DE8019202U1 - Coaxial heat exchanger - Google Patents

Description

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M.A.N. MASCHINENFABRIK AUGSBURG-NÜRNBERG Aktiengesellschaft

Munich, June 27 , 1980

Coaxial heat exchanger

T5 The invention relates to a coaxial heat exchanger for heat pumps, consisting of a main pipe in which at least one inner pipe is arranged.

Shell-and-tube heat exchangers are usually used in heat pumps used, which consist of a short hollow cylinder in which a large number of inner tubes are arranged are. The ends of the inner tubes protruding from the hollow cylinder become smaller in diameter bundled and with the connecting cables for the

Connected flow circuit of a first working medium. However, this is very complex in terms of production technology Procedure. Apart from that, these known heat exchangers, because of their relatively large size Diameter designed with a very thick wall thickness

to withstand the high pressures occurring in the heat exchange process. Also requires a such a heat exchanger of a very large filling volume for the working media.

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These factors affect in particular the weight and the manufacturing costs of the heat pumps equipped with such heat exchangers. The use of such heat exchangers for heating single or multi-family houses is therefore very unprofitable if you also consider that the use of heat pumps can currently save up to 45% of the primary energy.
10

So far, the principle of compressor chillers has been used for heat pumps applied. In these heat pumps, which usually contain fluorocarbons such as Frigen are used as refrigerants, the heat exchangers ^ 5 are made of copper or brass. The principle of Sorption chillers can also be used for heat pumps can be applied. In these cases, ammonia is used as the refrigerant. The known heat exchangers are used for this purpose but unsuitable because the copper or brass

^w is attacked by ammonia.

The invention is based on the object of a heat exchanger to develop of the type mentioned, which is suitable to be used in heat pumps of any kind

to be able to, and while maintaining a high degree of efficiency, the concerns of using the heat pumps for heating taken into account by family houses.

The object is achieved in that the

Casing tube has a smaller diameter in relation to its length and spirals with the inner tube, or is helically or meander-shaped, and that the The dumbbell and the inner tube are made of steel.

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With such a heat exchanger it is achieved that this component, while improving its efficiency, has a significantly smaller overall volume than the conventional ones Receives steel heat exchanger. Due to the considerably smaller diameter of the main pipe, you can significantly thinner wall thicknesses are used in the heat exchanger according to the invention, which also applies to Use in the areas of higher pressure of a heat pump recorded a relatively small mass and thus low weight can be. The manufacturing technology is also much easier by using a much smaller number of inner tubes, in the range of 7 tubes on average find which at their ends connect much more easily or even directly to a manifold 1assen.

The heat exchanger according to the invention can also use for all points in a heat pump process, ^ O in c'.enen a heat transfer from one medium to one other things take place, e.g. in the condenser, in the evaporator, in the temperature changer, absorber, etc. This general use leads to a profitable, inexpensive series production of standardized heat exchangers according to the invention. Taking into account the usability this heat exchanger for both compressor heat pumps and absorption heat pumps more aggressive working media, the manufacturing costs by increasing the series production numbers

further reduced.

These advantages are all reflected in the reduction in the total weight and price of heat pumps out, making an important contribution to profitability

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is provided by house heating heat pumps, especially a heat pump is equipped with several heat exchangers at the same time.

The unit according to the invention has the further advantage that it can be achieved by a relatively simple variation of its basic geometry allows adaptation to the requirements of different heat exchangers. It is also possible, reduce the number of inner tubes and use Use ribbed inner tubes.

The small container volume and the small mass make it possible In connection with the media forced control, a quick response to changes in performance and moreover a good urine transition even with small volume flows, whereby a high degree of efficiency is achieved even with small temperature differences. This also bears this contributes to the use of the heat exchanger according to the invention on as many process engineering applications as possible to expand.

_{Carbon steels or chromium-nickel steels using sodium dichromate (Na 2} Cr O ₇ ) as an inhibitor can preferably be used for the parts of the heat exchanger exposed to ammonia or ammonia-water solution.

The invention extends to a method for producing a heat exchanger characterized in claim 1.

The inventive method consists in after Assemble the cut-to-length inner pipes with the casing pipe a liquid, in particular water, into the casing pipe and to fill a cooling brine into the inner pipes, and

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the heat exchanger tube after the water has frozen to bend a mandrel.

It is known that the bending processes of pipes Pipes are filled with a supportive substance to get a Avoid collapse of their cross-sections. With traditional methods, the pipes are either covered with sand or filled with low-melting alloys. These However, aids have the disadvantage that they can only be removed inadequately after bending. Apart from this, In the process with alloys, the melting process must not only be used when filling but also when removing

be performed.
15th

In the method according to the invention, however, is the Use of external energy only necessary once, namely when the cooling brine is pumped into the inner pipes while the re-thawing of the ice at room temperature takes place easily. In addition, the aid is water and the cooling brine can be easily and completely removed from the pipes. The system can preferably do this afterwards be rinsed with a drainage fluid.

It has also been found that the ice simultaneously is used to hold or spacer and to support the inner tubes, so that the inner tubes not additionally filled with a proppant

have to.
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In order to ensure an exact distance between the inner tubes with one another and with the jacket tube, it is advantageous if the inner pipes are fitted with spacers, such as spring washers, before being inserted into the casing pipe.

be cut.

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An embodiment of the invention is shown schematically in the drawing shown. Show it:

Fig. 1 shows the embodiment in side view

and

Fig. 2 in plan view.

TO The coaxial heat exchanger shown in side view in FIG. 1 consists of a helically bent heat exchanger tube 10, which is formed from a jacket tube 11 and 7 arranged therein inner tubes 12. Within of the jacket tube 11, the inner tubes 12 with spacing

^ hold 13 at certain distances from each other and from the *! a ntel pipe wall held so that the inner pipes 12 evenly be washed around by the medium flowing in the jacket tube, so that an optimal heat transfer between the Medium inside the inner tubes 12 and outside the same

^ O is assured. The inside of the heat exchanger tube 10 forcibly guided heat-exchanging media can be used in Flow co-current or in the more favorable counter-current.

As shown in more detail in Fig. 2, the ends of the heat exchanger tube 10 each provided with a T-connector 14. The inner tubes 12 are provided with an end piece 15 of the T-piece welded. This is followed by a channel system (not shown) for that through the inner tubes 12 flowing working medium.

3.

A side connection is provided for the second working medium flowing in the jacket tube 11 outside the inner tubes 16 provided on the T-connector.

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The manufacture of such heat exchangers only includes few very simple process steps. The first straight pipes 11 and 12 are cut to length accordingly. The inner tubes 12 are at intervals with the Provided spacers 13 and pushed into the jacket tube. Then the T-connectors 14 are welded on accordingly and the pipe system formed in this way Filled via the connection 16 with water or another liquid.

In order to freeze the liquid located in the jacket tube 11, a cooling medium is passed through the inner tubes 12 pumped in. Because of the material used, steel, in particular mild steel, the heat exchanger tube 10 not affected by the thermal expansion of the water during freezing.

The tube, which is then filled with ice as an aid, is then wound or bent accordingly on a mandrel. In order to achieve the smallest possible size, are the individual turns pressed close together. As a result, at the same time, to a certain extent, the external surface in contact with the atmosphere is reduced of the heat exchanger. It turned out that at In this process, after freezing the bending tools, the pipe only expands elastically to a minimal extent. It is therefore possible to manufacture the end product precisely and reproducibly for series production with tight tolerances.

After the bending process, the ice melts automatically due to the room temperature, so that this aid and the coolant pumped into the inner tubes directly

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-ιοί can be let out again. If necessary, the pipes 11 and 12 are rinsed with a further medium

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Claims (1)

i fet prerequisite 15 ι Coaxial heat exchanger for heat pumps, consisting of from a jacket tube in which at least one inner tube is arranged, characterized in that the jacket tube (11) has a small diameter in relation to the length and with the inner tube (12) Spiral, or helical, or meandering is bent, and that the jacket and inner tubes are made of steel. 2. Heat exchanger according to claim 1, characterized in that that a carbon steel is used as the steel. 3. Heat exchanger according to claim 1, characterized in that that chromium-nickel steel is used as steel. U - "-C -, U ^, U _D » _P 4. _O 1 1, JJ JVmQ + Claim 1, thereby gaVanmni rhn ^ i ! i ||| M f \ ~ ι || dem 7iigammpn <: Pi-7Pp him ιι | ιι) ι | η jl ι η inner tubes (12) with 7.1995