DE962389C - Air heater for hot air turbines with closed circuit - Google Patents

Description

Air heater for hot air turbines with closed circuit In order to be able to achieve high economic efficiencies, especially low specific fuel consumption, for hot air systems, it is necessary that the temperature of the hot air at the entry into the hot air turbines is around 69o ° C. With a short length and good insulation of the pipeline between the air heater and hot air turbine systems, the temperature in the air heater parts at the outlet of the air heater is roughly 700 ° C. B. in the range of 30 to 50 kg / cm2, must be operated, it follows that the structural design of the individual components of the air heater and the materials used must be of particularly high quality. It is just as important that in the case of shipping operations and any damage to parts of the air heater, these can be repaired without spending too much time and, if possible, with on-board resources. A sufficient subdivision of the air heater into several independent elements must also be ensured, and it must be possible to shut down the individual elements for overhaul purposes without the operation with the remaining air heater elements having to be interrupted for a long time. Furthermore, the cleaning of the Asdhe air heater parts exposed to the raw gas draft or oil burn residues must be able to be carried out with simple means, especially since boiler heating oils with relatively high specific proportions of sulfur and incombustible components have to be used as fuel for these systems in order to compete with the steam turbines - and diesel engine systems. Furthermore, the natural relative thermal expansions of the parts of the air heater which are at different temperatures must be taken into account, so that no uncontrollable thermal stresses can additionally stress the parts of the air heater that are subject to high loads. Finally, the operation of the air heater must be simple and clear, so that the operating personnel can carry out the operation on board with the usual care.

Since there is also steam on board for technical and economic purposes If there is a need for strongly changing requirements, the steam generation should be organic with the air heater. as far as heating, combustion air preheating, flue gas extraction and Operation come into consideration, be connected.

According to the invention, the above conditions are met in that the air heater. is formed by several heater elements grouped around a central flue gas duct, which consist in a manner known per se of vertical pipe strings arranged concentrically around the burner and flame axis of each element with common annular collector chambers. The heater elements are expediently completely identical to one another and grouped in a star shape around the central flue gas duct, with at least one vertical steam generator element being built into the system as a further unit in such a way that the burners for the air heater elements and for the steam generator element share a common in the central flue gas duct arranged air preheater for the combustion air are supplied and the flue gases of all elements of the system flow through the common flue gas exhaust with air preheater to the chimney. The combination according to the invention of the elements to form a self-contained spatial shape with the smallest external dimensions enables a clear arrangement of the required heat exchange surfaces in restricted ship spaces with a good overview, ease of use and monitoring. According to a further object of the invention, the individual heater elements of the system are constructed from one or more concentrically arranged, in a known manner, double-ring tube walls formed in the main field: straight and vertical tubes, the outer surfaces of which are cylindrical or slightly conical. The ends of all tubes of a double-ring tube wall open partly at one end face into a double-chamber ring, the tube ends at the other end face 4n into a simple chamber ring, which ensures perfect circulation of the propellant to be heated through all the tubes. The inventive design of the pipe walls for guiding the heating gas flow in the individual heater elements from straight vertical pipes, each rolled separately for each pipe wall in upper and lower chamber rings, has the advantage over the known pipe walls made of S-shaped curved pipes that the pipe walls can easily be removed individually upwards, and on the other hand, if only the chamber rings are given sufficient heat mobility, gaps in the pipe walls through which the heating gases can escape from the prescribed path early on cannot arise when the element is in operation. The concentric inside -cum of the Rohrringwän.de then serves as a combustion chamber, and the gases are then passed through the annular spaces of the tight pipe walls to the exhaust gas collection space. The vertical arrangement of the tube walls results in a high vertical combustion chamber, which is acted upon by one or more burners on the lower horizontal end face. The propellant to be heated reaches the lower double chamber rings via collecting tube rings, and it is distributed evenly to the individual chamber rings via connecting tube bends. It flows from the lower double-chamber rings to the pipe walls. This arrangement ensures that all of the pipes of the heater elements are admitted to a good effect, thus limiting pipe ruptures and other damage in the flow pipe system to a considerable extent. The heated propellants flowing out of the inner double-chamber rings then reach the engine via manifold bends. It can be seen that the means proposed by the invention enable large radiant and contact heating surfaces to be accommodated in the smallest of spaces. Another advantage of the design of the heater elements according to the invention is the possibility of expanding the pipe walls upwards with a corresponding design of the casing. The connection of special steam generator elements in structural integration into the closed system results in not only a substantial gain in space but also heat-economical advantages, which must be seen above all in the favorable utilization of the exhaust gases together with the exhaust gases from the heater elements. Naturally, any number of elements can be arranged in a star shape around a central exhaust duct, with the exhaust gas space being correspondingly larger in size depending on the number of individual elements and thus also being suitable for accommodating larger secondary heating surfaces.

As an example, the drawing shows an air heater with a Steam generator is combined and meets the aforementioned requirements.

Fig.r shows in the cross-section of a ship how this combined Unit is housed in the ship. There are two such aggregates, each of same design and performance, installed. The one from the engine room corridor the end operable burners shine from bottom to top; the smoke gases draw off the top of the chimney in an organic manner.

Fig. 2 shows that each aggregate out of five are identical to one another Air heater elements i, 2, 3, 4, 5 and a special element 6 for steam generation consists. All elements i to 6 let the flue gases gradually and through a tubular air preheater for the combustion air 7 to be drawn off after the chimney 8.

Fig. 3 shows the structural design of a on the left Air heater element and on the right side that of the element for steam generation and in the middle that of the common air preheater.

In the exemplary embodiment, the five air heaters are for a normal working air performance of a total of 12 8oo ooo kcal / h at a maximum hot air temperature of 700 ° C and a working air outlet temperature from the heat exchanger of the hot air turbine system of 425 ° C, furthermore for an operating pressure of around 45 kg / cm2 built. The steam generator is built for a normal steam output of 600 kg / h wet steam and an operating pressure of 6.5 kg / cm2. Each element of the air heater consists of three lower double chamber rings 9, io, i i. Each of these chamber rings has a partition wall 12, 13, 14. The chamber rings are made of two U-shaped rings made of durable austenitic special steel, between which the partition wall is welded. The inlet of the working air entering the air heater at 425 ° C takes place for each of the five elements through three welded pipe bends 15 which are evenly distributed around the circumference of the chamber ring ii and which are connected to the pipe ring 16. The pipe ring 16 of each of the five air heater elements is connected by a pipe bend 17 to the collecting ring i8, which feeds all five air heater elements from the return line of the working air i9 from the heat exchanger of the hot air turbine system. By using the pipe rings and the pipe bends with a large radius of curvature, this pipe arrangement can be expanded in all directions. The chamber rings 9, io, ii are elastically connected to one another by three transfer manifolds 2o each distributed evenly over the circumference (see Fig. 4). To reduce the dissipation of heat to the outside, each chamber ring rests on circularly distributed short foundation supports 21 which are connected to the lower foundation ceiling 22 of the air heater. The foundation ceiling-22 is built in the frame construction as a foundation for the combined air heater and steam generator; it is supported by supports and pillars from the double floor of the ship. A pipe wall 23, 24 ... 25, 26 ... 27, 28 is rolled into the upper wall of each chamber of the lower chamber rings 9, 1o, ii = two adjacent rows of pipes - except for the area * of the flue gas passage 29 in the Stirring wall 25, 26 - form a closed pipe wall. The relative distance between the individual rows of pipe walls is measured taking into account the variable volume of the combustion gases on their way through the air heater. The individual rows of pipes are traversed by the working air at high speed in the directions indicated by the arrows. The tubes 23, a4 have an outer diameter of 22 mm and a clear diameter of 18 mm. The tubes 25, 26 and: 27. 28 are designed with diameters of 2o / 16 mm. For the rolling in of the pipes or for sealing individual pipes in the event of breakage, the chamber rings are provided with corresponding bores with roller grooves or with stoppers. At the upper end of each double row pipe wall there is a single chamber ring 30, 31, 3?, Each of which serves for the flow transition of the working air from one pipe wall to the immediately adjacent pipe wall. These single chamber rings are basically made in the same way as the double chamber rings; however, they do not receive partitions. To the central. The first pipe wall element 9, 23, 24, 3o is held by the outer ring 33 of the flue gas distribution rosette 34, which is inserted with play. This ensures unimpeded expansion of the pipe wall element in the axial and radial directions. Connected to the rosette 34, the protective rings 35 serve as protection for the rolling points of the tube 23, 24 in the chamber ring 30. Similarly, the second pipe wall zo, 25, 26, 31 through the chamber ring 31 with play compared to the wall ring 36 in its central attitude. The rolling points of the tubes 25, 26 are through. the protective rings 37 protected. The same applies mutatis mutandis to the third pipe wall 11, 27, 28, 32 in;) ezug to the spacer ring 38 and the protective rings 39. The height of the chamber rings 30, 31, 32 is different, on the one hand for the heat dissipation from the flue gases to the In the individual pipes of the pipe walls circulating working air to obtain favorable ratios and on the other hand for the flue gases favorable cross-sectional ratios. For the centrally located burner 40, iöi a burner of known design has been used here, further, as usual, fireclay 41, brick lining 42, covers 43.The latter protect the lower chamber rings 9, io, ii and the pipe rolling points from the direct effects of heat from the flue gases . The flow path of the flue gases is indicated schematically by arrows. Each air heater element can be closed off by a door 44 against the common space 45 below the air preheater 7, if necessary. The room 45 'is accessible through a versahließbazen entrance'46. The outflow of the working air of 700 ° C from the chamber 9 takes place through three on the circumference of the chamber ring 9 evenly distributed and welded pipe bends 47, the one. Feed pipe ring 48. The pipe ring 48 of each of the five elements of the air heater is connected by the pipe bend 49 to the collecting ring 5o, from which the main line 51 leads to the hot-air high-pressure turbine. With regard to the all-round expansion possibility of this kohranordnung the same applies what has been said before. The split jacket 52, 53 of each air heater element is lined with refractory bricks 54 after the flue gas space and protected against heat radiation on the outside with insulating rats 55. For the inspection of the inner parts there are correspondingly lined closure openings 56, 57. The upper furnace vault cover 58, 59 made of refractory bricks can. can be easily dismantled with simple means for the general overhaul of the internal parts of the air heater and the like. The ceiling of each air heater element is a reef sheet plate 6o. The front half of the jacket 52, denoted by 53, can be pulled off laterally over its entire length as a whole by virtue of the flange connection. This ensures that all elements of the fan heater can be easily replaced, without the need for extensive dismantling. Further details are given at the end of this description. Each flue gas ring is equipped with a nozzle ring line 61, 62, 63 for blowing soot on the lower stone covers 43. Each of these sootblower lines can be turned on individually via the compressed air collecting line 64. The six channels 65, 66, which are formed at the junctions by the jackets 52 and the guide jacket 67 for the air preheater tube bundle 68, are used to convey the combustion air conveyed by the air blowers into the collecting line 69 to the tubular air preheater 7, which is divided into four chambers The combustion air is diverted from one adjacent chamber to the other alternately through the associated three channels 65 and 66. The weight of the smoke tube bundle 68 rests on the support ring 70 and is sealed there against the smoke gas space by an asbestos ring placed underneath. The individual chambers of the air preheater are sealed against each other by the asbestos cords embedded in grooved rings 7. The tube bundle can freely follow the thermal expansions, since the neck end of the tube bundle is passed through a stuffing box 72 with asbestos cord cover. The path of the combustion air is schematically indicated by arrows. The jacket parts 52, which directly form the walls of the channels 65, 66, are left without brickwork in order to also use this heat absorption source for preheating the combustion air. From the last (fourth) chamber, the combustion air flows directly into the manifold 73, which is built underneath the foundation ceiling 22 of the air heater and is divided into six ring segments. The five burners 4o of the air heater elements and the burner ioi for the steam generator are fed from this manifold. The size of the opening for the inflow of combustion air after each of these six burners can be regulated by means of a curved slide valve 74. Above the air preheater tube bundle 68, the flue 75 opens up into the flue bend 76 firmly connected to the chimney 8. B. the tube wall 23, 24 connected to the chamber rings 9 and 30 , the three tube bends 47 adjoining the chamber ring 9 and the three overflow bends 2o, which connect the chamber ring 9 to the neighboring chamber ring io, are separated by a flame cut. This work can be carried out through appropriate flaps in the foundation ceiling 22. After the burner 40 and the adjoining fire ring 41 have been removed, the tube bundle that has become free can be pulled out upwards through the lifted furnace ceiling 34, 58, 59. After inserting a replacement wall with chamber rings and pipe sockets 2o, 47, the pipe sockets 2o and 47 are welded together. The brickwork and burner and the furnace vault cover are then reinstalled and the rest of the assembly work is carried out. So that the operation with the remaining four air heater elements and with the steam generator can continue during the repair work, the pipe bend 49 of the air heating element under repair is separated by flame cutting, and the part remaining on the collecting ring So is sealed by encapsulation. Valves can optionally be used to connect and disconnect the individual main pipelines. However, since the material used is easily weldable and whiteable and there is no need to subsequently heat-treat the welds, preference should be given to the design described above without valves. Should the second or third pipe wall have to be replaced, the front half of the casing of the relevant air heater element 53 is removed for this assembly work. However, it is also possible to expand each ring pipe wall upwards. A special design has been selected so that the steam generator can be integrated organically into the basic shape given by the air heater elements. Since the operating pressure for. the intended purpose of the ship's operation only needs to be 6.5 kg / cm2 and because only a water-tube boiler can be considered for a rapid opening of steam and because the burner system should expediently be the same as for the individual elements of the air heater, the selected one can be used Ring shape for the lower and upper drum of the water tube boiler can be regarded as useful, if other shapes are certainly also possible. The burner ioi corresponds to the steam output of the boiler. dimensioned for an hourly fuel throughput which is greater here than the fuel throughput required for an air heater element. The lower and upper ring drums are made up of two ring shells io2, 103 and 104, 105, the ring shell, which is used for rolling in the water pipes, is made with a correspondingly thick wall, while the other ring shell, which receives the four welded-on nozzles io6, which can be closed with a manhole, for driving on the ring drum, is manufactured with a correspondingly thin wall thickness. This makes the production of the ring drums and their handling relatively easy; a damaged pipe can also be easily grafted tight with this design. The boiler has nine rows of annular tubes. The first and second rows (counting from the boiler axis), the fifth and sixth as well as the eighth and ninth rows for the flue gas duct are drawn together to form closed pipe walls. In the area of the three flue gas lanes 107, 1o8, 109 , the tubes of the row in question are widened accordingly. The path of the flue gases is indicated schematically by arrows. Rows of pipes 1 to 6, which are primarily used as risers, pipes of 32/26 mm diameter, and rows of pipes 7 to 9, which mainly serve as downpipes, are equipped with pipes of 36/30 mm diameter. This gives the boiler natural water circulation. In order to have a large volume of water available in the boiler system when more steam is drawn off, a drum is installed outside the actual boiler. The generated steam is fed to this drum through the overflow pipe iii; on the other hand, the water spaces of the ring drums are in constant communication with the water space of the outer drum through the downpipe 112. The steam is extracted from the steam space of the outer drum, which also receives the usual boiler fittings, such as water levels and the like. For the formation of the firebox vault 113, the same structural aspects are taken into account as with those of the air heater elements; the same applies to the lining of the housing jacket 114: the ring pipes for the soot blowing 115, i 16 are connected to the compressed air line 64. The exhaust gas flow to the space 45 below the air preheater can, if necessary, through the door i 18 take place. The supply of the amount of combustion air after the burner ioi can be regulated by a curved slide valve.

Claims (14)

PATENT CLAIMS: i. Air heater for hot air turbines with closed circuit, especially for ship propulsion and with auxiliary steam generation, characterized by several heater elements (i to 5) grouped around a central raw gas duct (7), which in a known manner consist of vertical, concentric around the burner and flame axis of each element arranged pipe strings with common annular collector chambers exist. 2. Air heater according to claim i, characterized in that that it is divided into the same air heater elements (i to 5), which are grouped in a star shape around the central flue gas duct (7), with at least a vertical steam generator element (6) as a further unit in the air heater system is structurally inserted so that the burner (40, 101) for the air heater elements (i to 5) and the steam generator element (6) from a common, in the central one Flue gas duct (7) arranged preheater (68) supplied for the combustion air and the flue gases of all elements (i to 6) of the heater system through the common Drain off the air preheater (68). 3. Air preheater according to claim i and 2, characterized in that that each air heater element (i to 5) from. one in a known manner in the main field straight and. vertically standing pipes (23 to 28) formed-defined double ring pipe wall is constructed, the outer surface of which is cylindrical or slightly conical, and that the ends of all tubes (23, 24) of the double ring tube wall at one end with a Double chamber ring (9), the ends of the tubes at the other end with a simple Chamber ring (30) are connected, and that also the interior of the double ring tube wall (23, 24) serves as a furnace, on the end of which the burner (40) is located, while. the access of the air to be heated for the fan heater element to the outer Chamber of the double chamber ring through several pipe sockets evenly distributed around the circumference takes place and the heated working air in the same type of distribution from the inner chamber (9) of this double chamber ring exits through pipe socket (47). 4. Air heater according to claims i to 3, characterized in that when an air heater element is built up from several concentrically arranged double ring tube walls (23 to 28) the individual Double chamber rings (9 to ii) for each ring pipe wall one below the other by means of several overflow pipe bends (2o) are connected, their inlets and outlets evenly over the circumference of the Annular chambers (9 to ii) are distributed, while the working air to be heated over several pipe bends evenly distributed over the circumference of the outer chamber (ii) (15) of the outermost double-chamber ring (i i) and the heated working medium over several evenly over the circumference of the inner chamber (9) of the innermost double-chamber ring distributed pipe bends (47) emerges. 5. Air heater according to claim i to 4, characterized characterized in that the individual pipe bends (15) for the access of the working air to the outer chamber rings (ii) open into a pipe ring (16) and the pipe bends (47) also for the outflow of the working air from the inner chamber rings (9) open into a pipe ring (48), which in turn over pipe bends (17, 49) into collecting rings (18, 50) for everyone. The heater elements (i to 5) of the system open up, from where the work equipment is supplied or discharged. 6. Air heater according to claim i to 5, characterized in that the upper and lower chamber rings (9 to i i or 3o to 32) are each made of two U-irons bent into rings and in the connecting seam of the U-irons for the lower chamber rings (9 to i i) is a non-running one Partition (i2 to 14) is welded in. 7. air heater according to claim i to 6, characterized in that the individual elements (i to 6) .des heater of a cladding jacket (55) are connected to form a coherent structure, the Core space accommodates the core jacket (67) for a common smoke gas exhaust space, in which the flue gas extractors of the individual heating elements (i to 6) flow in, with the core jacket (67) at the same time the outer periphery of the air preheater (7) for the Combustion air limited. B. Air heater according to Claims 1 to 7, characterized in that that the inner parts of the cladding jacket (55) and the core jacket (67) formed triangular arc spaces (65, 66) as flow channels for the combustion air used, d.ie the air preheater (7) flows through and after the collecting line (73) for the individual burners (4o, ioi) of the Lufter'hitzerzlemente (i to 5) and of the steam generator element (6) flows away, the individual chambers of the air preheater (7) the combustion air flows through one after the other, while the flue gases the flue pipes (68) of the air preheater flow through and at the free end of the vertical Drain the pipe walls after the chimney (75). 9. Air heater according to claim i to 8, characterized in that the free-standing chamber rings (9 to i i) of the double ring tube walls held in the axial direction by guide rings (2i) with radial and axial play are, in such a way that the Doppelririgrahrwand (23 to 28) and the chamber rings (9 to i i) are not hindered in their natural thermal expansions, the Guide rings (2i) attached to the casing for the fan heater element are. 'io. Air heater according to Claims i to 9, characterized in that the Flue pipe walls (68) of the air preheater for the combustion air in the core jacket (67) are attached so that they can move through heat. ii. Air heater according to claims i to io, characterized characterized in that the cover of the combustion chamber and the flue gas chambers of the individual Pneumatic ventilated elements can be removed so that the annular tube walls (23 to 28) after separation the pipe socket (i5, 47) sitting on their double chamber rings (9 to 14) from their Sheath jacket (54) can be pulled out upwards. ' 12. Air heater according to claims i to ii, characterized in that the outer parts of the covering shell (55) are connected to one another by two vertical side flanges in such a way that each outer part can be removed individually. 13. Air heater according to claim i to i2, characterized in that the element (6) designed as a steam generator has a lower (1o2, io3) and an upper tubular drum (1o4, 1o5), each of which consists of two ring shells (1o2, 103 or io4, io5) are welded together, where. the ring shells (1o3, io5), which are used to hold the water pipes (1o7 to io9) arranged in rows, are thick-walled, while the other ring shells (io2, 104) only have a wall thickness corresponding to the steam pressure and are equipped with a manhole socket . 14. Air heater according to claim i to 1d, characterized in that the burner (ioi) for the steam generator (6) is arranged in the vertical boiler axis and the exhaust of the flue gases through the flue gas gases formed by the rows of annular tubes to the central flue gas collecting space (45 ) of the air preheater (7) takes place. Documents considered: German Patent No. 721 32o; Swiss patents No. 258 413, 25 1 223, 240 525.