CN207830759U - A kind of cold area's pipeline heat-insulating system - Google Patents
A kind of cold area's pipeline heat-insulating system Download PDFInfo
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- CN207830759U CN207830759U CN201820169526.6U CN201820169526U CN207830759U CN 207830759 U CN207830759 U CN 207830759U CN 201820169526 U CN201820169526 U CN 201820169526U CN 207830759 U CN207830759 U CN 207830759U
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Abstract
The utility model discloses a kind of cold area's pipeline heat-insulating systems, pass through several section air hoses of package on pipeline, the head end connection wind turbine of air hose is continually fed into high-temperature gas to air hose inside, air hose is fixed by the bracket in the outside of pipeline, there is air duct between pipeline and air hose, high-temperature gas persistently heats pipeline in air duct again, this system can be that tunnel in cold area water fire fighting system provides antifreeze guarantee in winter, to avoid because severe cold causes fire protection pipeline to freeze, tunnel fire safety loses guarantee, achieve the purpose that promoted severe cold in the case of tunnel fire protection system reliability.
Description
Technical field
The utility model belongs to tunnel fire-fighting domain, and in particular to a kind of cold area's pipeline heat-insulating system.
Background technology
The frost zone area of China is up to 5.14 × 106km2, account for the 53.5% of national total area.It is built in these areas
Tunnel is a special engineering in infrastructure, and with the continuous development of China's infrastructure, tunnel in cold area Quantity is not
It is disconnected to increase.The greatest problem that tunnel in cold area faces is freezing damage in tunnel, and China puts into the expense of tunnel in cold area freeze injury improvement in recent years
With being continuously increased, nonetheless, still there are many tunnels to endure freeze injury puzzlement to the fullest extent, or even discarded, tunnel in cold area freezing prevention just becomes
The important subject on tunnel circle.In tunnel in cold area freeze injury problem, the security against fire of tunnel in cold area is to be related to the people
The important topic of the security of the lives and property, tunnel in cold area local environment temperature is extremely low, and fire protection pipeline easily loses work because of sharp freezing
With making staff in tunnel be in unsafe condition.
In previous research, researcher proposes a variety of heater by service, as electric tracing thermal insulation, fire protection pipeline filling are anti-
Freeze liquid, dry fire protection system, discharge water heat preservation etc..Electric tracer heating system is a kind of radial pattern heating system, using heating wire as heating agent, is led to
Crossing makes heating cable energization convert electrical energy into thermal energy, heated object is passed to, and by the protection of outer layer heat-barrier material, to reach
Heating, heat insulation effect to system needs.It refers to that antifreezing agent is added in tunnel fire extinguisher canvas hose that fire protection pipeline, which fills anti-icing fluid, drop
The freezing point of water in low pipeline, to reach antifreeze purpose.Dry fire protection system refers to that usually water pipe is interior to be run for blank pipe, and fire occurs
Carry out water supply operation again afterwards.The heat preservation that discharges water refers to that periodically pipeline inner cold water is discharged in the case of satisfying the requirements, and introduces underground
Water keeps the water temperature in pipe to be consistently higher than freezing point.These measures can reach the requirement of freezing prevention tubing heat preservation under ideal conditions,
But there are various problems to occur in practical operation, it is difficult to achieve the desired results, fire-fighting heat preservation in current tunnel in cold area is made to be in
Unreliable state, there are security risks.
Utility model content
Purpose of the utility model is to overcome the above-mentioned shortcomings and provide a kind of cold area's pipeline heat-insulating systems, which can
Antifreeze guarantee is provided in winter for tunnel in cold area water fire fighting system, to avoid because severe cold causes fire protection pipeline to freeze, tunnel
Fire safety evaluating loses guarantee, achievees the purpose that tunnel fire protection system reliability in the case of promotion severe cold.
In order to achieve the above object, the utility model include with water pump connecting pipe, and be wrapped in several sections on pipeline
Air hose, adjacent air hose are connected by box and pin, and the head end of air hose connects wind turbine, and air hose is fixed by the bracket in the outer of pipeline
There is air duct, wind turbine to be accessed in air duct by Fan pipeline between pipeline and air hose for side.
Air hose includes linear type air hose, L-type air hose and T-type air hose.
Linear type air hose include with water pump connecting pipe, and be wrapped in several section straight line air hoses on pipeline.
T-type air hose includes the fire protection pipeline and fire-fighting branch pipe of T-shaped setting, and the corner of fire-fighting branch pipe and fire protection pipeline is set
It is equipped with L-shaped branch tube boot, the outside of fire protection pipeline side is provided with air hose, and air hose is collectively covered with branch tube boot in fire-fighting
Pipeline and fire-fighting branch tube outer surface, between air hose and branch tube boot and fire protection pipeline and fire-fighting branch pipe have air duct, branch tube boot with
The end of air hose collectively constitutes interface.
L-type air hose includes the fire protection pipeline in L-shaped setting, and the bending place of fire protection pipeline is covered with the wind of L-shaped setting
Pipe, air duct is supported between air hose and fire protection pipeline by holder.
It is connected by box and pin between adjacent air hose.
Compared with prior art, the heat-insulation system of the utility model passes through several section air hoses of package on pipeline, air hose
Head end connection wind turbine high-temperature gas is continually fed into air hose inside, air hose is fixed by the bracket in the outside of pipeline, pipeline with
There is air duct, high-temperature gas persistently to be heated again to pipeline in air duct, thermal conductivity functional using air heat insulation between air hose
The feature of difference, can increase system single heat preservation duration while reducing heat preservation energy consumption, this system can be that tunnel in cold area water disappears
Anti- system provides antifreeze guarantee in winter, and to avoid because severe cold causes fire protection pipeline to freeze, tunnel fire safety loses guarantor
Card achievees the purpose that tunnel fire protection system reliability in the case of promotion severe cold.This system is highly reliable, and modular member is conducive to peace
Dress and maintenance can be not only used for newly-built pipeline, can be used for the heat preservation transformation for having pipeline.
Description of the drawings
Fig. 1 is the front view of the utility model cathetus type air hose;
Fig. 2 is the vertical view of the utility model cathetus type air hose;
Fig. 3 is the side view of the utility model cathetus type air hose;
Fig. 4 is the front view of T-type air hose in the utility model;
Fig. 5 is the vertical view of T-type air hose in the utility model;
Fig. 6 is the side view of T-type air hose in the utility model;
Fig. 7 is the vertical view of L-type air hose in the utility model;
Fig. 8 is wind turbine layout drawing in the utility model;
Fig. 9 is wind turbine and measuring point value arrangement map in the utility model embodiment;
Wherein, 1, air hose;2, holder;3, interface;4, air duct;5, fire protection pipeline;6, fire-fighting branch pipe;7, branch tube boot;8、
Fan pipeline;9, wind turbine;10, measuring point;11, water pump;12, pump house;13, manifold.
Specific implementation mode
The utility model is described further below in conjunction with the accompanying drawings.
This system makes fire protection pipeline 6 be in warm wind environment to avoid in pipeline using air hose as 5 inner thermal insulating layer of fire protection pipeline
Water freezes, it is advantageous that reliability is high, expense is low, is suitable for most tunnels.The system is made of wind turbine 9 and air hose 1.
In order to avoid because in air hose 1 heat it is outer cold due to lead to condensation vapor in air hose, influence system stability, wind turbine 9 should have heating and
Dehumidification function.Air hose 1 includes linear type air hose, L-type air hose and T-type air hose.
Referring to Fig. 1, Fig. 2 and Fig. 3 and Fig. 8, linear type air hose include with 11 connecting pipe of water pump, and be wrapped on pipeline
Several section air hoses 1 are connected by box and pin between adjacent air hose 1, and the head end of air hose 1 connects wind turbine 9, and air hose 1 is solid by holder 2
It is scheduled on the outside of pipeline, there is air duct 4, wind turbine 9 to be accessed in air duct 4 by Fan pipeline 8 between pipeline and air hose 1.
Referring to Fig. 4, Fig. 5 and Fig. 6, T-type air hose includes the fire protection pipeline 5 and fire-fighting branch pipe 6 of T-shaped setting, fire-fighting branch pipe 6
The corner of fire protection pipeline 5 is provided with L-shaped branch tube boot 7, the outside of 5 side of fire protection pipeline is provided with air hose 1, air hose
1 collectively covers with branch tube boot 7 in 6 outer surface of fire protection pipeline 5 and fire-fighting branch pipe, air hose 1 and branch tube boot 7 and fire protection pipeline 5
There is air duct 4, branch tube boot 7 and the end of air hose 1 to collectively constitute interface 3 between fire-fighting branch pipe 6.
Referring to Fig. 7, L-type air hose includes the fire protection pipeline 5 in L-shaped setting, and the bending place of fire protection pipeline 5 is covered in L
The air hose 1 of type setting, exhaust passage 4. is supported between air hose 1 and fire protection pipeline 5 by holder 2
The structure of air hose 1 uses fourth of the twelve Earthly Branches buckle structure, is made of two semicircles in left and right, interlocks when installation or so, often save
The male mouth of interface point and female mouth, interlock by box and pin between often saving and are attached and seal, and junction is fixed using cranse, hoop
Its size is equal to air hose outer diameter after circle tightening.The size of branch tube boot can be according to the size and length of fire hydrant branch pipe in tunnel
It determines.It is fixed by 4 fixing brackets between inner wall of the pipe and fire protection pipeline, keeps air hose and fire protection pipeline whole as one
Body.
Implementation for the purpose for realizing above-mentioned, cold area's pipeline heat-insulating system described in the utility model includes following step
Suddenly:
The first step reconnoitres the site environment temperature of required utilidor by field measurement and meteorological data investigation
Investigation determines the variation of ambient temperature rule along pipe arrangement direction.In investigation duct orientation after Temperature Distribution, draw extreme
At a temperature of temperature profile in duct orientation, in order to determine the working range of system;Due in the underground spaces such as tunnel
Then temperature more remote from hole is closer to year-round average temperature, therefore not pipeline full section is required for Insulation, to avoid waste.
Second step, heat loss in air hose, considers space when taking different insulation layer thicknesses according to scene temperature calculating
The factors such as limitation and cost, select suitable insulation layer thickness and power of fan:
It is assumed that being constant heat flow in air hose.
1, wind inner air tube reynolds number Re is calculated according to formula 1-1, judges air flow condition in air hose, calculated to spreading
Hot coefficient.
Re-Reynolds number (reflects fluid inertia force and viscous force relative size), vf- section mean flow rate;D-takes wind
Road equivalent diameter de;V-fluid kinematic viscosity
Air duct equivalent diameter deIt calculates as follows:
r1- fire protection pipeline outer diameter;r2- air hose internal diameter.
A large amount of result of calculations show it is different in flow rate in air hose in the case of Reynolds number be all higher than 104, illustrate air stream in air hose
It is dynamic to be in vigorous turbulence state.
2, the convective heat-transfer coefficient at fire-fighting tube wall is calculated.
h1- fire-fighting tube wall convective heat-transfer coefficient;Re-Reynolds number;Pr-Prandtl number (reflects fluid momentum diffusion energy
The relative size of power and heat diffusion ability);λf- fluid thermal conductivity;D-caliber (takes air duct equivalent diameter de);
3, the convective heat-transfer coefficient at air hose inner wall is calculated.
h2- air hose inner wall convective heat-transfer coefficient;Re-Reynolds number;Pr-Prandtl number;λf- fluid thermal conductivity;D-pipe
Diameter (takes air duct equivalent diameter);εl- pipe range correction factor;εt- temperature difference correction factor;εR- bend pipe effect correction factor.
Wherein, as l/d >=60, entrance influences less entire pipe average convection heat transfer coefficient, can not examine
Consider, i.e. εl=1.When gas is cooled, εt=1.When straight pipe is longer, bending tube section is to entire pipe average convection heat transfer coefficient
Influence it is little, can approximation take εR=1.
Because fire protection pipeline length is much larger than caliber in tunnel, and substantially straight line is arranged, therefore formula 1-3 can simplify
For:
4, the long heat output of fire-fighting tube wall unit tube (heat loss) is calculated.
According to it is assumed that wind inner air tube is constant heat flow, therefore mean temperature difference obtains according to the following formula
Δtm1=tw1-tf (1-6)
tw1- fire-fighting tube wall temperature (since fire protection pipeline belongs to thin-walled and thermal conductivity of material is fabulous, assert fire-fighting
Pipeline wall surface temperature is equal to water temperature in pipeline);tf- fluid temperature (F.T.).
The heat output of unit of account pipe range after acquirement mean temperature difference
Φl1=h1(πde)Δtm (1-7)
Φl1The long heat output of-fire-fighting tube wall unit tube;h1- fire-fighting tube wall convective heat-transfer coefficient;de- equivalent diameter;Δ
tm- mean temperature difference.
5, the long heat output of unit tube when different insulation layer thicknesses is calculated, is then controlled according to heat waste and needs to select suitably
Insulation layer thickness.
Calculate entire thermal resistance Rλ=Rf+R1+R2 (1-8)
Air hose inner wall thermal-convection resistance
Air hose thermal resistance
Insulating layer thermal resistance
Temperature difference t=tw2-tw4 (1-12)
Unit pipe range thermal flow meter is calculated
Rλ- entire thermal resistance;Rf- air hose inner wall thermal-convection resistance;R1- air hose thermal resistance;R2- insulating layer thermal resistance;h2In-air hose
Wall convective heat-transfer coefficient;d1- air hose inner diameter (i.e. air hose equivalent diameter);d2- air hose outer diameter (d2=d1+2δ1,
Middle δ1For air hose thickness);d3- insulating layer diameter (d3=d2+2δ2, wherein δ2For insulation layer thickness);λ1- air hose thermal conductivity;
λ2- insulating layer thermal conductivity;tw2- air hose inner wall temperature;tw4- insulating layer temperature outside (environment temperature takes average temperature);
Φl3- unit pipe range heat flow.
6, total heat flow is calculated, warm wind equipment power and quantity are selected according to total heat flow.
Unit pipe range total hot-fluid amount Φl=Φl1+Φl2 (1-14)
Total heat flow φ=Φll (1-15)
Wind turbine equipment quantity N=φ/P (1-16)
Φ-total heat flow;L-fire protection pipeline overall length;P-wind turbine thermal power;N-wind turbine quantity.
Different thermal insulation material heat preservation parameters and operating temperature need to be investigated, considers space and cost, thicker its of material is made
Valence is higher, and its operating temperature limits the output temperature of wind turbine, it is therefore desirable to make table and carry out material than choosing;Space limits
As limitation of the pipeline local environment to insulation layer thickness, this refers to spare spaces around fire protection pipeline present position in tunnel
Size;Suitable power of fan refers to, if tube circumference space is nervous, being not enough to apply enough insulating layers, then needing to improve
Power of fan is increased with offsetting the heat waste that insulating layer deficiency is brought.
Third walks, and site installation test is carried out according to result of calculation and drawing, and wind turbine suggestion is arranged in pump house, convenient for protecting
It is mild to safeguard.Wind speed and temperature point are arranged every a distance, monitoring data are read after system stable operation in air hose;It adopts
Wind turbine and measuring point are included in same system with technology of Internet of things, air hose temperature is monitored in real time by measuring point, when temperature is low in air hose
Start wind turbine when critical value, carry out pipe tracing, when temperature reaches safety value and closes wind turbine after stablizing in air hose, supervises
It surveys temperature in air hose and adjusts required time.
Point layout spacing must determine that rule is that air hose entrance is closeer according to duct length, and interlude is relatively dredged;System
Refer to that measuring point reads no fluctuation that tends to be steady after system stable operation;According to drawing installation refer to according to but be not limited to attached drawing into
The mounting arrangements of sector-style machine, air hose and measuring point must be adjusted correspondingly according to specific project situation;Measuring point refers to,
Wind speed and Temperature Humidity Sensor are arranged between air hose and fire protection pipeline, and system is connected by wired;Critical value refers to prevent pipe
Interior liquid freezes set minimum temperature to be heated;Safety value refers to that wind turbine is closed after minimum temperature reaches in system to reduce
The temperature of energy consumption.Internet of Things composition, air hose installation and point layout are shown in attached drawing.
4th step, after first group of test, after temperature is restored to critical-temperature in pipe, adjustment wind turbine wind speed and temperature
Degree, repeats above-mentioned test;
5th step arranges each group monitoring data, the heat waste that different test groups obtain is compared with desired heat waste, determines
Best wind speed and temperature.
Referring to Fig. 9, embodiment:
The first step reconnoitres the site environment temperature of required utilidor by field measurement and meteorological data investigation
Investigation determines the variation of ambient temperature rule along pipe arrangement direction.The tunnels Yang Jing are located in Wuqi County to deckle highway, the winter
Season, temperature was extremely low, is susceptible to fire protection pipeline and freezes unstability, winter extreme temperature is -25.4 DEG C, along pipeline side under extreme temperature
Upward temperature profile such as figure below (wherein 50,100m refer to depth in hole).Because natural wind in hole and traffic air are stronger, in hole
For temperature still in below freezing, it is -14 DEG C that mean temperature, which is calculated,.
Second step, heat loss in air hose, considers space when taking different insulation layer thicknesses according to scene temperature calculating
The factors such as limitation and cost, select suitable insulation layer thickness and power of fan:
It it is -14 DEG C according to mean temperature in hole is calculated, water comes from underground deep well in fire protection pipeline, and temperature is 5 DEG C, to disappear
- 14 DEG C of 5 DEG C of anti-pipeline water temperature, environment temperature calculating heat loss, it is assumed that air is dry air and is constant heat flow:
When air velocity takes 5m/s or higher, reynolds number Re is all higher than 104, illustrate that air flowing is in vigorous rapids in air hose
Stream mode, convective heat-transfer coefficient increases with Reynolds number and is increased known to formula (1-3) and formula (1-5), and Reynolds number and spy
It is directly proportional (1-1) to levy flow velocity, therefore the more big then heat loss of wind speed is higher, this sentences 5m/s as feature flow velocity.Air hose material is
PVC material, thickness 10mm, thermal insulation material are polyurethane material, thermal coefficient 0.038, ignore air hose and thermal insulation material it
Between thermal contact resistance.
According to calculating it is found that the more high then heat loss of air themperature is bigger, insulation layer thickness contributes unit pipe range heat loss
Less, while in order to avoid causing without heat source in air hose because of wind turbine unstability, therefore insulation layer thickness is also unsuitable excessively thin, selects herein
30mm thickness polyurethane is selected as insulating layer.10 DEG C are selected as average air temperature, then needs the power of fan to be for every hundred meters
5.11kw uses power of fan for 15kw, and separate unit substantially meets the heat demand of entrance 300m.It is handed in Portal Section and barrel section
A wind turbine is arranged at boundary again, then single hole tunnel need to arrange that 4 Fans carry out heating operation altogether.
Third walks, and carries out site installation test according to result of calculation and drawing, wind turbine suggestion is arranged in pump house and hole
At 290m, convenient for heat preservation and safeguard.Portal Section arranges wind speed and temperature point every 50m in air hose, and barrel section is every 100m cloth
Measuring point (measurement task can be completed using airspeedometer) is set, monitoring data are read after system stable operation;Using Internet of Things skill
Wind turbine and airspeedometer are included in same system by art, and air hose temperature is monitored in real time by measuring point, when temperature is less than critical value in air hose
Shi Qidong wind turbines carry out pipe tracing, when temperature reaches safety value and closes wind turbine after stablizing in air hose, monitor in air hose
The time required to temperature is adjusted.
Refer to that measuring point reads no fluctuation that tends to be steady after system stable operation;According to drawing installation refer to according to but not
It is limited to the mounting arrangements that attached drawing carries out wind turbine, air hose and measuring point, must be adjusted correspondingly according to specific project situation;It surveys
Point refers to arranging wind speed and Temperature Humidity Sensor between air hose and fire protection pipeline, system being connected by wired;Critical value refers to
To prevent liquid in pipe from freezing set minimum temperature to be heated, it is set as 5 DEG C herein;Safety value refers to lowest temperature in system
Degree closes wind turbine to reduce the temperature of energy consumption after reaching, be set as 10 DEG C herein.Air hose is installed and point layout is shown in attached drawing 9.
4th step, after first group of test, after temperature is restored to critical-temperature in pipe, critical-temperature at this time is 5 DEG C,
Wind turbine wind speed and temperature are adjusted, above-mentioned test is repeated;
5th step arranges each group monitoring data, the heat waste that different test groups obtain is compared with desired heat waste, determines
Best wind speed and temperature.
The implementation of the utility model calculates convective heat-transfer coefficient first, then calculates the convection current heat transfer system at fire-fighting tube wall
Unit tube when number, the convective heat-transfer coefficient at air hose inner wall, the long heat output of fire-fighting tube wall unit tube and different insulation layer thicknesses
Long heat output needs to select suitable insulation layer thickness, finally calculates total heat flow, selected according to total heat flow according to heat waste control
Select warm wind equipment power and quantity, can to choose pipeline heat-insulating system play the role of it is guiding, guarantee reached with smaller cost
To the effect of heat preservation, cost is reduced, improves efficiency.
Claims (6)
1. a kind of cold area's pipeline heat-insulating system, which is characterized in that including with water pump (11) connecting pipe, and be wrapped on pipeline
Several section air hoses (1), the head end connection wind turbine (9) of air hose (1), air hose (1) are fixed on the outside of pipeline by holder (2), managed
There are air duct (4) between road and air hose (1), wind turbine (9) is accessed by Fan pipeline (8) in air duct (4).
2. a kind of cold area's pipeline heat-insulating system according to claim 1, which is characterized in that air hose (1) includes linear type wind
Pipe, L-type air hose and T-type air hose.
3. a kind of cold area's pipeline heat-insulating system according to claim 2, which is characterized in that linear type air hose includes and water pump
(11) connecting pipe, and it is wrapped in several section straight line air hoses on pipeline.
4. a kind of cold area's pipeline heat-insulating system according to claim 2, which is characterized in that T-type air hose includes T-shaped setting
Fire protection pipeline (5) and fire-fighting branch pipe (6), the corner of fire-fighting branch pipe (6) and fire protection pipeline (5) be provided with L-shaped branch pipe
The outside of sheath (7), fire protection pipeline (5) side is provided with air hose (1), and air hose (1) is collectively covered with branch tube boot (7) in fire-fighting
Pipeline (5) and fire-fighting branch pipe (6) outer surface, have between air hose (1) and branch tube boot (7) and fire protection pipeline (5) and fire-fighting branch pipe (6)
There are air duct (4), branch tube boot (7) and the end of air hose (1) to collectively constitute interface (3).
5. a kind of cold area's pipeline heat-insulating system according to claim 2, which is characterized in that L-type air hose includes L-shaped setting
In fire protection pipeline (5), the bending place of fire protection pipeline (5) is covered with the air hose (1) of L-shaped setting, air hose (1) and fire protection pipeline
(5) air duct (4) are supported by holder (2) between.
6. a kind of cold area's pipeline heat-insulating system according to claim 1, which is characterized in that pass through between adjacent air hose (1)
Box and pin connects.
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CN201820169526.6U CN207830759U (en) | 2018-01-31 | 2018-01-31 | A kind of cold area's pipeline heat-insulating system |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108278423A (en) * | 2018-01-31 | 2018-07-13 | 长安大学 | A kind of cold area's pipeline heat-insulating system and test method |
CN109939409A (en) * | 2019-03-21 | 2019-06-28 | 杭州吉宝传动设备有限公司 | Pipeline constant temperature protects slide device and its control method |
-
2018
- 2018-01-31 CN CN201820169526.6U patent/CN207830759U/en not_active Expired - Fee Related
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108278423A (en) * | 2018-01-31 | 2018-07-13 | 长安大学 | A kind of cold area's pipeline heat-insulating system and test method |
CN109939409A (en) * | 2019-03-21 | 2019-06-28 | 杭州吉宝传动设备有限公司 | Pipeline constant temperature protects slide device and its control method |
CN109939409B (en) * | 2019-03-21 | 2021-02-26 | 杭州吉宝传动设备有限公司 | Pipeline constant-temperature protection sliding device and control method thereof |
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Granted publication date: 20180907 Termination date: 20210131 |