DE1631684U - EXPANSION COMPENSATION DEVICE FOR PRESSURE VESSELS WITH HIGH INTERNAL PRESSURE AND DIFFERENT HIGH TEMPERATURES OF THE VESSEL PARTS, IN PARTICULAR HEAT EXCHANGERS. - Google Patents

Description

"Expansion compensation for pressure vessels with high internal pressure and various high temperatures of the vessel parts, especially heat exchangers "The invention concerns the control of thermal expansion and the associated local Voltage on a pressure vessel, which z. B. from a cylindrical outer shell and consists of a tube bundle rolled or welded into the end face. The inside of the vessel is in a known manner from the compressed air to be heated flows through, while the tube bundle is heated inside by hot gases of low pressure will. If now the lower end of the vessel is held in the longitudinal direction the thermal expansion of the upper tube sheet at the end of the heating tube bundle must be opposite that of the cylindrical outer jacket, which remains fairly cold, through installation an elastic member to be balanced pressure-resistant. These known elastic Expansion elements have so far been within certain pressure and temperature limits proven quite well. But difficulties arise as soon as the temperatures occur and pressures exceed a certain level. On the one hand, the switched on Expansion elements must be thin-walled in order to reduce the exposure caused by the high temperatures to cope with large stretches and on the other hand they have to withstand the high pressures to have grown inside the vessel.

These difficulties are solved according to the invention in that the expansion element switched on at the point of greatest expansion differences, e.g. B. a bellows, through the shuttering of the high internal pressure in stages degrading Do not follow this with labyrinth-like sealing elements is exposed to high internal vascular pressure. To achieve the desired effect However, a certain leakage loss of the pressurized medium has to be accepted to take, which however has only a subordinate meaning. The is controlled Pressure reduction through small openings in the last labyrinth chamber or the end space connect with the outside atmosphere in the expansion element. Through them the flow of the Pressure medium determined by the labyrinth chambers. The throttling points between the individual chambers are formed by piston rings or sealing lamellas, their design is chosen as possible so that either the overpressure on the sealing element or the change in shape during operation, the tight fit of the sealing surfaces supports the loss of high quality leaks over a long period of operation compacted work equipment limited to a minimum.

With larger dimensions of the pressure vessels, e.g. B. in a heat exchanger with a diameter of several meters, however, can be used in the formation of the Expansion elements (bellows or the like) and the throttle stages (piston rings, labyrinths) constructive difficulties arise in further development of the invention be remedied that those used to control the relative thermal expansion Components on the one hand and the sealing device serving for pressure sealing on the other hand be arranged in one of the gas-carrying lines that have a smaller diameter have than the heat exchanger jacket. One summarizes the gases z. B. after leaving the tube bundle together in a conical hood, which is converted into a cylindrical piece of pipe is. This cylindrical pipe section has approximately the diameter of the gas outlet pipe on. Its diameter is therefore considerably smaller than the diameter of the heat exchanger jacket. If one provides this cylindrical pipe socket, which protrudes into the gas outlet pipe with a kind of piston ring seal, one has the advantage of an arrangement with relative small diameter that is easy to control. this applies to both for production as well as for assembly and for operation.

In the drawing are several exemplary embodiments of expansion compensation devices shown according to the invention, namely: Fig. 1 shows a heat exchanger in A schematic illustration of FIG. 2 shows the part of FIG. 1 surrounding it with a circle Expansion compensation device in section and on a larger scale Fig. 3 a Longitudinal section through a heat exchanger in which the expansion compensation is at one point arranged with a small diameter, Fig. 4 shows another form of the expansion and sealing device and FIG. 5 shows a section through the expansion and sealing device on the container bottom corresponding to the bordered point in FIG. 3.

The heat exchanger according to FIGS. 1 and 2 consists of the outer jacket 1 with the thermal insulation 2, a tube bundle 3, which is in the upper plate 4 and the Base plate 5 is rolled or welded in, the gas discharge hood 6, the expansion element 7 and the sealing element 8 with the piston rings 9. The hot gases enter 10 from below into the heat exchanger, flow through the individual tubes of the tube bundle 3 and leave the heat exchanger through the hood 6. The heat-absorbing underneath Pressurized medium, e.g. B. air, enters at 11 and 12 and washes around baffles 13 guided the tube bundle 3 in a number of pulls, the heat from one to the other flow medium passes through the pipe walls.

The heated pressure medium leaves the heat exchanger at 14.

Since the hot tube bundle 3 naturally expands much more than the relatively cold container wall 1, they are with the interposition of a Sealing element 8 by an elastic expansion element 7 in the form of a bellows connected with each other. The thin walls of the expansion element 7 and the shape of the folds the same allow a good balance of the various thermal expansions of Container wall 1 and tube bundle 3. To the expansion element 7 but the required Thinness To be able to give, the pressure of the medium to be heated must be kept as far away from him as possible will. This takes place through the sealing element 8 with its piston rings 9.

The piston rings form throttling points through which the pressure of the to be heated Medium is gradually degraded from the inside to the outside until it is in the expansion element 7 has reached the lowering required for its wall thickness. Forced and controlled is the pressure drop through openings 15, which the last labyrinth chamber with the Connect the outside atmosphere and the flow through the upstream throttle points dose.

Instead of the piston ring seal, any other labyrinth seal Find application. It is only essential for their design that through the stretching movement of the container parts against each other does not reduce the sealing effect, but rather is reinforced.

3 shows an expansion and sealing device for pressure vessels shown with larger dimensions. The general structure of the heat exchanger is the same as that of FIG. 1. A tube bundle 20 is between the plates 21 and 22 arranged and is located inside a pressure vessel from the jacket 23 and the insulation 24. Transverse walls 25 conduct the entering at 26 under pressure standing medium in different trains through the tube bundle 20. At 27 the heated print medium. The heating gases are fed to the tubes 20 at 28, flow through them, giving off heat to the pressure medium and passing through them the hood 29 and the tubular connecting piece 30 from. The expansion element 31 with the throttle rings 32, which allows an unimpeded longitudinal expansion of the tube bundle 20 with the plate 21 and the hood 29 opposite the container wall 23 is permitted laid here in the tubular connection piece 30, so in a component with substantially smaller dimensions than the vessel itself. As a result, the function of the to master individual components better. It is also shown here that the necessary passage of pressure medium through the throttle stages for the pressure reduction does not necessarily have to be a loss, but you can use the print medium as far as the Pressure is still above atmospheric pressure and dissipate any purpose of use make useful.

In Fig. 4, a bellows 33 is used for sealing, the here'in consequence of its smaller dimensions it can be designed so that it has both the necessary elongation as well as the internal pressure of the heat exchanger is.

5 is also shown. as well as the radial expansion compensation can be made between the tube bundle and the container wall according to a similar principle can. The lower plate 22 of the tube bundle 20 engages in an annular groove 34 from the wall flange 35 and the flange 36 is formed on the lower feed and rests on the lower surface with its heavy weight. The pressure seal takes place again through labyrinth seals with gradual pressure reduction to the outside. The penetrating Pressure medium is discharged through the bores 37. The bottom plate 22 can expand independently of the container wall 23 in the radial direction. Protection claims : 1. Expansion compensation of a pressure vessel with high internal pressure and different levels Temperatures of the vessel parts, characterized in that the in the vessel wall (1) activated expansion element (7) effective pressure through gradual relaxation is largely lowered in upstream labyrinth-like chambers.

Claims (1)

2. expansion compensation according to claim 1, characterized in that the last labyrinth chamber is connected to the outside atmosphere through small bores (15) is through which the flow of a small part of the pressurized in the vessel Medium is controlled, which is the pressure drop from the inside of the vessel to the expansion element causes. 3. expansion compensation according to claim 1, characterized in that the one behind the other connected labyrinth chambers by elastically deforming Sealing rings or piston rings (9) are separated from each other. 40 expansion compensation according to claim 1, characterized in that the sealing elements (9) between the individual labyrinth chambers are designed in this way are that they are due to the expansion in or due to the overpressure inside the vessel in their Effect are supported. 50 Expansion compensation of a pressure vessel with high internal pressure and different high temperatures of the vessel parts, especially for heat exchangers of large dimensions, characterized in that the control of the relative thermal expansion of the Components on the one hand and sealing device serving for pressure sealing on the other hand (31, 32) in one of the gas-carrying pipes (which has a smaller Have a diameter than the heat exchanger jacket (1, 23). 60 heat exchanger according to claim 5, characterized in that that at the same time several sealing devices in the supply and discharge lines of the heat exchanger arranged sin