EA026190B1 - Heated pipeline system - Google Patents

Abstract

The invention is related to the field of pipeline transport and can be used for maintaining pipeline temperature in the operating range, for protection against freezing and for starting heating of pipelines to the operating temperature. A heated pipeleine system includes at least one section of a metal pipe lined with an insulating layer, electrodes connected to the metal pipe, and an electric power source with a control system. A specific feature of the pipeline system is that the lined pipe is a metal pipe lined inside with cast stone material, through holes are made along the pipe length, electrodes are inserted in the holes in a sealed way, one ends of the electrodes contacting the pipe and the other ends contacting the pulp being pumped over.

Description

The invention relates to the field of pipeline transport and can be used to maintain the temperature of pipelines in the operating range, as well as to protect against freezing of pipelines and starting heating of pipelines to operating temperature.

The operation of pipes and pipelines laid above the ground or in the ground at freezing depth in the cold season is associated with certain difficulties: the pipe cross-section is narrowed, the temperature decreases and the viscosity of the transported liquids increases, plugs form, the product freezes and the pipeline is destroyed. The use of high-quality heat-insulating material reduces the direct impact of cold on the pipeline, but cannot fully protect it from freezing or lowering the temperature of the transported liquid.

The most economical and easy to manage track electric heating using a direct or indirect heating system.

With direct impedance heating, alternating or direct voltage is applied to the ends of the heated section of the pipeline.

Track heating tools are usually mounted under a layer of thermal insulation on the surface of the pipe.

To compensate for heat loss, a heating cable is mounted on the pipeline. The heating cable is selected so that the amount of heat generated by it is greater than the heat loss of the insulated pipeline in each section of the pipe. The insulation must be insulated from moisture.

Direct heating is simple and reliable in operation, but its application requires the implementation of special technical solutions, it is unsafe for maintenance personnel and is used in critical situations: when an oil pipeline with frozen oil starts up and other means of track heating fail [Edigarov S.G. Design and operation of oil depots and gas storages. Nedra Publishing House, Moscow, 1973, p.199]. In addition, heating the pipe itself requires good thermal insulation from the environment. In addition, such pipes have low resistance and have a limited life.

For indirect heating, heating elements in the form of tapes and cables and coaxial heaters located on the surface or inside the pipeline are used.

Such heating also requires good thermal insulation of pipes and has low efficiency.

With the internal heating method, the satellite pipeline is located inside the pipeline.

This solution also has its drawbacks. At the same time, the effective cross-section of the pipeline decreases, as well as the requirements for the stability of the internal pipeline increase, and its maintainability decreases.

The closest solution for formal features is the solution for US patent 6292627. In this solution, the pipeline is composed of two concentric pipes with electrical contacts and insulators. In this case, the pipeline can be segmented, and the contacts can be connected in various dreams of the pipeline.

This solution also has all of the above disadvantages.

The objective of the invention is the creation of a reliable and durable design and piping system for transporting various liquids and mixtures in cold conditions and increasing the efficiency of such a system.

The objective of the invention is solved as follows.

Heated pipe system, which includes at least one section of a metal lined with an insulating layer of pipe, electrodes connected to a metal pipe and an electric current source with a control system. In this case, a metal pipe lined inside by stone casting is used as a lined pipe. Moreover, through holes are made through holes in which electrodes are hermetically inserted, one ends of which have contact with a metal pipe, and the second with pumped pulp.

In one improvement, the electrodes are made of graphite.

In another improvement, the surface of the electrodes in contact with the pulp is made of graphite.

The drawing shows a longitudinal and transverse sections of the proposed system.

The pipeline or its segment is made of a steel pipe 1, lined inside with stone casting 2, for example, basalt casting.

Between a steel pipe and stone casting there may be an intermediate layer of a bonding solution or additional thermal insulation. Such pipes are commercially available and can have a length of 1 to 11 m. CJSC Conveyor Equipment Plant, 623107 Russia, Sverdlovsk Region. Pervouralsk, Serova St., 4A 1i1r: ///ao/co.gi/5Yughe/32982/33006/. Also, such pipes are also produced by other companies, for example, lined pipes with stone-cast liners by the Company EIT1T c.ga. 1i1p: // \ y \ y \ u.siO1.s //. Repd1a1 Niaap WakaB R1re1te Co., Iy. Nyr: //ep.ka/5d | .sp /. But the best suited are solid pipes LLC Dnieper Lining Plant based on LMT manganese stone casting (102/2 Heroes of Chernobyl St., Nikopol, Dnipropetrovsk Region, 53221, Ukraine).

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Along the pipe with a certain calculation step, there are holes with hermetically mounted electrodes 3. Such electrodes can be made of graphite, or have a graphite coating that ensures the inertness of the electrode with respect to the transport medium. In this case, the pipe itself is usually connected to the grounded pole of the current source 4, and the electrodes, through insulated wires 5, to the second pole of the source through the regulating device 6 and the electrode 7 in contact with the transported medium.

An alternate connection of electrodes is also possible. In this case, part of the electrodes should be isolated from the external pipe.

The system works as follows. If necessary, the heating control device connects the necessary current for this to the electrodes 6 and 7 of the pipeline. This current acts on the transported medium and heats it directly. This method of heating is the most effective, because all its energy is spent directly on heating the transported medium.

Pipes lined on the inside by stone casting have a longer service life, high abrasion resistance and a sufficiently high thermal insulation. In this case, the lining layer is both an electric and thermal insulator and a protective layer during heating.

Calculation of thermal efficiency is given below.

1. Calculation of the melting of the pulp in the pipeline according to the heat balance.

To calculate the required amount of heat to ensure the melting of the frozen pulp, we determine the conditions of the thermal regime during an emergency stop in the layers of the slurry pipeline (denoted as state 0). Suppose that the pulp has cooled to a certain average temperature T _cf and that the temperature across the pulp cross section differs little from the average, i.e. for assessment, the temperature at the boundary of the pulp and the lining T ₁ will be equal to Tav.

We define the amount of heat c ₁ passing through the wall of a pipe of length 1. For a cylindrical steel pipe with an inner lining, we write:

Here T ₁ is the temperature at the boundary of the pulp and the lining,

T ₂ - the temperature at the border of the lining and the steel wall,

T ₃ - temperature at the outer boundary of the steel wall,

T _n is the outside air temperature, the thermal conductivity of the lining, the thermal conductivity of steel, the inner diameter of the pipe (the space occupied by the pulp), the diameter of the pipe taking into account the thickness of the lining, the outer diameter of the pipe, α is the heat transfer coefficient from the steel pipe to the environment.

Given these definitions, the heat flux passing through the pipe surface per unit time through the unit length of the pipe surface is λι ^λ 2 'ι ^D 2 Dz

where K _Tr - heat transfer resistance of the pipe walls,

DT - temperature pressure from the pulp to the environment.

The temperatures at the boundaries of the lining and the steel pipe with the environment are equal

Due to the relative smallness of the thickness of the lining and the steel wall for evaluation, we assume that the temperature varies linearly inside these layers.

For example, for lining

Τ ^ Τι-ίΤι-Τζ) - ^^

G2-P

Then the heat content per unit length of the frozen pulp:

H „= 0.5r„ Wed „2et] (Το + T]) = that! ιρ _; , Ο „Τ ^e P linings (4)

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0.5р ^ С ρψ2π (Γ ₂ -η) (Τι + Τ:) = Ο.5ρφ6ρψπ (ά: -άι) (Τι + Τ>) (5) steel wall

Η _£ ™ = О.5р _ст , Сг _с , „2я (гз-г ₂ ) (Т2-1-Тз) = О.5р _{ст |} Compare _with "31 (az- <12) (T2-1-Ts)

At the moment the pulp has melted (state 1), the heat content of the pipe with the melted pulp will be set by the heat content of the steel wall, lining and the melted pulp:

H '= aa, p „C _d , Tr, (7) = Ο.5ρ _φ ϋ ^ π (ά ₂ -άι) (Τι ^] + Τ ₂ '), (8)

Η '™ = O.5r ™ C _Lt <-ά ₂ and ₃₎ (Τ _2> + Τ _3'). (nine)

Here T ¹ sr may be equal to the melting temperature of the pulp (for example, the melting temperature of ice is 273 K), if it is necessary to melt it, and not heat it.

The amount of heat required to heat a unit length of the pipe with the pulp and its transition from state 0 to state 1 is equal to the difference in heat content, taking into account the heat spent on thawing snow Н ¹ т = пб ₁ р _п б _п :

О-Н, '- Ηθ + Ηφ-Ηθ + н _{£ т} -н ° „+ н /„. (10)

In fact, this difference determines the required power of the heaters to ensure the melting of the pulp.

If we have a cylindrical heater, then the specific surface power (W / m ² ) released in the conductor during the passage of electric current is

4EP ^{2 φ_} π ² υ ² ά ³ where P is the volumetric power of the heater,

K is the specific resistance of the heater material, and is the voltage at the heater, ά is the diameter of the heater.

Let us estimate the minimum required number of heaters to ensure heating of a unit of pipe length. The surface area of the heater is equal to ^^ heat> then the amount of heat leaving the system per unit time is equal to ^la ^ heat> Then, for some given period of time Δΐ, the heat ^ C // нррфМ will go into the pipe, (11) thereby to ensure heating of the pulp per unit length of the pipe before transitioning to state 1 for a period of time Δί requires the number of heaters not less (or better with a margin) n = 0 / (kS // nagrfDO. (12)

To heat the pulp in a pipe of length 1, respectively, p1 heaters are needed.

2. An example of a calculation based on the data presented.

Data:

ά ₁ = 0.516 m, ά ₂ = 0.616 m, ά ₃ = 0.630 m

Let the outdoor temperature T _n = 243 K.

Suppose the pulp has cooled to T _cf = 263 K.

It is necessary to heat it to the melting temperature, i.e. in the state of 1 T _cf = 273 K.

Thermal conductivity of the lining λ! = 1.37, steel λ ₂ = 47,

The specific heat of the lining is 850 J / kg K.

The heat capacity of steel is 500 J / kg K.

The density of steel is 7700 kg / m ³ '

Lining density 3000 kg / m ³ (average).

Specific heat of fusion of ice L _n = 330,000.

According to the parameters for steel pipes, the heat transfer coefficient is approximated depending on the diameter at a wind speed of 6 m / s:

α = 27.54429-14.03χά ₃ + 4.67857χά ₃ χά ₃

In our case, α = 20.56.

The heat capacity of the slurry depends on the density of the pulp _Pn = 12.48818 - 0.01151hr _n + 3.19828E - 6hr _n hr _n

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We take for the estimated density of the pulp equal to p _p = 1142 kg / m ³ .

Then the specific heat is equal to C _Pn = 3520 J / kg K.

Heater dimensions ά = 0.057 m, load = 0.057 m.

3. Calculation of the melting of the pulp in the pipeline according to the heat balance.

1. We find the temperature head in state 1 and the heat transfer resistance in the formula (1):

ΔΤ = T _cf -Tn = 20K,

To _mp = 0.3055.

2. We find the temperature of the layers in state 0 according to formulas (2), (3):

T ₂ = 254.54 K,

T ₃ = 253.11 K.

3. Similarly, we determine the temperature for the layers in state 1 by formulas (2) and (3):

The temperature head is ΔΤ = 30 K.

T \ = 260.30 K,

T \ = 258.16 K.

4. According to formulas (4) - (9) we find the difference in the heat contents of the layers and pulp:

H ¹ P - H ⁰ P = 65164091.033 N ^! f - H ⁰ f = 6312716.278,

H ^! st - H ⁰ st = 915238.617.

5. The amount of heat to melt the pulp

II ¹ ,,, = πάιρ _η Τ _η = 610603646.4.

6. We find O by the formula (10):

O = 682995691.

7. We find the amount of heat from the heater according to formula (11) for the time, for example, per day = (3600x24) seconds for a given specific power φ of the surface of the heater that can be provided.

8. The number of heaters is calculated by the formula (12).

Such a combination of features, such as the combination of the properties of pipes molded inside by stone casting, graphite electrodes and their connections provide reliable and durable operation of pipelines in adverse conditions and in a wide range of temperatures of transported media, including chemically active and abrasive components. In emergency cases, during freezing of the pulp, such a system ensures the restoration of transportation, as well as the prevention of such situations. The combination of stone casting and a graphite heater has favorable temperature parameters. Both materials are also chemically resistant even at high temperatures. Other heaters may also be used, but the graphite coating of such a heater on the surface of contact with the pumped medium is preferred.

Thus, the present invention has novelty, inventive step and is technically feasible.

Claims (3)

CLAIM 1. A heated heating pipe system comprising at least one portion of a metal lined pipe with an insulating layer and an electric current source whose poles are connected through a control system to a metal pipe and a transported medium, characterized in that a metal pipe lined inside is used as a lined pipe stone casting, moreover, through holes are made through holes in which electrodes are hermetically inserted, one ends of which are in contact with a metal pipe, and the second - with pumped pulp. 2. The system according to claim 1, characterized in that the electrodes are made of graphite. 3. The system according to claim 1, characterized in that the surface of the electrodes in contact with the pulp is made of graphite.