DE2732879A1 - HEAT EXCHANGER - Google Patents

Description

2732H7B

8836

Heat exchanger 709884/1034

Heat exchanger

The invention relates to heat exchangers and is more particularly concerned with a heat exchanger that includes a plurality of thermal lift tubes which contain a heat exchange fluid to extract heat from a hot fluid such as steam.

In power plants, the steam discharged from a steam turbine is typically used in a once-through condenser supplied, in which feed water is passed through the steam for heat exchange in order to condense the steam. Because of the considerable water consumption and the resulting thermal pollution. or disadvantages are these Types of condensation devices are becoming less and less popular.

As a result, various types of dry heat exchangers have been found proposed to use the air, which is under pressure in its basic form, to condense the steam. These however, dry condensation devices are significant more expensive than the water condensing devices described above because the fan consumes power, and there the heat exchanger is part of the condensation device. They also have dry condensing devices a smaller cooling volume than water condensing devices.

A third form of heat exchanger that is possible in the aforementioned environment is the so-called heat pipe heat exchanger, which has a plurality of horizontally extending tubes closed at their ends and those at their inner surfaces have a wick material. The heat exchange fluid is located in the pipes and it is generated by the heat of the steam, which is passed through part of the tubes, evaporates, and it becomes air or a similar medium over

709884/1034

the other parts of the tubes to condense the heat exchange fluid. However, this type of arrangement is not suitable for large arrangements, since the wick material is expensive and the tubes are difficult and costly are to be made and since the pipes are limited to use in a horizontal position.

The invention is based on the object of creating a heat exchanger which is air-cooled and which is relatively can be manufactured at low cost.

This object is achieved by the characterizing features of claims 1, 8 and 11.

It is essential for the solutions according to the invention that each heat exchanger has several thermal lifting tubes, the upper part protrudes into an upper heat exchanger section and its lower part protrudes into a lower heat exchanger section.

Each tube is closed at its ends and contains a heat exchange fluid that when a hot fluid is passed through it through the lower heat exchange section the heat is transferred from the hot fluid to the heat exchange fluid. A cool fluid is passed through the upper heat exchange section to add the heat to the heat exchange fluid remove.

According to the invention, an advantageous heat exchanger is to be created in which the need for a high fan output is kept to a minimum and in which no heat pipes are required which require a wick material on their inner surface. According to the invention, a heat exchanger of the type mentioned above is provided that includes a plurality of gravity-controlled, thermal siphon tubes that are constructed and arranged uniformly.

708884/1034

The heat exchanger according to the invention can be characterized by that it separates an upper heat exchange section, a lower heat exchange section, and a plurality of thermal lift tubes each of which has an upper part protruding into the upper heat exchange section, each of the Tubes is closed at its ends and contains a heat exchange fluid that means are provided to passing a hot fluid along the lower portions of the tubes to transfer heat from the hot fluid to the heat exchange fluid to be transmitted, and that there is means for passing a cool fluid along the upper parts of the tubes, to remove the heat from the heat exchange fluid.

Embodiments of the invention are described below with reference to the drawings. Show:

Fig. 1 is a schematic view of part of a power plant, which the heat exchanger according to the invention used,

Fig. 2 is an enlarged vertical section showing one embodiment of the heat exchanger according to the invention

3 is an enlarged partial view of part of the condensing section according to Fig. 2,

4 is an enlarged perspective view of another Embodiment of the heat exchanger according to the Invention and

Fig. 5

and 6 sections along lines 5-5 and 6-6 in FIG

709884/1034

- ίο -

By way of example, the heat exchanger is described together with a power plant in which the heat exchanger is used for this purpose is to condense the steam emitted by a turbine. In Fig. 1 is a steam turbine with the reference number 10 and it has an inlet conduit 12 for steam from an external generator into the turbine introduce, and further two outlet ducts 15 and 16 to the discharged steam after it has passed through the turbine has passed through. The turbine works in a known manner around an electrical generator 18 for generation of electrical energy in a known manner.

Four condensation or liquefaction sections 20, 22, 24 and 26 surround turbine 10 with condensing sections 20 and 22 on one side of the turbine and the condensing sections 24 and 26 are on their other side. The condensation sections 20 and receive the vapor discharged from the outlet line 14 and the condensing sections 24 and 26 take that from the Outlet line 16 emitted steam.

One embodiment of a condensation section 22 is shown in detail in Figures 2 and 3, and of course the remaining condensation sections 20, 24 and 26 be constructed accordingly. In particular, the condensation section 22 has a housing 30, which is shown in FIG an upper part 32 and a lower part 34 is divided by a horizontally extending partition 36. It is an inlet port 38 provided at one end of the lower housing portion 34 for receiving steam from the steam line 14, which is treated in the manner described below.

709884/1034

A plurality of vertical partition walls 40 are provided at intervals from one another in the upper housing part 32, the End partitions 40 form the walls of the housing. There are also several perforated vertical partitions 42 in the top Housing part 32 is provided, which are arranged next to the partition walls 40. Each partition 42 divides the space between the adjacent partition 40 into an air passage 44 and a heat exchange chamber 46.

If a plurality of thermal lifting tubes 50 are provided in the housing 30, with the upper part of each tube extending into the Chamber 46 extends, and wherein the lower part of the tube protrudes into the lower housing part 34. The tubes 50 are in of each heat exchange chamber 46 is arranged in three parallel rows, the end pipes of each row being shown. Of course, the number of tubes 50 in each row can be varied according to the particular construction. A plurality of heat exchange fins 51 protrude from the upper parts of the tubes 50 into the heat exchange chamber 46 and the lower part each of the tubes 50 extends at an angle with respect to the upper part for a reason as follows is explained. Each tube is closed at its ends and contains a heat exchange fluid such as ammonia, that in the part of the tube that goes into the lower housing part protrudes, has evaporated and which is condensed in the part of the tube which protrudes into the heat exchange chamber 46, so as it is described in detail below.

A fan 52 is provided at the top of each air passage, and it acts to bring ambient air into the Passage 44 leads into it, specifically in the downward direction, as can be seen from FIGS. 2 and 3. A guide wall 54 is provided in each air passage 44 to direct some of the air into the lower part of the passage. the Air then passes through the holes in the partitions 42 in a general right to left direction

709884/1034

and flows in the heat exchange chambers 46 via the upper ones Parts of the tubes 50. A plurality of exhaust air tubes 56 protrude through the upper wall of the housing 30 and take in the air afterwards it has passed through the heat exchange chambers 46 and it is then via a wind direction outlet 58 which is attached to the upper end of each outlet tube 56 is.

As can be seen from FIG. 2, there is another air outlet pipe 60 is connected to two heat exchange chambers 46 and it works so that there is some of the air coming from the last called heat exchange chambers is discharged into a collecting channel 62. The collecting channel 62 is used to the relatively warm air in turn to the boiler (not shown) connected to the steam turbine 10 to feed the boiler with combustion air. As can be seen from Fig. 3, the passage of air through the outlet pipes 56 and 60, which with the two the latter heat exchange chambers 46 are connected, optionally with the help of manually operated damping valves 64, provided in each pipe are controlled according to the combustion air required by the boiler. Of course the number of heat exchange chambers 46, which have an additional air discharge pipe 60, can be correspondingly change the needs.

Referring to Fig. 1, two steam condensate lines 70 and 72 connect the outlet end of the lower housing portions 34 of the condensation sections 22 or 24 with a pump 78; and steam condensate lines 74 and 76 connect the lower housing parts the condensation sections 20 and 26, respectively, with a pump 80. The pumps 78 and 80 act to condense the Withdraw steam from condensing sections 20, 22, 24 and 26 and transfer it to a sump (not shown) or a similar device for further treatment.

709884/1034

In operation, the steam is released from the turbine 10 via the exhaust lines 14 and 16 the condensation sections 20, 22, 24 and 26 supplied, into which it flows and in which it passes through the lower housing part of this section and around the lower parts of the tubes 50 flows. The steam heat is on transfer the heat exchange fluid in the tubes 50, whereupon the vapor condenses and the heat exchange fluid evaporates and migrates into the upper part of the tubes 50, the are located in the heat exchange chambers 46. The fans 52 force relatively cool ambient air into the air passages 44 through the perforated partition walls 42 and conduct them over the upper parts of the tubes 50 to remove the heat to transfer the heat exchange fluid in the tubes to the air before the air via the outlet tubes 56 and at a Part of the heat exchange chambers 46 discharged through the outlet pipes 60 will. As the air flows past the top of the tubes 50, the heat exchange fluid condenses in the tubes and drips due to gravity to the lower parts of the tubes in the lower housing part 34 to prevent the transmission of heat to continue in the manner described above.

As can be seen from FIG. 1, the condensed vapor is released from the condensing sections 20, 22, 24 and 26 Sucked off via the lines 70, 72, 74 and 76 with the aid of the pumps 78 and 80 and it then becomes collecting containers on these or similar facilities for further treatment.

Another embodiment of the condensation section is provided with the reference number 88 in FIGS and it includes a conduit 90 which is used to receive the vapor from lines 14 or 16 and to discharge the condensed Steam to the lines 70 and 72 is used, in a manner similar to that in the lower housing part 34 of the above

709884/1034

described embodiment is provided. There are several Heat exchange tubes 92 are provided, each of which has a lower portion 92a protruding into the channel 90, and an upper portion 92b protruding outwardly from the upper wall of the channel. The upper parts 92b of the heat exchange tubes extend at an angle to the lower parts 92a and are laterally displaced with respect to the channel 90. The heat exchange tubes 92 are divided into two groups, 94 and 96, with the heat exchange tubes following one group one side of the channel 90 protrude, and the heat exchange tubes of the other group to the other side of the heat exchange channel protrude. Each group 94 and 96 contains four rows of heat exchange tubes 92, each row being extends the full length of the channel 90. In this way, the heat exchange tubes 92 form a substantially Y-shaped Assumption in a view from the end of the channel 90, the web of the Y protruding into the channel 90.

A plurality of fins 98 are provided on the upper part 92b of the heat pipes, but these are for the sake of simplicity only some are shown. Each heat pipe 92 is closed at its ends and contains a heat exchange fluid and operates in the same way as the heat pipes or tubes 50 of the previously described embodiment.

A support plate 100 is connected to and protrudes over the upper ends of the heat pipes 92 and supports an induction draft fan 102 and a hood 104 disposed around the fan and open at its upper end is. An opening (not shown) is provided in the mounting plate 100 so that air can flow through the induction fan 102 is drawn past the upper parts 92b of the heat pipes and through the hood 104 for discharge into the ambient air can be performed, as shown by the flow arrows.

709884/1034

- 15 - 273287H

In operation, the fan 102 operates to blow air on the tops 92b of the heat pipes of both groups 94 and 96 the heat pipes by suction and conveyed through the hood 104, whereby the heat exchange fluid at the upper ends 92b of the Heat pipe is cooled. The heat exchange fluid condenses and drips down into the lower portions 92b of FIG Heat pipes, which are located in the channel 90, and it is because of the heat exchange with the steam passing through them Channel passes through, evaporates.

The lower parts 92a of the heat pipes can be used in the same manner as the lower parts of the heat pipes 50 described previously Embodiment be inclined.

Various advantages result from the arrangement according to the invention. For example, it is not necessary to have a Provide wick or something similar in the heat pipes of the two arrangements, as these pipes are considered by gravity controlled, thermal lifting tubes work, i.e. that the condensed heat exchange fluid in the tubes under gravity drips from their upper part into their lower part. Furthermore, the heat exchanger according to the invention can be used together with known steam turbines, which have a low back pressure and low heating speeds exhibit.

In the embodiment according to Figures 2 and 3, the inclined lower parts of the heat pipes allow enlargement its length without the need to increase the structure of the vapor passage and it is also thereby the resistance to the flow of heat is reduced. Furthermore, by the in the embodiment according to the Figures 2 and 3 methods used, namely at least some of the heated air given off by the boiler will,? u use, to increase the efficiency of the whole system.

709884/1034

In the embodiment according to FIGS k to 6 is kept minimal by the Y-shape of the heat pipes, the air deflection and thus a change of speed and it is thus largely reduces a circulating hot air through the arrangement as compared with other by an air stream of a Fan cooled units. In the embodiment according to FIGS. 4 to 6, the packing density of the heat pipes is also relatively high, which leads to a relatively large air-cooled surface per unit length, which in turn means that the space requirement of the heat exchanger is low. The embodiment according to FIGS. 4 to 6 also enables a very economical fan size to be selected by changing the number of heat pipes and the angles at which the upper parts of the heat pipes are in relation to the lower parts of the heat pipes.

The present invention is not limited to use in an arrangement for condensing steam, but rather can be used in all cases where heat exchange between two fluids is desired.

709884/1034

Blank page

Claims (15)

. Heat exchanger, characterized by a plurality of heat exchange sections (20, 22, 24, 26), separating devices (36) for dividing each heat exchange section into an upper part (32) and a lower part Part (34), further separating devices (40) for dividing the upper part of each heat exchange section into several horizontally aligned chambers, several thermal lifting tubes (50) each of which has an upper one Has part that protrudes into one of the chambers, and a lower part that extends into the lower part (34) of the heat exchange: h from sections s (20, 22, 24, 26) protrudes, each Tube (50) is closed at its ends and contains a heat exchange fluid, means (14) through which the lower parts (34) of the heat exchange sections (20, 22, 24, 26) with a source of a relative hot fluids are connected so that the hot fluid flows along the lower parts of the tubes (50) to To transfer heat from the hot fluid to the heat exchange fluid and with means associated with each Chamber connected to convey a relatively cool fluid along the upper parts of the tubes (50), to extract heat from the heat exchange fluid. 2. Heat exchanger according to claim 1, characterized in that the upper parts of the tubes (50) in a substantially extend vertical direction, and that the lower parts of the tubes (50) opposite their corresponding vertical Parts run at an angle. 709884/1034 2 7 3 2 8 7 ^C J - ir - 3. Heat exchanger according to claim 2,
characterized in that the heat exchange fluid evaporates in the lower parts of the tubes (50) and condenses in the upper parts of the tubes (50), and that the condensed fluid drips due to gravity from the upper parts of the tubes to the lower parts of the tubes. 4. Heat exchanger according to claim 1,
characterized in that the relatively cool fluid is air and that the guide device has fans (52), one of which is assigned to one of the chambers _{7 in} order to guide ambient air through the chambers. 5. Heat exchanger according to claim 4,
characterized in that each of the chambers has an outlet (56) for exhausting the air to the ambient air after it has been passed along the tops of the tubes (50). 6. Heat exchanger according to claim 4,
characterized in that at least some of the chambers have an additional outlet (60) for directing the air to a manifold (62) for further treatment after it has been passed over the tops of the tubes (50). 7. Heat exchanger according to claim 6,
characterized in that means (64) are associated with each chamber for selectively directing air through the outlets. 709884/1034 3> 8. Heat exchanger
characterized by a housing (30), separating means (36) for dividing the housing into an upper part and a lower part, a plurality of thermal lifting tubes (50), the upper part of which protrudes substantially vertically into the upper part of the housing and the lower part of which extends into the lower part of the housing protrudes, the lower part of each of the tubes (50) extending at an angle with respect to the corresponding upper part, each of the tubes (50) being closed at its ends and containing a heat exchange fluid, a means around a relatively hot one fluid along out through the lower part of the housing (30) and on the lower parts of the tubes (50), _f in order to transfer heat from the hot fluid to the heat exchange fluid and means to the relatively cool fluid through the upper part of the housing (30) and along the upper parts of the tubes (50) and remove heat from the heat exchange fluid. 9. Heat exchanger according to claim 8,
characterized in that the lower part of the tubes (50) extends at an obtuse angle to the vertically extending parts of these tubes. 10. Heat exchanger according to claim 8, characterized in that the heat exchange fluid in the lower parts of the Tubes (50) evaporated and condensed in the upper parts of the tubes (50), and that the condensed fluid moved from the upper parts of the tubes to the lower parts of the tubes under the influence of gravity. 709884/1034 11. heat exchanger,
characterized by a channel (9O) ₇ connectable to a source of relatively hot fluid, a plurality of thermal lift tubes (92) each having a lower portion (92a) protruding into the channel in the flow of the relatively hot fluid, and an upper part (92b) protruding out of the channel and at an angle to the lower part (92a), the tubes (92) being arranged in at least two spaced parallel rows, the upper parts (92b) one row protruding in the direction of one side wall of the channel (90) and the upper parts (92b) of the other row in the direction of the other side wall of the channel (90) and the tubes being closed at their ends and containing a heat exchange fluid that Receives heat from the relatively hot fluid into the conduit (90), and by means for passing a relatively cool fluid along the upper portions (92b) of the tubes to remove heat from the heat exchange fluid to dissipate. 12. Heat exchanger according to claim 11,
characterized in that the channel (90) is horizontal and the tubes (92) are substantially Y-shaped when viewed from the end of the channel. 13. Heat exchanger according to claim 11,
characterized in that the heat exchange fluid vaporizes in the lower parts (92a) of the tubes (92) and condenses in the upper parts (92b) of the tubes (92) and that the condensed fluid separates under the influence of gravity from the upper parts of the tubes moved to the lower parts of the tubes (92). 709884/1034 2732870 14. Heat exchanger according to claim 11,
characterized in that the relatively cold fluid is air and that the guide device comprises a support plate (100) connected to the upper ends of the tubes (92) and a fan (102) attached to the plate for guiding ambient air is arranged along the upper parts of the tubes. 15. Heat exchanger according to claim 14,
characterized in that the fan (102) is an induction draft fan. 709884/1034