DE3706408C1 - Heat transfer tube - Google Patents

Abstract

The subject of the invention is a heat transfer tube having an outer tube (6) and an inner tube (7) running coaxially with respect to the latter, a knurled or ribbed surface structure on the outside of the inner tube (7) or on the inside of the outer tube (6) determining a defined gap (5) between the two touching tubes. To make the design more simple and to improve the heat transfer, it is proposed that the gap (5) be designed as an open capillary gap, the equivalent gap width of which, converted to a circular, smooth gap of the same average diameter, lies in the range from 30 to 150 mu m and that the gap (5) be filled with a liquid heat transfer medium of which the boiling point is higher than the maximum operating temperature. <IMAGE>

Description

The invention relates to a heat transfer tube an outer tube and an inner tube running coaxially with it, with a knurled or ribbed surface structure on the Outside of the inner tube or the inside of the outer tube a defined gap between the two touching Pipes determined.

From DE-OS 21 15 271 is a heat transfer pipe with a leak known display consisting of two concentric tubes, between which the leaking medium may penetrate. The Inner tube is on its outside with a variety of pyramid-shaped or truncated pyramid-shaped elevations, which have a defined distance between the tubes, a good one Heat transport and at the same time ensure a safe leak detection should perform. In this known heat transfer tube the gap between the two tubes in normal operation with air filled. This slows down the heat transfer. Furthermore becomes the well-known heat transfer tube in a closed system operated, d. H. the gap between the two pipes is after closed on the outside by special fittings with which a Pressure gauge for leak detection can be connected.

DE-OS 31 28 497 is a heat exchanger with a heat Transmission tube known, which also consists of an outer tube and a coaxial inner tube, wherein between the two non-touching pipes defined gap is provided to improve the Heat transfer with a liquid, powder or granulate shaped heat transfer medium can be filled. This known heat transfer tube can also only in closed system operated, so that proportionately elaborate connection fittings are required.

Proceeding from this, the object of the invention basic, a simply constructed heat transfer tube of the type described above to create improved heat transfer, which in the open System can be operated.

The solution according to the invention is a heat transfer Pipe of the type described initially proposed, in which the gap between the two tubes as an open capillary gap is formed, the one on an annular, smooth Equivalent equivalent gap of the same average diameter Gap width in the range from 30 to 150 µm (0.03 to 0.15 mm) lies, and in which the gap also with a liquid Heat transfer medium is filled, its boiling temperature is higher than the maximum operating temperature.

In a practical embodiment, the equivalent Gap width is preferably 80 microns (0.08 mm). These preferred gap width can be with a heat transfer tube an inner tube knurled on its outside be achieved that the truncated pyramid height about 0.6 mm, the Angle to the tube axis approx. 30 ° and the knurling division approx. 1.6 to 2.0 mm.

The heat transfer medium can be in a practical way be a cooling brine, the boiling temperature of which Factor 1.2 to 2 higher than the maximum operating temperature of the Heat transfer tube is. Has proven to be particularly suitable a cooling brine based on 1,2-propylene glycol with a Addition of corrosion inhibitors.

The heat transfer constructed according to this technical teaching suspension tube has the advantages of an improved Heat transfer and a significantly reduced  Construction effort compared to the known heat transmission tubes because it has the advantages of the one hand DE-OS 21 15 271 known heat transfer tube with itself touching tubes and that known from DE-OS 31 28 497 Heat transfer tube with non-touching tubes, however with a gap filled with a heat transfer medium connects and on the other hand also the operation in allowed a very simply constructed open system. So that the heat transfer medium does not come from through the upper surface structure on the outside of the inner tube or Emerge from the inside of the outer tube defined gap, can evaporate or dry out, this must according to the invention be formed as a capillary gap, the heat transfer medium due to its capillary action and in connection with a correspondingly set kinematic viscosity holds liquid heat transfer medium. With one after this technical teaching constructed heat transfer tube the heat transfer medium is only then from the defined Escape gap if there is a leak somewhere through which an operating medium, for example water or a refrigerant enters the defined gap and the heat transfer medium drives out. In this case, the expulsion of the Heat transfer medium evaluated for a leak indicator will. Special connection or connection fittings between the outer and inner tubes are not required.

In the after following description is based on the drawings a preferred embodiment of an invention trained heat transfer tube using the example of a ribs tube condenser for use in a hot water Storage of refrigeration systems and hot water heat pumps Warming of drinking water shown and explained. In the Shows drawings  

Figure 1 shows a finned tube condenser in side view.

Figure 2 seen the same finned tube condenser from the inlet and outlet side.

Figure 3 shows a portion of a heat transfer tube with an outer tube formed as a finned tube and an inner tube knurled on the outside.

Figure 4 shows a portion of a heat transfer tube with a smooth outer tube and an inner tube knurled on its outside.

Figure 5 shows a portion of a heat transfer tube with a smooth outer tube and an inner tube grooved on its outside.

Figure 6 shows a portion of a heat transfer tube with an outer tube grooved on its inside and a smooth inner tube.

Fig. 7 shows the diagram of an experimental evaluation.

A finned tube condenser 1 shown in FIGS . 1 and 2 has an inlet 2 and an outlet 3 for the refrigerant. At the inlet 2 , a connection fitting 4 is arranged, which at the same time also seals a gap 5 between an outer tube 6 and an inner tube 7 of a double-tube heat transfer tube 8 . At the outlet 3 the inner pipe 7 protrudes with a smooth pipe end and a connection fitting 9 of the outer tube 6 out. The gap 5 is open at this outlet end of the heat transfer tube 8 . The exit of a heat transfer medium filling the gap 5 can be evaluated by means of sensors and a display device 11 arranged in an electrical circuit 10 as a leak indicator.

The heat transfer tube 8 may have the configurations shown in FIGS. 3 to 6.

In the embodiment shown in FIG. 3, the outer tube 6 is provided on its outside with spirally extending ribs 12 and is smooth on its inside. The arranged in the outer tube 6 the inner tube 7 is provided on its outer side with a knurling 13, the pyramids truncated height about 0.6 mm, angle of approximately mm contributes to the pipe axis approximately 30 ° and knurl 1.6 to 2.0. The shift-resistant bond between the outer and inner tube is produced by plastic deformation of one of the two tubes, preferably by ribbing the outer tube against an inner mandrel in the inner tube. The pyramids of the knurling of the inner tube are pressed onto the inner surface of the outer tube and increase the gap surface by a factor of 1 (smooth tube) to approx. 2. The equivalent gap width should be converted to a circular, smooth gap of the same average diameter in the range from 30 to 150 µm, preferably 80 µm (0.08 mm).

In the embodiment shown in FIG. 4, the outer tube 6 is smooth on its outside and inside, while the inner tube 7 is again provided with a knurling 13 . In this embodiment, the non-sliding bond between the outer and inner tubes by plastic deformation of the outer tube z. B. can be achieved by pulling together through a drawing die. Otherwise, the gap geometry corresponds to the embodiment described above in accordance with FIG. 3.

In the embodiment shown in FIG. 5, the outer tube 6 is smooth on its outside and inside. The inner tube 7 is provided on its outside with grooves 14 which run in a spiral. The groove width and depth is to be calculated in such a way that the gap geometry also corresponds to the gap geometry described above for the configuration according to FIG. 3 in this embodiment.

In the embodiment of the heat transfer tube 8 shown in FIG. 6, the outer tube 6 is smooth on the outside and provided on its inside with grooves 15 which can run straight or also spirally, while the inner tube 7 is smooth on both sides. In this embodiment, the gap geometry must be designed as it has been described for the design from FIG. 3 above.

A cooling brine based on 1,2-propylene glycol with the addition of corrosion inhibitors is used as the heat transfer medium. The boiling temperature at 1 bar is approx. 180 ° C and is therefore above the maximum operating temperature for district heating of approx. 140 ° C and the maximum operating temperature for refrigerant condensation of approx. 90 ° C. The thermal conductivity is greater than 0.20 W / m ° K at 20 ° C. With regard to the capillary forces in the capillary gap, it should be said that the kinematic viscosity at 20 ° C is less than 100 mm ² / s and the surface tension at 20 ° C is less than 60 mN / m. The physical properties of this heat transfer medium are optimally matched to the gap geometry described above. For introducing the heat transfer medium into the gap 5 , the heat transfer tube 8 is closed on one side after its assembly and completion with the connection fittings 4, 9 to a vacuum system, the gap 5 is evacuated and then filled with the heat transfer medium.

The power diagram shown in FIG. 7 shows the superiority of the heat transfer tube designed according to the invention in comparison with the prior art. To carry out the test, heated heating water was pumped in a circuit through the inner tube 7 of a heat transfer tube 8 used in a storage tank for hot process water. The heating water flow rate was determined with a flow meter. The process water was introduced into the storage unit via a flow meter, where it heats up on the outer tube 6 of the heat transfer tube 8 . For the evaluation, thermocouples for the heating water inlet, heating water outlet, hot water inlet and hot water outlet temperatures were installed in the memory. In addition, thermocouples for determining the storage temperature were installed in the storage water for process water. The heat transfer coefficients for the following three heat transfer pipes were measured as a function of the water speed:

Curve 1 finned tube without inner tube and with smooth inner wall;
Curve 2 smooth outer tube with inserted and knurled inner tube according to DE-OS 21 15 271;
Curve 3 according to the invention formed heat transfer tube 8 in the embodiment according to Fig. 3 with a finned tube as the outer tube 6 and an inner side on the outer knurled pipe 7.

From the experimental diagram it can be seen that the heat transfer performance of a heat transfer tube designed according to the invention with a finned tube as the outer tube 6 and a knurled inner tube 7 on the outside is considerably higher than the power of the heat transfer tube known from DE-OS 21 15 271 and is quite tight is due to the optimal performance of a simple finned tube.

• REFERENCE SIGNS LIST 1 finned tube condenser
  2 entry
  3 exit
  4 connection fitting
  5 gap
  6 outer tube
  7 inner tube
  8 heat transfer tube
  9 connection fitting
  10 circuit
  11 display device
  12 rib
  13 knurling
  14 groove
  15 groove

Claims (5)

1. Heat transfer tube with an outer tube ( 6 ) and a coaxial inner tube ( 7 ), a knurled or ribbed surface structure on the outer side of the inner tube ( 7 ) or the inside of the outer tube ( 6 ) a defined gap ( 5 ) between the determined both pipes in contact, characterized,
that the gap is designed as an open capillary gap, whose equivalent gap width, converted to a circular, smooth gap of the same average diameter, is in the range from 30 to 150 μm and
that the gap ( 5 ) is filled with a liquid heat transfer medium whose boiling temperature is higher than the maximum operating temperature. 2. Heat transfer tube according to claim 1, characterized records that the equivalent gap width is preferably 80 microns is. 3. Heat transfer tube according to claim 1 or 2 with a knurled on its outside inner tube ( 7 ), characterized in that the truncated pyramid height about 0.6 mm, the angle to the tube axis about 30 ° and the knurled division about 1.6 to 2.0 mm. 4. Heat transfer tube according to one of claims 1 to 3, characterized in that the heat transfer medium Is cooling brine, whose boiling temperature by a factor of 1.2 to 2 is higher than the maximum operating temperature. 5. Heat transfer tube according to claim 4, characterized net that the heat transfer medium is a cooling brine on the Base of 1,2-propylene glycol with the addition of Is corrosion inhibitors.