DE2404366A1 - PROCESS FOR CREATING CONDENSATE DROPS ON HEAT EXCHANGER TUBES - Google Patents

Description

PATENT ADVOCATE

DR. HANS ULRICH MAY

D S MUNICH 2, OTTOSTRASSE 1a TELEaRAMME: MAYPATENT MUNICH

TELEPHONE CO81-O 593682 2 A 0 A 3 6

CP 475/1251 Munich, January 3, 1974

B 4699.3 in ^Dr ' ^{M / ws}

Commissariat ä I ¹ Energie Atoiaique in Paris / France and Societe Produits Chirniques ügine Kuhlmann in Paris / France

Method for inducing the formation of condensate droplets

Heat exchanger tubes

The invention relates to a method for bringing about the formation of condensate droplets on heat exchanger pipes, especially in maize water distillation systems is applicable.

As is known, an important problem in heating plants, thermal power plants ₅ in chemical plants and seawater desalination plants is the high price of the heat exchangers, especially when these heat exchangers consist of tubes made of relatively noble metals (copper alloys, nickel alloys, titanium). Efforts are therefore made to substantially reduce the investment costs required by improving the heat exchange quality in order to be able to reduce the heat exchanger surface.

One means of achieving this improvement is to the formation of a condensate film on the outer wall of the heat

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Prevent exchanger tubes and scatt its for condensation to provide in teardrop form. 2404366

A consideration of the classic case of capacitors with cylindrical Tubing shows that the overall heat exchange coefficient between the vapor to be condensed and the coolant is reduced calculated using the following equation?

"W ~ '" tr ^{+ r} p ^{+ r} t ⁺

1 ^l C

where h. the heat exchange coefficient to the interior of the pipe, is on the coolant side;

h is the heat exchange coefficient of condensation atif the outside of the pipe, i.e. on the steam side,

r is the thermal resistance of the wall and

r. _{t is} the thermal resistance of the scale and impurities.

In the current most common case, v / o you have too much deposition Clay scale or dirt through appropriate pretreatment of the coolant and v / o the wall is made of a sufficiently thermally conductive material (e.g. a copper alloy), the various terms of formula (i) essentially have that following weight:

40 % for the limb

20 % for the sum r + r _t
40 % for the expression i / h _c

It can be seen from this that, for example, with an improvement in the condensation _{coefficient h c} by a factor of 2, the total heat exchange coefficient increases by a factor of 1.25.

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The improvement in the iCoudetisacJonsf coefficient is obtained, by creating a drop-shaped condensation on the outer or inner wall of the heat exchanger tube. So that this takes place, you have to make the wall hydrophobic, i.e. not wettable by water. The steam then condenses in the form of drops, which are preferred Points of the wall arise and grow and, when they have reached a sufficient size, roll along the wall and break away from it. The main part of the pipe wall is free of liquid and is in direct contact with the Steam, which increases the heat exchange coefficient.

The following measures are currently known to make the outer or inner wall of heat exchanger tubes hydrophobic:

For example, this wall can be provided with a hydrophobic coating. This coating must consist of a fairly good heat-conducting material or as an extremely fine layer be secluded. The coating must also be very durable and have a practically unlimited life. Currently Coatings made of gold or chrome give good results, but have the disadvantage of extremely high costs.

One can also use organic agents to promote the drop-shaped condensation, such as copper oleate, octadecylamine, mercaptans Silicone oils etc. These products are introduced into the vapor phase and come in powder form in the liquid phase or vapor phase in contact with the heat exchanger tube. You mix with that Steam and excrete on the outer or inner wall of the pipe, where it is absorbed, in the form of a thin skin or monomolecular Shift off. These organic products must be non-toxic

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and must not corrode the pipes. 2404366

The invention now aims at a method for bringing about Formation of condensate droplets on heat exchanger pipes due to the action of a particularly favorable one that promotes condensate droplet formation By means of,

According to the invention, this object is achieved in that, in such a method, at least one chemical compound is added to the feed steam before it passes over or through the pipe _s which ax \ s consists of a fluorine derivative of the following general formula:

where η and a are each an integer between 2 and 20 and X a functional group which can anchor the fluorinated product to the pipe wall.

The fluorine derivatives defined above are described in FR-PS EN 71 43253 of the Societe ügine Kuhlmann. If you have these connections Added to the steam fed in, they adhere to the pipe wall and form a coating with excellent hydrophobic and deophobic properties. In this way, the process according to the invention enables condensation in the form of drops not only of water vapor but also from the vapors of organic liquids.

The following products may be mentioned as examples of the fluorine derivatives which can be used in the process according to the invention:

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₀ - (CF ₀ ) - C ₀ H. - COOH

^C00H

CF ₃ ~ ( ^CP 2 ^ n ~ ^C 2 ^H 3 ^{C1 OPO} 3 ^H 2

CP

₃ - (CPg) _n - C ₂ H ₄ - SO ₂ NH - (CH ₂ ) ₆ OH

CpHoGJ. - OPO ₃ Hp few ^ - GOOH C ₂ H ₄ - SH

K - ^c pH _A S0 _o ■ "N (Cn") - CoH.OH

which give excellent results on stainless steel walls and

CF ₃ CF ₃ CF ₃ - (CP ₂ Y _n

which give excellent results on copper walls.

The method according to the invention can also be carried out with the aid of substances Compositions based on fluorine-containing polymers and copolymers carried out, for example, in FR-PS 08366 of the Societe Produits Chimiques Ugine Kuhlmann are described

According to an advantageous development of the invention, the fluorine-containing derivative is a fluorinated disulfide of the general Formula;. .

8 - (CH ₂ ) _a - C _n P _{2n + 1}

used, wherein C _n F _2n ^ means a perfluorinated straight or branched chain and η and a are each an integer between 2 and 20.

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These polyfluorinated disulfides are described in the PR-PS No EN 72 03932 of the Societe Pechiney-Ugine Kuhlmann. These polyfluorinated Disulfides give particularly good results in the process according to the invention.

According to the invention, the polyfluorinated compound or compounds are introduced Products in the vapor phase either

-by mixing with the liquid which is to provide the feed steam, the fluorinated products pressure distilling with their own steam, or
by passing the steam over or through a solution or emulsion of the fluorinated products in water, or by mechanically injecting the fluorinated product or products, optionally dissolved in a solvent, into the feed steam in the form of a mist.

According to an advantageous embodiment of the invention the fluorinated product (s) used together with a customary aid to promote the formation of condensate droplets. The introduction of these different compounds can be done either simultaneously or separately.

The introduction of the fluorine derivative into the feed steam can be carried out either continuously or discontinuously. It is preferably done discontinuous, since the life of the fluorinated products is very long, which means that the addition is very slow Sequence of steps and thus enables considerable savings.

For certain applications, especially in plants for the desalination of sea water, it is absolutely necessary that the agent for inducing condensation droplets is non-toxic.

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This is the case with the method according to the invention, since the use ten fluorinated derivatives have a sufficiently long perfluorinated chain in their molecules that the toxicity is sufficient diminishes or completely eliminates.

The invention is illustrated with reference to the attached figure, which is schematic shows a Verdampfimgs condensation system explained through the following examples.

The device used is shown in the attached figure. It has a steam generator 1 ₁ to a condensation chamber 2 and a cooling system. 3

The steam generator 1 made of stainless steel is one Cylindrical chamber with a diameter of 0.5 m and a length of 1 m, containing about 100 liters of desalinated water (treated with permutite) holds. It is heated by immersed heating elements 4, which are fed with three-phase electricity and have a maximum output of 36 KW hand over.

The condensation chamber 2 consists of a cylinder made of chemically and heat-resistant glass 1 m long and 400 mm in diameter, by a layer of glass wool with two observation windows is thermally insulated. The condensation chamber 2 is connected to the steam generator 1 by a heat-insulated line 5 made of rustproof « em steel, whose inner diameter (160 mm) is calculated in this way is that the steam enters the condensation chamber at a rate not over im / selc.

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A measuring tube 6, on which the condensation takes place, leads through the condensation chamber 2. This tube 6 is 900 mm long and has an outer diameter of 25 mm and a wall thickness of 1 mm. It is thermally insulated from the walls of the chamber 2 by rings 7 made of polytetrafluoroethylene ("Teflon ¹¹ ~ E.WZ.").

Through the pipe 6 flows water of the cooling circuit 3, which is directly is connected to the city water pipe. The water is circulated by a pump 9 in the cooling circuit, which under can deliver 15m / h under the applied operating conditions. the Adjustment of the temperature of the coolant is carried out by continuously supplying water from the city water network, the regulation being carried out by hand by adjusting the needle valve 10, which derives the from the outlet of the condensation chamber 2 incoming heated cooling water controls.

The high throughput of the water flowing in each pipe is chosen so that the temperature increase caused by the steam condensation of the pipe 6 is small in terms of the temperature difference between the steam and the cooling water. In this example the tube 6 is made of copper.

_{A polyfluorinated disulfite compound of the formula (CgP 1} ^ C ₂ H ₄ S) ₂ is now introduced through line 11 into the steam coming from the steam generator 1. Approximately 38 mg of this compound must be introduced to obtain 1m ° condensate. A single injection of (CgP ₁₇ C ₂ H ₄ S) _{2 produces a teardrop shape}

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Condensation for more than 2500 hours, which shows that the life of the compound (CgF ₁₇ C ₂ H ₄ S) _{2 is} very long.

Example 2

The same apparatus as described in Example 1 is used. The tube 1 here consists of a copper-nickel alloy.

When the apparatus is started up, they form on the surface of the pipe 6 different colored stripes and spots, which are caused by condensate threads that form on the pipe and it oxidize.

Under these conditions the compound (CgF ^ ₇ C ₂ H ₄ S) _{2 would} only be fixed to the tube 6 with difficulty. A mixture is therefore used consisting of the compound (CgF ₁ .7C ₂ H ₄ S) _? and the acid CgF ₁₇ C ₂ H ₄ COOH. This acid enables the disulfide derivative to be fixed. A mixture of 1/3 of the acid and 2/3 of the disulphide is injected once through line 11 and a drop-shaped condensate formation is thus obtained for more than 2500 hours.

In the previous two examples is the total heat exchange coefficient increased by a factor of 3.

Example 3

Further investigations were made with other compounds and one Stainless steel condensation pipe carried out.

The agent to be tested which promotes the formation of condensate droplets was introduced into the vapor phase. The type of condensation obtained, namely as a mixed film or in the form of drops, was observed. The following table lists the results:

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«. 10 ··

Additional form of the condensate imagexuvj

C ₈ P ₁₇ (CfIg) ₁₀ COOH: drops

C ₈ F ₁₇ C ₂ H ₄ SO ₃ H: Mixed condensation on injection;

ends when the injection is finished

C ₆ F ₁ 3CHCl-CH ₂ OPO ₃ H ₂ same O ₇ F ₁ C-COGH ₀ -COCH ,, * same (CgF ₁₇ C ₂ H ₄ S) ₂ : drops on injection, drop formation

ends when the injection is terminated

Example 4

The tests of Example 3 are repeated with a condensation tube made of ordinary steel. With (C ₈ F ₁₇ C ₂ H ₄ S) ₂ a good cone-like droplet mixture is obtained.

Example 5

The tests of Example 3 are repeated with an aluminum condensation tube. After several injections of (CgF ₁₇ C ₂ H ^ S) ₂ , a condensation in the form of drops is obtained.

Example 6

The tests of Example 3 are repeated with a condensation tube made of copper alloy.

The following table gives the results obtained:

Addition i

: Excellent droplet formation - very large lifespan

: the same

7210 ^: ^ ⁿ ' ^Sro P ^ ⁿ ^ ^OTm "for a few hours

₇ (CH ₂ ) ₄ -NH ₂ : same.

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Claims (11)

1. / Method for inducing the formation of condensate droplets Heat exchanger tubes, characterized in that the feed steam before its passage through or over the tube at least a chemical compound is added, which is derived from a fluorine derivative of the general Poi ^ mel <> a - ^x consists, in which X is a functional group, which the adhesion of the fluorine-containing product can cause on the wall of the pipe, means and η and a are each an integer between 2 and 20. 2, The method according to claim 1, characterized in that one as a fluorine-containing derivative, a polyfluorinated disulfide of the general Formula: used, where C _n F ₂ ^ means a straight or branched perfluorinated chain and both η and a are an integer between 2 and 20. 3. The method according to claim 1 or 2, characterized in that the fluorine derivative is added by adding it to the liquid mixes which is to form the feed steam » 4. Method according to claim 1 or 2, characterized in that the fluorine derivative is added by passing the feed steam through or over an emulsion of the fluorine derivative in water. 409832/0830 5 »The method according to claim 1 or 2, characterized in that the fluorine derivative is added ₉ by being in the form of a
Mechanically injected mist into the feed steam. 6. Method according to one of Claims 1 to 5, characterized in that the addition of the fluorine derivative to the feed steam
continuously 7 * Method according to one of claims 1 to 5 _t characterized in that the Susatz of the fluorine derivative is discontinuous to the feed vapor · 8. The method according to any one of claims 1 to 7 »characterized in that a compound of the formula as the fluorine derivative
(CgF ₁₇ G ₂ H ₄ S) ₂ is used. 9. The method according to any one of claims 1 to 8 »characterized in that that a mixture of fluorine derivatives is used. 10. The method according to claim 9, characterized in that a compound of the formula (CgF ₁₇ C ₂ H ₄ S) _{2 is used} in combination with an acid of the formula CgF ₁₇ C ₂ H ₄ COOH as the fluorine derivative. 11. Application of the method according to one of claims 1 to 10, in plants for the desalination of sea water « AC9832 / 0830