RU39186U1 - HEAT EXCHANGE REGENERATIVE AIR HEATER UNIT - Google Patents

Abstract

The utility model relates to a power system, and in particular, to devices for recovering heat from gases emitted from aggregates, in particular, for heating air with exhaust products coming from a compressor of a gas turbine installation of a gas pumping unit at compressor stations of gas mains. The heat exchanger block of a regenerative air heater, preferably a block-section one, consists of a housing, a bottom, a top cover and end walls, a housing, manifolds for supplying and discharging a heated medium with tube plates, and a multi-way multi-row bundle of heat exchange tubes, forming, respectively, in each row an even number of straight-line multi-tube branches , including at least two internal and two external, connected by sections with bends of a predominantly constant beam for all pipes a dius, the bottom, the cover and one of the end walls of the block body made in the form of panels with strapping elements of stiffness forming flat rod systems, and the spatial frame of the block is formed by a combination of flat rod systems of the frameworks of these panels with intermediate racks uniting them and rigidly connected with them by the bodies of the inlet and outlet manifolds of the heated medium, which, in turn, are connected to the bottom of the block and to each other by double-ring diaphragms and a displacer of the annular medium, the collector bodies for supplying and discharging a heated medium with tube boards mounted in them and an annular displacer form a spatially developed rigid end wall of the block body, and on the longitudinal sides the frame is made with the possibility of fixing respectively diffuser and confuser elements for supplying and discharging a cooled medium. The technical result achieved by using the proposed utility model is to create conditions for efficient heat transfer when flowing around a four-way multi-row bundle of heat transfer pipes, as well as to increase the rigidity and strength of the structure while reducing metal consumption.

Description

The utility model relates to a power system, and in particular, to devices for recovering heat from gases emitted from aggregates, in particular, for heating air with exhaust products coming from a compressor of a gas turbine installation of a gas pumping unit at compressor stations of gas mains.

Known air heater (SU No. 992920, F 12 L 15/04, 1983), containing located on top of one another and mounted on the lower frame blocks of heat-exchange sections, formed by vertical tubes with horizontal tube boards, rigidly fastened to each other and the upper distribution box, equipped with a compensator for temperature changes, while the air heater is equipped with a power belt with spring supports covering the junction box, rigidly fastened with a belt in the area below its compensator, and the section you the latter interacting with its spring supports.

Known regenerative air heater (SU, No. 985595, F 12 L 15/04, 1982), containing a tube plate with a bundle of heat exchange tubes fixed in it, installed in vertical rows, the planes of which are perpendicular to the supporting edges of the tube plate, while reducing thermal stresses of the pipe in the places of fixing the bundle of pipes in the pipe boards of the pipe in rows in sections located on the side of the supporting edges of the pipe board are connected to each other and to the pipe boards by additional spacers.

The disadvantages of the above devices include the complexity of their design and metal consumption. In the first analogue, the load from the upper distribution box is perceived through the blocks of the heat exchange sections by the lower frame, and therefore the introduction of a power belt with spring supports was required. In the second analogue, in order to reduce thermal stresses, it was necessary to introduce spacers connecting the pipes together and with the tube plate.

The closest analogue is a regenerative air heater (RU, No. 31838 F 23 L 15/04, 2002) containing a spatial frame, a bottom, a top cover and end walls, collectors for supply and removal of a heated

media with tube plates and heat transfer units having one-pack four-way bundles of heat transfer tubes forming straight lines in each row - two internal and two external, ends of the heat transfer tubes are connected to the air supply and exhaust manifolds, individual tube boards welded directly into the wall of the corresponding collector.

The disadvantages of the closest analogue include the fact that it does not provide high thermal efficiency, as well as the compactness of the stacking of heat transfer pipes, while ensuring strength and rigidity of the structure, as a result of which the closest analogue has an increased metal consumption.

The problem solved by the utility model is to increase the heat transfer efficiency while increasing the strength and rigidity of the structure and reducing the metal consumption.

The problem is solved due to the fact that the heat exchanger block of the regenerative air heater, preferably block-sectional, contains a housing, a housing, collectors for supplying and discharging the heated medium with pipe boards and a multi-way multi-row bundle of heat-exchange pipes, which consists of a spatial frame, bottom, and end walls respectively, in each row, an even number of rectilinear multitube branches, including at least two internal and two external, connected by sections with bends pre a radius beam substantially constant for all pipes, while the bottom, the cover, and one of the end walls of the block body are made in the form of panels with strapping elements of stiffness forming at least within each panel flat rod systems, and the spatial frame of the block is formed by a set of flat rod frame systems of these panels with intermediate racks uniting them and rigidly connected to them bodies of collectors for supplying and discharging a heated medium, which, in turn, are connected to the bottom of the block and between each other with double-ring diaphragms and a displacer of the annulus, moreover, parts of the housings of the collectors for supplying and discharging the heated medium with tube boards and a displacer of the annulus installed in them together form a spatially developed rigid end wall of the block casing, and along the longitudinal sides the frame is made with the possibility of fastening elements of the diffuser and confuser for supplying and discharging the cooled medium, while the transverse area

the cross section of each of the collectors is 1.8-3.5 of the total flow area of the heat transfer tubes in the block.

The displacer annular medium can be made in the form of a profiled panel with a flat section located in the plane of the outer surfaces of the tube sheets of the bundle of heat transfer tubes.

Combs for at least the inner branches of the lower row of heat transfer tubes can be fixed to the bottom of the housing.

The heat exchange unit may be provided with spacing elements fixed to the bottom and frame of the unit body for heat exchange pipes of the outer beam branches in the form of spacing grids, said heat exchanging pipes being passed through openings of the spacing grids, and subsequent rows of heat exchanging pipes in the area of internal branches can be separated by spacing fold-shaped strips that are attached to racks mounted on the bottom.

The collectors for supplying and discharging the heated medium can be made with manholes located on the side of the bottom of the unit, while the manhole covers are pivotally mounted on the bodies of the collectors for supplying and discharging the heated medium with the possibility of rotation in a plane perpendicular to the longitudinal axis of symmetry of the collectors of the inlet and outlet heated medium.

The displacer of the annular medium can be made in the form of a profiled panel with a flat section, the inner surface of which is located between the collectors in the same plane as the outer plane of the tube plates or can be made in the form of a flat panel welded to the walls of the collectors for supplying and discharging the heated medium so that it the inner surface is located in the same plane with the outer plane of the tube plates.

The block can be equipped with brackets for attaching external thermal insulation.

On the inner walls of the manifolds for supplying and discharging the heated medium, supports can be installed that form a ladder for inspection and maintenance of the manifolds for supplying and discharging the heated medium and tube plates.

The heat exchange unit may be equipped with means for attaching a diffuser for supply and a confuser for draining the cooled medium, mounted on opposite side elements of the spatial frame of the block.

The technical result achieved by using the proposed utility model is to create conditions for efficient heat transfer when flowing around a four-way multi-row bundle of heat exchange tubes filled with heated air, high-temperature combustion products, including in the area of the end wall of the block, as well as to increase the rigidity and strength of the structure operating at high temperatures, while reducing metal consumption.

The achievement of the technical result is ensured by the inclusion in the power circuit of the casing block of the air heater of the end wall formed from parts of the casing of the manifolds for supplying and discharging the heated medium with tube plates and a displacer of the annular medium, while the ratio between the cross-sectional area of the heat exchanger pipes made by multi-pass single-packet must be observed , and the area of the passage section of one of the collectors for supplying or removing the heated medium. The high heat exchange efficiency of the regenerative air heater with the specified properties of the coolant is achieved due to the design of one of the end walls described above, which eliminates the occurrence of stagnant zones in the end of the heat exchange unit using distance elements having a different design for the external and internal branches of the heat exchanger tube bundle, ensuring their good washability surface combustion products and reliable volumetric fixation of heat transfer pipes. Along with efficient heat transfer, the spatially developed design of the end wall formed by collectors with tube boards mounted in them and the design of a displacer of the annular medium provides strength and rigidity of the structure while reducing metal consumption.

The utility model is illustrated by drawings, which depict:

figure 1 is a main view of a regenerative air heater;

figure 2 - regenerative air heater, top view;

figure 3 is a section of a regenerative air heater, the main view;

figure 4 is a section of a regenerative air heater, side view;

figure 5 - heat transfer unit regenerative air heater;

figure 6 - node a in figure 4;

Fig.7 is a section bB in Fig.4;

on Fig - heat transfer unit regenerative air heater, top view.

Regenerative air heater, mainly block-sectional, contains two sections 1, each of which consists of at least two heat-exchange blocks 2, mounted one above the other inside the section housing. In a preferred embodiment, section 1 comprises four heat exchange units 2.

Each heat exchange unit 2 includes a housing 3 formed of a spatial frame, a bottom, a top cover and end walls, collectors for supplying 4 and exhaust 5 of a heated medium, which are connected to heat transfer pipes 6 by means of separate tube plates 7 and 8. Heat transfer pipes 6 form a multi-pass multi-row a bundle having in each row an even number of rectilinear multitube branches, including at least two internal and two external branches connected by sections with bends of a beam of radius R constant for all pipes.

The bottom 9, the top cover 10 and one of the end walls 11 of the block body are made in the form of panels with a strapping of stiffeners forming a flat rod system 12.

The spatial frame of block 2 is formed by a combination of flat core systems of panel frames with interconnecting intermediate racks 13 and collector bodies 4 and 5 rigidly connected to them, which, in turn, are connected to the bottom 9 of block 2 and to each other by two-ring diaphragms and a displacer 14 of the annular medium . Parts of the bodies of the inlet 4 and 5 outlet manifolds of the heated medium with tube plates 7 and 8 mounted in them and the annular displacer 14 together form a spatially developed rigid end wall 15 of the block 2 case. Along the longitudinal sides, the frame is made with the possibility of fixing the elements of the diffuser 16 and confuser 17 for supplying and discharging a cooled medium.

The cross-sectional area of each of the collectors 4 or 5 is 0.45-0.82 of the total flow area of the heat exchanger tubes b in block 2.

The annular displacer 14 is a profiled panel with a flat section 18 located in the plane of the outer surfaces

pipe boards 7 and 8 of the bundle of heat transfer pipes.

Combs 19 are fixed on the bottom of the housing 9 for at least the inner branches of the lower row of heat transfer tubes 6.

The heat exchange unit has spacing elements fixed to the bottom 9 and the frame of the block body 3 for the heat exchange tubes of the outer beam branches in the form of spacing grids, the heat transfer pipes of the outer beam branches passing through the openings of the spacing grids.

The rows of heat exchange tubes 6 in the area of internal branches are separated by folded spacing bars 20 that are attached to racks mounted on the bottom 9.

The manifolds for supplying 4 and venting 5 of the heated medium are made with manholes located on the side of the bottom of the unit, while the covers 21 for manhole are pivotally mounted on the bodies of the manifolds for supplying 4 and venting 5 of the heated medium with the possibility of rotation in a plane perpendicular to the longitudinal axis of symmetry of the collectors supply 4 and removal 5 of the heated medium.

The displacer 14 of the annular medium can be made in the form of a profiled panel with a flat section, the inner surface of which is located between the collectors of the inlet 4 and the outlet 5 of the heated medium in the same plane as the outer plane of the tube plates 7 and 8, or can be made in the form of a flat panel welded to the walls of the collectors inlet 4 and outlet 5 of the heated medium so that its inner surface is located in the same plane with the outer plane of the tube plates 7 and 8.

The block can be equipped with brackets for attaching external thermal insulation.

On the inner walls of the manifolds for supplying and discharging the heated medium, supports can be installed that form a ladder for inspection and maintenance of the manifolds for supplying and discharging the heated medium and tube plates.

The heat exchange unit can be equipped with means for attaching a diffuser 1 6 for supply and a confuser 17 for removing the cooled medium mounted on opposite side elements of the space frame of the block.

The regenerative air heater is as follows.

The air intended for the combustion of a gas turbine installation enters the compressor, in which it is compressed, and then through the supply pipe through the collector 4 for supplying a heated medium and the pipe board 7 is supplied to the heat exchange pipes 6 of blocks 2 of each section. The air temperature after the compressor is about 200 ° C.

The combustion products of the above composition from the turbine turbine unit through a diffuser 16 adjacent to the casing of the heat exchange unit 2, enter the section unit 2 and wash the heat exchange pipes 6 with heated air. The supply of combustion products to the heat exchange units 2 is carried out in countercurrent with the direction of movement of the heated air, that is, the combustion products enter the heat exchange unit 2 from the location of the collector of the exhaust 5 of the heated air. At the entrance to the heat exchange unit 2, the combustion products have a temperature of 520-550 ° C.

Passing through heat exchanging pipes 6 of blocks 2, the air is heated by the combustion products to a temperature of 440-450 ° C and through the pipe board 8 it enters the collector 5 of the outlet of the heated medium, from which it is supplied through the pipeline to the inlet of the gas turbine combustion chamber.

The combustion products are discharged into the atmosphere through the confuser 17 adjacent to the housing of the heat exchange units 2.

Claims (9)

1. The heat exchange unit of a regenerative air heater, preferably block-sectional, characterized in that it comprises a housing consisting of a spatial frame, bottom, top cover and end walls, manifolds for supplying and discharging a heated medium with tube plates and a multi-way multi-row bundle of heat exchange tubes, respectively forming in each row, an even number of straight multi-pipe branches, including at least two internal and two external, connected by sections with bends, mainly A beam of radius constant for all pipes, with the bottom, the cover, and one of the end walls of the block body made in the form of panels with strapping from stiffeners forming flat rod systems, and the spatial frame of the block is formed by a set of flat rod systems of the frameworks of these panels with intermediate panels connecting them racks and rigidly connected to them bodies of manifolds for supplying and discharging a heated medium, which, in turn, are connected to the bottom of the block and to each other by double-ring diaphragms and a displacer an annular medium, and parts of the bodies of the manifolds for supplying and discharging the heated medium with tube boards mounted in them and an annular displacer form a spatially developed rigid end wall of the block body, and along the longitudinal sides the frame is made with the possibility of fixing, respectively, diffuser and confuser elements for supply and removal of the cooled medium, while the displacer annular medium is made in the form of a profiled panel with a flat section located in the plane of the outer overhnostey tubesheets bundle of heat exchange tubes. 2. The heat exchange unit according to claim 1, characterized in that the cross-sectional area of each of the collectors is 1.8-3.5 of the total flow area of the heat-transfer pipes in the block. 3. The heat exchange unit according to claim 1 or 2, characterized in that combs are mounted on the bottom of the housing for at least the inner branches of the lower row of heat transfer pipes. 4. The heat exchange unit according to claim 1, characterized in that it is provided with spacer elements fixed to the bottom and frame of the block body for heat exchange tubes of the outer beam branches in the form of spacing grids, said heat exchanging tubes being passed through the openings of the spacing grids, and subsequent rows of heat transfer tubes in the area of internal branches are separated by folded-off spacers that are attached to racks mounted on the bottom. 5. The heat exchange unit according to claim 1, characterized in that the headers for supplying and discharging the heated medium are made with manholes located on the side of the bottom of the unit, while the manhole covers are pivotally mounted on the bodies of the headers for supplying and discharging the heated medium with rotation in a plane perpendicular to the longitudinal axis of symmetry of the inlet and outlet collectors of the heated medium. 6. The heat exchange unit according to claim 1, characterized in that the displacer of the annular medium is made in the form of a profiled panel with a flat section, the inner surface of which is located between the collectors in the same plane as the outer plane of the tube plates or in the form of a flat panel welded to the walls of the supply manifolds and the removal of the heated medium so that its inner surface is located in the same plane with the outer plane of the tube plates. 7. The heat exchange unit according to claim 1, characterized in that the unit is equipped with brackets for attaching external thermal insulation. 8. The heat exchange unit according to claim 1, characterized in that on the inner walls of the collectors for supplying and discharging the heated medium, supports are formed that form a ladder for inspection and maintenance of the collectors and tube plates. 9. The heat exchange unit according to claim 1, characterized in that it is equipped with means for attaching a diffuser for supplying and a confuser for draining the cooled medium mounted on opposite side elements of the spatial frame of the block.