DE19729725A1 - Heat-exchanger between flowing media - Google Patents

Abstract

The exchanger has a tubular body (1) containing a guide for the first medium and an inlet and outlet (8,5) for the latter. A casing (6) enclosing the body forms a chamber (7) with inlet and outlet (11,10) for the second medium. The body has an opening which can be sealed off, and through which the guide can be extracted. The guide consists of an oblong metal or plastic strip twisted round its lengthwise axis. It contains cuts (12) at regular intervals and which form segments (13) bearing against the inside surface of the tubular body. Thus on extracting the guide through the opening deposits are scraped off the body wall and transported outside through the opening. The cuts in the guide (15) can be at irregular intervals and of different depths and widths, also at different angles to the guide outside edge. They can be used to form turbulence-inducing segments of different sizes.

Description

The invention relates to a device for exchanging heat.

DE 43 25 193 Fig. 1 by the same inventor shows a heat exchanger which consists on the inside of a twisted guide device for the first medium and on the outside of a jacket tube for the second medium. However, the mentioned guiding device (helix) can only be produced with great effort and the possible number of helical revolutions (number of twists) is limited. The effect of heat transfer can be greatly reduced because the length of the screw path (transmission length) is limited. The mode of operation can be inadequate, particularly in the case of larger widths or diameters of the helix, since a very high expenditure of force is required when drilling and the number of drillings is therefore very low due to the production. The deformation of the guide device (helix) can be so great that it breaks out of the screw path and is therefore unusable. When using the guide device as an exhaust gas heat exchanger in engines, the sound-absorbing effect is also very low.

It is therefore the object of the invention to provide a device for exchanging heat between a first and a second flowable medium that it avoids the disadvantages of the known prior art. It should one achieve higher efficiency and have a sound absorbing effect.

The task is solved by a device with the features of Main claim.

The inventive guide device can be as in the prior art for example, from a standard flat steel by simply twisting produce. To now the efficiency of the guide device compared to the state of the Technique increase will be on the edges of the guide device before twisting Incisions made. These cuts reduce the effective width of the Guide device when twisting. This makes it essential when twisting less effort required and the helical revolutions (number of drill) increase. The increase in the drill number leads to an increase in the effective  Length of the screw path in the pipe. The dwell time of the first medium in the Heat exchanger increases and thus the heat can be more effectively at the inner tube and thus be delivered to the second medium.

Since the guide device (helix) is twisted in the area of the incisions in deformed individual segment-like bodies (so-called segments), a helical fanning out of the outer edge of the guide device in the area of Incisions.

The fanned out segments that lie against the inner tube prevent that a laminar flow forms on the helix. Because of the strong The medium can cause turbulence in the area of the segments Cool the inner tube particularly well and the heat can be transferred to the inner tube second medium in the outer jacket can be given off very well.

The incisions on the helix are normally arranged at an angle of 90 degrees, so that rectangular segments are created.

However, you do not bring the incisions on the helix at an angle of 90 degrees Outside edge of the guide device, but you vary the angle for example to 30 degrees or 45 degrees, this creates diamond-shaped or trapezoidal Segments. Due to the different geometric arrangement of the segments, the efficiency of the heat exchanger can be varied.

When using the guide device (segment coil) as an exhaust gas heat exchanger in the case of diesel engines, results from the turbulence that arises at the Segments have less soot build-up than with spirals without segments. This has a self-cleaning effect. The maintenance intervals can thus be extended.

When using the guide device as an exhaust gas heat exchanger for engines, results due to the turbulence on the segments, a sound-absorbing effect. Of the  Exhaust silencers, which are normally connected downstream, can possibly be be made smaller.

In order to easily deploy the guide device for maintenance and cleaning work can, at least one inspection opening is provided in the axial direction. The fact that the outer edges of the guide device with the segments on the Bearing inner surface of the tubular body, this inner surface is at Pulling out the guide device cleaned. Possibly adhering soot particles use as an exhaust gas heat exchanger are also stripped. To at Cleaning work to move the helix more easily is at the end of the day Spiral to provide a hole in which you can hang a tool (hook) and so can easily pull out the helix and reinsert it. By several times it pushes the helix back and forth, the inner tube of the Heat exchanger cleaned very well by the segments and thus the heat can fully transferred again when the heat exchanger continues to operate.

Further details of the invention emerge from the subclaims and the description of exemplary embodiments, which are based on the Drawings are explained in detail. It shows

Fig. 1 shows a longitudinal section through the device according to the invention and

Fig. 2 shows a cross section through the inventive device of FIG. 1.

The inner tube 1 is connected on one side to the inlet nozzle 5 and on the other side to the outlet nozzle 3 located on the side. The opening 8 is arranged in the axial direction of the inner tube 1 and has a closure 4 . The inner tube 1 is connected to the jacket tube 6 and has a common cavity 7 .

The casing tube 6 can, as shown in Fig. 2, optionally be made with a radial or a rectangular or square cross-section ( 6 or 9 ). However, the choice of cross-section has practically no influence on the mode of operation of the heat exchanger.

The casing tube 6 has a radial inlet connector 11 and a radial outlet connector 10 . The inlet and outlet ports 11 and 10 of the casing tube 6 are arranged such that an exhaust gas of an internal combustion engine passed through the inner tube 1 flows in the opposite direction to a liquid passed through the cavity 7 . Provided within the inner tube 1 is a helically turned steel band serving as a guide device 15 , the outer longitudinal edges of which abut the inner surface of the tube 1 . Incisions 12 are made at the edge of the steel strip transversely to the direction of flow of the exhaust gas. These cuts 12 divide the outer region of the steel strip into individual turbulence-generating segments 13 which remain connected to the steel strip.

If a hot exhaust gas from an internal combustion engine is now introduced into the pipe 1 through the inlet connection 5 , it is acted upon by the helix 15 with a helical swirl which brings it into contact with the pipe wall 1 again and again and thus ensures good heat transfer. In order to prevent a laminar flow from forming, the incisions 12 and the turbulence-generating segments 13 are provided, which ensure a constant swirling of the exhaust gas in the outer region of the coil 15 . The speed of the exhaust gas is increased very strongly in the region of the segments 13 and is very turbulent. This increases the heat transfer to the inner tube 1 and increases the efficiency of the heat exchanger. The heat given off by the exhaust gas goes into the wall of the tube 1 and is then dissipated via the flowing medium in the cavity 7 .

If there is soot or dirt deposits in the pipe 1 after a long period of use, the heat exchanger can be cleaned in a simple manner. For this purpose, the closure 4 is removed and the helix 15 can be pulled out through the opening 8 that is created. To make it easier, a hole 2 is provided, into which a corresponding tool can be hooked. When the helix 15 is pulled out, the segments 13, which lie closely against the inner wall of the tube 1 , scrape off the soot or dirt deposits and convey them through the axial opening 8 to the outside. By repeatedly pushing the coil 15 back and forth, practically any dirt is removed, so that the efficiency of a new heat exchanger is achieved again. Due to the mode of action of the turbulence-generating segments 13 and the high flow velocity of the exhaust gases in the region of the segments 13 , less or no dirt or soot settles on the inner tube 1 and the heat exchanger does not have to be cleaned as often.

If, after the manufacture of the helix 15, it is found that the efficiency of the heat exchanger is too low, the efficiency can be increased by twisting the helix 15 more strongly. The effective helical path of the exhaust gas through the heat exchanger becomes longer and the residence time of the exhaust gas at the segments 13 increases. If, after the manufacture of the helix 15, it is found that the efficiency of the heat exchanger is too high, the efficiency can be reduced by twisting the helix 15 to a lesser extent. The effective helical path through the heat exchanger is shorter and the residence time of the exhaust gas at the segments 13 is reduced. The aforementioned change (modulation) of the efficiency of the heat exchanger can be increased. For example, the incisions 12 between the segments 13 can be made deeper or less deep. As a result, the effective width of the helix 15 changes and the amount of force when twisting is less or greater. This in turn increases or decreases the number of drillings. A good empirical value in practice results from a total depth of the cuts 12 on both sides of approximately 40% based on the entire width of the helix 15 . Only 60% of the material has to be deformed when drilling.

The resulting turbulence on the segments 13 results in a sound-absorbing effect on the heat exchanger. A downstream silencer can be reduced under circumstances.

Claims (8)

1. Device for exchanging heat from a first flowable medium to a second flowable medium with a tubular body 1 , which has in its interior a guide device 15 for the first flowable medium and both an inlet 5 and an outlet 3 therefor and with one Sheath 6 , which forms a cavity 7 with the tubular body 1 and has both an inlet 11 and an outlet 10 for the second flowable medium, the tubular body 1 having a closable opening 8 through which the guide device 15 can be pulled out, and wherein the guide device 15 consists of an elongated metal or plastic band which is helically rotated about its longitudinal central axis and, with its regularly made incisions 12 and segments 13, rests against the inner surface of the tubular body 1 such that when the guide device 15 is pulled out through the closable opening 8 Filing stanchions of the inner wall of the tubular body 1 scraped through the segments 13 and conveyed out through the opening 8 . 2. Device according to claim 1, in which on the outer edge of the guide device 15 incisions 12 are made, which are made at irregular intervals. 3. Device according to claim 1, in which 15 incisions 12 are made on the outer edge of the guide device, which are made at different depths. 4. The device according to claim 1, in which 15 incisions 12 are made on the outer edge of the guide device, which are of different widths. 5. The device according to claim 1, wherein the incisions 12 are arranged at different intervals. 6. The device according to claim 1, wherein the incisions 12 are arranged at different angles to the outer edge of the guide device 15 . 7. The device according to claim 2, in which through the incisions 12 , turbulence-generating segments 13 are formed, which are of different sizes. 8. The device according to claim 2, in which 12 segments 13 are formed by the incisions arranged at different angles, which in turn are arranged at the corresponding different angles.