing and mounting system according to claim 1, wherein each positioning and mounting part comprises an outer shell plate, a sealing chamber is formed inside the outer shell plate, the sealing chamber is partitioned by a supporting partition plate to form two or more than two gas bins, any two adjacent gas bins are communicated through a one-way valve, a gas injection port and a gas output port are formed in the outer shell plate, the gas injection port is communicated with one of the gas bins, and the gas output port is communicated with one of the gas bins; preferably, a connecting plate is fixed at the butt joint position of the two positioning installation parts, and the two positioning installation parts are fixedly connected through the connecting plate after being in butt joint; preferably, the top of thermal-insulated mounting panel is fixed with the mount pad, form the installation screw on the mount pad, the cooperation screw is fixed in on the thermal-insulated mounting panel, thermal-insulated fixed subassembly block fixed mounting in the mount pad, preferably, the supporting baffle is the groined type setting, the gas storehouse is square cavity.

4. The energy recovery-based pipe fixing and mounting system according to claim 1, wherein the anti-freezing support leg is assembled at the bottom of the heat insulation mounting plate through a support leg mounting opening; the anti-freezing pulling support leg comprises a support leg body and an expansion inner core, wherein a hollow channel is formed in the support leg body, at least one side wall through hole is formed in the side wall of the support leg body, and a freezing pulling nail is assembled in each side wall through hole; the expansion inner core comprises a fixed transparent cover which is detachably assembled at the top of the supporting leg body, an embedded insulating thread sleeve which is fixed in a central opening of the fixed transparent cover, a frozen-drawn nail push sleeve which is fixed at the bottom of the insulating thread sleeve and is positioned in a hollow channel, and a frozen-drawn nail push rod which is matched with the frozen-drawn nail push sleeve; the freeze-drawn nail push rod comprises a push rod part and a conical part, wherein the push rod part is partially sleeved in the freeze-drawn nail push sleeve, the conical part is fixed at the bottom end of the push rod part, the outer diameter of the push rod part is smaller than the inner diameter of the freeze-drawn nail push sleeve, the diameter of the large end of the conical part is larger than the inner diameter of the freeze-drawn nail push sleeve, and the top of the push rod part penetrates out of the central opening; when the frozen extracted nail push rod moves upwards, the conical part pushes the frozen extracted nail push sleeve to expand, and the frozen extracted nail push sleeve pushes the tail end of the frozen extracted nail to enable the head end of the frozen extracted nail to penetrate through the side wall through hole;

the top of the freeze-drawing nail push rod is provided with a first power supply terminal, the fixed transparent cover is provided with a second power supply terminal, the first power supply terminal, the freeze-drawing nail push rod, the freeze-drawing nail push sleeve, the freeze-drawing nail, the side wall of the support leg body, the fixed transparent cover and the second power supply terminal form an electric loop, and the freeze-drawing nail is made of an electric heating material;

preferably, the push rod part is in threaded connection with the insulating thread sleeve, and the top of the push rod part is provided with a hexagonal opening.

5. The energy recovery-based pipeline fixing and mounting system as claimed in claim 4, wherein the bottom of the supporting leg body is in a pointed cone shape, a threaded plate is fixed on the outside of the side wall of the supporting leg body, and preferably, the top of the supporting leg body is in threaded connection with the fixing transparent cover.

6. The energy recovery based pipe securement mounting system of claim 4, wherein said anti-freeze support legs further comprise support rods mateably inserted into said hollow channel.

7. The energy recovery-based pipeline fixing and mounting system as claimed in claim 4, wherein a freeze-drawn nail bushing perpendicular to the supporting leg body is fixed in the side wall through hole, the freeze-drawn nail is embedded in the freeze-drawn nail bushing, and preferably, a release-preventing pin is fixed at the tail end of the freeze-drawn nail to prevent the freeze-drawn nail from being released from the freeze-drawn nail bushing.

8. The energy recovery-based pipeline fixing and mounting system according to claim 4, wherein the freeze-drawn nail pushing sleeve is formed by enclosing a plurality of groups of arc-shaped plates, the top of each arc-shaped plate is fixed to the bottom of the insulating screw sleeve, an expansion slot is formed between the arc-shaped plates, a freeze-drawn nail fixing groove is formed in the arc-shaped plate corresponding to the freeze-drawn nail, the tail end of the freeze-drawn nail is located in the freeze-drawn nail fixing groove, when the freeze-drawn nail pushing rod moves upwards, the arc-shaped plates bend, the freeze-drawn nail pushing sleeve expands, and in the expansion process, the freeze-drawn nail fixing groove pushes the freeze-drawn nail to move out of the freeze-drawn nail bushing.

9. The energy recovery-based pipeline fixing and mounting system according to claim 1, wherein the support leg mounting opening is in threaded connection with the support leg body, after the support leg body is installed in the permafrost layer, the support leg mounting opening is assembled at the top of the support leg body, and then the support leg mounting opening is welded to the bottom end of the heat insulation mounting plate.

10. The energy recovery-based pipe fixing and mounting system according to claim 1, wherein each of the pipe fixing and mounting systems comprises two or more anti-freeze-extraction support legs symmetrically assembled to the bottom of the heat insulation mounting plate, and the two or more anti-freeze-extraction support legs are composed of a corresponding number of support leg bodies and an expansion core.