JP3051745B1 - Air cooler support structure - Google Patents

Abstract

The present invention relates to a support structure for an air cooler, in which a reaction force due to thermal expansion of piping is absorbed on the air cooler side to avoid the influence of the reaction force. The air cooler (81) has four support parts (83).
Are attached, and four support devices 1 are provided on the bottom surface of each support portion 83.
Are fixed, and support the air cooler 81. The support device 1 supports the support portion 83 with the bracket 2, the rod 3 is connected with the pin 8, the rod 3 is fixed to the adjustment tube 4 with the lock nut 10, and the rod 5 is fixed with the lock nut 11 at the lower end of the adjustment tube 4. The rod 5 is attached to the bracket 6 with the pin 9
The lower end of the bracket 6 is connected to the spring support 7
And is elastically supported. When the air cooler 81 receives the reaction force due to the thermal expansion of the pipe, the vertical force is the spring support 7, and the right and left are the pins 8, 9 and the spherical bearings θ ₁ , θ.
_By rotating in _two directions, the movement of the air cooler 81 is absorbed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a structure for supporting an air cooler, and more particularly, to a structure for supporting an air cooler so as to absorb expansion and contraction due to thermal stress of piping connected to the air cooler, and to reduce influence on the piping. It was relaxed.

[0002]

2. Description of the Related Art In a gas turbine, a high-temperature combustion gas from a combustor is caused to flow through a gas path composed of a stationary blade and a moving blade to rotate a rotor. A method of cooling with air is employed. For cooling air, air of about 450 ° C from the compressor is led to an air cooler, cooled with water to form cooling air of about 200 ° C, supplied to the blades and rotor, and the air after cooling is passed through a gas path. Has released. Therefore, 450 ° C. supplied from the compressor is provided between the gas turbine body and the air cooler.
Pipes through which high-temperature air flows through, and pipes through which relatively low-temperature air of about 200 ° C. cooled by an air cooler are laid. In order to absorb the reaction force at the time, a long arrangement is performed by arranging the arrangement to some extent in a U-shape.

FIG. 6 is a configuration diagram of a pipe between an air cooler and a gas turbine. In the air cooler 81, the temperature of the air from the compressor or the temperature is increased to about 450 ° C. after cooling the gas turbine 80. Air flows in from the pipe 90. The inflowing high-temperature air is supplied to the cooling water 1 supplied from the outside to the air cooler 81.
00 is cooled to about 200 ° C. and becomes low-temperature air.
1 is supplied to a gas turbine 80 via a header 82 via pipes 92 and 93.
The cooling blades, rotor blades and rotor are cooled, and the cooled air is discharged to the gas path. In addition, the compressed 45
The air that has become approximately 0 ° C.
And cooled.

FIG. 7 is a plan view showing an example of a pipe connected to the air cooler 81 described above.
Is disposed separately from the gas turbine 80, and low-temperature air 101 of about 200 ° C. is supplied to the gas turbine from a pipe 91, and high-temperature air 1 of about 450 ° C. is supplied from the gas turbine 80.
02 returns to the air cooler 81 and is cooled.
A bypass pipe 94 is a flow path for adjusting the temperature of air supplied to the gas turbine 80 by the valve 95. Between the air cooler 81 and the gas turbine 80, there are such pipes 90, 91, 94, etc., and these pipes expand and contract due to heat, and the reaction force affects the connection with the air cooler 81. Then, the connection portion receives a reaction force.
Further, in order to avoid the influence of such a reaction force, a method of laying pipes in, for example, a U-shape to absorb thermal expansion has been adopted.

[0005]

As described above, there is a pipe between the air cooler of the gas turbine and the gas turbine through which low-temperature cooling air and high-temperature air from the compressor flow. These pipes are affected by heat and expand and contract, and the connection points of the pipes with the air cooler receive the reaction force. Therefore, in order to avoid such thermal effects, pipes are laid in a long length so that the reaction force of thermal expansion can be absorbed, but on the equipment, the thermal effects at the connection point of the air cooler are reduced. It is preferable to reduce the reaction force and to make the piping as short as possible.

Accordingly, the present invention has a support structure in which the reaction force due to the thermal expansion of the pipes connected to the air cooler can be absorbed by the air cooler, thereby reducing the influence of the reaction force received on the pipe side, and for that purpose, An object of the present invention is to provide a support structure for an air cooler that can reduce the length of piping without requiring a bypass for absorbing excess thermal expansion.

[0007]

The present invention provides the following means (1) to (4) to solve the above-mentioned problems.

(1) It comprises a plurality of support structures that support the air cooler of the gas turbine as a foundation, and the support structure includes:
An upper bracket fixed to the bottom of the support portion protruding from the periphery of the air cooler; a support pipe connected to the bottom of the upper bracket and extending vertically downward and having a lower end connected to the lower bracket; An air cooling system comprising a spring support movably elastically supported and fixed to a foundation, wherein the support tube is rotatably connected to the upper and lower brackets via spherical bearings at upper and lower ends. Vessel support structure.

(2) A plurality of pillars that support the bottom surface of the support part projecting from the periphery of the gas turbine air cooler and extend vertically downward, and are respectively connected to lower ends of the plurality of pillars, and the pillars are elastically movable vertically. An air cooling system comprising: a spring support for supporting; and a bogie for supporting each of the spring supports, movably arranged back and forth and left and right on a base surface, and supporting the air cooler on a base. Vessel support structure.

(3) The gas turbine air cooler comprises a plurality of support structures that stand upright from a foundation and suspend the air cooler, and the support structure protrudes from the periphery of the air cooler. A pair of struts arranged on both sides of the portion, a support bracket attached to an upper portion of the same pair of struts, a spring connected between the support bracket and the support portion and suspending the air cooler; A support structure for an air cooler, comprising:

(4) The plurality of columns suspended from the ceiling beam of the building around the gas turbine air cooler, and the air cooling system is connected between the lower end of each column and a support projecting from the periphery of the air cooler. A support structure for an air cooler, comprising a spring for suspending the vessel.

In (1) of the present invention, when a reaction force due to thermal expansion of a pipe to which the air cooler is connected is received, the vertical direction is up and down by the elastic force of the spring support, and
The back and forth movement and the inclination are displaced between the support pipe and the lower bracket supported by the foundation via the upper bracket fixed to the air cooler and the spring support by the free movement by the spherical bearings at the upper and lower ends of the support pipe. And can absorb reaction forces from all directions to the air cooler. Therefore, the air cooler is not affected by the reaction force due to the thermal expansion of the pipe, and the pipe connected to the air cooler does not need to be provided with a detour as in the past and needs to be laid long, and it must be installed in the shortest possible time. Can be.

In (2) of the present invention, when the air cooler receives a reaction force due to the thermal expansion of the pipe, the vertical force is received by the vertical elastic force of the spring support fixed to the upper carriage, and X, The movement on the plane in the Y direction is as follows. The bogie moves in the X and Y directions on the base surface with the air cooler supported by the spring support and the support, and receives forces in all directions, up and down, left and right. Is not affected by the reaction force due to the thermal expansion of the pipe, and the pipe does not need to be long as in the conventional case, and can be arranged as short as possible.

According to (3) of the present invention, when the air cooler receives a reaction force due to the thermal expansion of the pipe, the vertical and horizontal movements in all directions cause the expansion and contraction of the spring and the surrounding of the suspended air cooler. The reaction force is absorbed by the swing, the air cooler is not affected by the reaction force, and the thermal expansion of the piping is also absorbed, so the piping does not need to be long as in the past, and it is minimized. be able to.

In (4) of the present invention, when the air cooler receives a reaction force due to thermal expansion of the pipe, the air cooler suspended by the spring swings in all directions, up and down, left and right, and absorbs the reaction force. Therefore, similarly to the invention of the above (3), the air cooler is not affected by the reaction force due to the thermal expansion of the piping, and the piping can be arranged in the shortest time.

[0016]

Embodiments of the present invention will be specifically described below with reference to the drawings. FIG. 1 shows a support structure of an air cooler according to a first embodiment of the present invention,
(A) is a top view and (b) is a side view. In both figures, four support portions 83 are provided around the air cooler 81, and two cooling water connection ports 84 through which cooling water flows in and out are provided below. The upper portion is provided with an inlet 85 for high-temperature air from the gas turbine compressor, and the lower portion is provided with a low-temperature air outlet (not shown) for supplying cooling air to the gas turbine.

The air cooler 81 is supported by the support device 1 at four support portions 83. The support device 1 is composed of the following 2 to 9 main parts. That is, reference numeral 2 denotes a bracket, which supports the bottom surface of the support portion 83, and reference numeral 3, a rod,
Are connected by Reference numeral 4 denotes an adjusting tube, the upper end of which is fixed to the rod 3 by a lock nut 10 and the lower end of which is fixed to a lower rod 5 by a lock nut 11. 5 is the rod described above, 6 is the lower bracket, and the upper part is
Are connected, and the lower portion is elastically supported by a spring support 7. The shaft 7a to which the lower end of the bracket 6 is fixed is inserted into the spring support 7, elastically supports the shaft 7a, and allows the bracket 6 to move elastically up and down.

In the supporting device 1 having the above-described structure, the air cooler 81 is elastically supported by the four supporting devices 1 via the supporting portion 83, and has an integral structure including the rods 3, 5 and the adjusting tube 4. on the support rod is rotatable through a pin 8, 9 theta ₁ direction under, also via a spherical bearing in the axial direction of the pin 8 and 9 to the bracket 2,6 as will be described later theta _It can rotate in _two directions.

Therefore, when a reaction force is generated due to the thermal expansion of the pipe connected to the air cooler 81, the air cooler 81 receives the reaction force, but the spring support 7 is moved vertically.
The left and right movements and inclination of the surroundings are received by the rotation of the pins 8 and 9 of the brackets 2 and 6 and the spherical bearing described later, and the support device 1 can freely move and receive the reaction force received from the pipe. .

FIG. 2 is a detailed side view of the support device 1 described above. The bracket 2 is attached to the bottom surface of the support portion 83 by welding or the like. through rod 3 is rotatably connected to the theta ₁ direction, theta ₂ direction. The rod 3 has an end inserted into the adjustment tube 4 and fixed with a lock nut 10.

A rod 5 is inserted into the lower end of the adjusting tube 4,
Lock is fixed by a nut 11, the rod 5 of the lower end theta ₁ direction to the bracket 6 by a pin 9 through a spherical bearing 6a, theta ₂
It is connected rotatably in the direction. The bracket 6 is attached to a shaft 7a of a spring support 7 by welding or the like, and the shaft 7a is elastically supported in the spring support 7 so as to be vertically movable.

When the air cooler 81 is supported by the support device 1, the lock nuts 10 and 11 are loosened to adjust the lengths of the adjusting tube 4 and the upper and lower rods 3 and 5, and the four support devices 1 The length of each of the four nuts can be adjusted to the same length, and the lock nuts 10 and 11 can be tightened and fixed to adjust the respective lengths.

As shown in FIG. 1, the supporting device 1 having the above structure is vertically arranged at four locations around an air cooler 81, supports four support portions 83, and holds the air cooler 83.
When the air pipe connected to the air cooler 81 undergoes thermal expansion and receives the reaction force, and receives a force in the vertical and horizontal directions, the air cooler 81 receives the force and the spring support 7 in the vertical direction.
In the axis 7a moves up and down, left and right rotation of the theta ₁ direction about the pin 8, 9 rotate, and the left and right movement of the direction perpendicular to the theta ₁ is spherical bearing 2a, by 6a theta ₂ direction With each rotation, it can move and absorb the reaction force in all directions. Therefore, no excessive force is applied to the pipe connected to the air cooler 81, so that there is no need to provide a U-shaped detour as in the related art, and the path of the pipe can be shortened.

FIGS. 3A and 3B show a support structure of an air cooler according to a second embodiment of the present invention, wherein FIG. 3A is a side view thereof, and FIG.
FIG. 3 is a view taken along the line AA in FIG. In the figure, in the second embodiment, the air cooler 81 is supported by a movable carriage and has a structure in which the air cooler 81 is also elastically supported in the vertical direction, which will be described in detail below.

In FIG. 3, reference numeral 21 denotes four columns,
The tip supports the bottom surface of the support portion 83, and the lower end is supported by spring supports 27 fixed to the four corners of the upper carriage 22. Reference numeral 22 denotes an upper carriage, and four rollers 23 are X
It is provided on the bottom surface so as to rotate in the direction and move freely. 24
Is a lower carriage, two guide grooves 25 are provided on the upper surface in the X direction, the rollers 23 of the upper carriage 22 are inserted, guided by these grooves 25, and the upper carriage 22 is movable in the X direction. I have.

Reference numeral 26 denotes four rollers provided on the bottom surface of the lower carriage 24, which are mounted so as to be movable in the Y direction along guide grooves 28 provided on the upper surface of the base. Reference numeral 27 denotes a spring support, which elastically supports the lower ends of the four columns 21, and provides an air cooler 81 to the upper carriage 23 via the columns 21.
It is to support.

In the second embodiment of the above construction, when the air cooler 81 receives a reaction force due to the thermal expansion of the pipe, the vertical movement is caused by the spring support 27 and the X direction and the Y direction.
The direction of movement is such that the upper bogie 22 moves in the X direction by rollers 26 along the guide grooves 25 and the lower bogie 24
It moves in the Y direction along 8 and can absorb forces in all directions that the air cooler 81 receives. Therefore, the same effect as that of the first embodiment shown in FIG. 1 can be obtained also in such a support structure of the second embodiment.

FIGS. 4A and 4B show a support structure for an air cooler according to a third embodiment of the present invention, wherein FIG. 4A is a top view, and FIG. In the figure, in the third embodiment, the air cooler 81 is structured to be suspended by a support by a spring, which will be described in detail below.

In FIG. 4, reference numeral 31 denotes eight columns.
Each two are disposed on both sides of the four supporting portions 83 around the air cooler 81, and are fixed to the foundation. That is, columns 31-1 and 31-2 are arranged on both sides of the support portion 83, the upper ends of the columns 31-1 and 31-2 extend above the support portion 83, and the support brackets 32 are attached to the ends of both columns. Have been. Reference numeral 33 denotes a spring, which has upper and lower ends attached between the support bracket 32 and the support portion 83 at four locations, and has a configuration in which the air cooler 81 is suspended and elastically supported at four locations via the support portion 83.

According to the third embodiment of the above construction, when the air cooler 81 receives a reaction force due to the thermal expansion of the pipe, the movement in all directions, up and down, left and right, is performed by the four springs 33.
As a result, the air cooler 81 is provided with the spring 3 at the center of the eight columns.
By suspending at 3, swinging freely and moving, it is possible to absorb reaction forces in all directions. Therefore, the same effect as that of the first embodiment shown in FIG. 1 can be obtained in the support structure of the third embodiment.

FIG. 5 is a side view of a support structure for an air cooler according to a fourth embodiment of the present invention. In the drawing, reference numeral 40 denotes a ceiling beam of a building, 41 denotes four suspension columns whose upper ends are fixed to the ceiling beam with bolts or the like, and a spring 42 is attached to the lower end thereof. It is attached to the support of the cooler 81. In the fourth embodiment, the air cooler 81 is suspended from the ceiling beam 40 by four suspension columns 41 and springs 42. When the air cooler 81 receives a reaction force due to thermal expansion of the pipe, As in the third embodiment shown in FIG. 4, by swinging up and down and left and right through the spring 42, the reaction force in all directions is absorbed, so that the same effect as in the first embodiment is exerted. be able to.

In addition to the above-described first to fourth embodiments of the support structure, a cold spring method can be employed as a means for receiving a reaction force due to thermal expansion of the pipe with respect to the air cooler. As this method, there is a method of pulling the pipe in a cold state and attaching the pipe under tension, or compressing the pipe to cope with expansion and contraction due to heat. Further, as another means,
It is also possible to provide a flexible hose at a predetermined location in the piping or use an expansion joint at the connection with the air cooler to make the connection stretchable, which is effective as a means to absorb the thermal stress of the piping. There is something.

In the first embodiment described above, the pins 8, 9; the spherical bearings 2a, 6a;
In the second embodiment, an upper bogie 2 is provided.
2 and the lower bogie 24 are combined, and the upper bogie 22 has a structure in which a spring support 27 is installed. In the third embodiment, the structure is suspended by a support 31 and a spring 33. In the fourth embodiment, a ceiling is provided. The beam 40 is suspended by a suspension column 41 and a spring 42.
Are supported, so that even if a reaction force due to thermal expansion of the pipe is applied to the air cooler 81, all the reaction forces can be absorbed by these structures. Further, with such a support structure, it is not necessary to provide a long pipe for absorbing thermal elongation as in the prior art, and the path of the pipe can be shortened.

[0034]

The support structure of the air cooler of the present invention is as follows.
(1) An upper bracket fixed to a bottom of a support portion protruding from the periphery of the air cooler, the upper bracket comprising a plurality of support structures that support an air cooler of a gas turbine as a foundation. A support tube connected to the bottom surface and extending vertically downward and having a lower end connected to the lower bracket, a spring support fixed to a foundation, elastically supporting the bottom surface of the lower bracket so as to be vertically movable, the support tube being The upper and lower brackets are rotatably connected to the upper and lower brackets via spherical bearings. With such a configuration, when receiving a reaction force due to thermal expansion of the pipe to which the air cooler is connected, the vertical direction is the vertical movement due to the elastic force of the spring support, the left and right, the front and rear movement, and the inclination are the upper and lower ends of the support pipe. The reaction force can be absorbed by the free movement of the support tube by the spherical bearing. Therefore, the air cooler is not affected by the reaction force due to the thermal expansion of the pipe, and the pipe connected to the air cooler can be disposed in the shortest time without having to provide a detour as in the related art and laying it long. .

According to the second aspect of the present invention, a plurality of pillars that support a bottom surface of a support part protruding from the periphery of the gas turbine air cooler and extend vertically downward are connected to lower ends of the plurality of pillars, respectively. It is characterized by comprising a spring support that elastically supports up and down movement, and a bogie that supports each of the spring supports, is arranged movably back and forth and left and right on a base surface, and supports an air cooler as a base. With such a configuration, when the air cooler receives a reaction force due to the thermal expansion of the pipe, the vertical force is received by the vertical elastic force of the spring support fixed to the upper carriage, and the air cooler is placed on the plane in the X and Y directions. The movement of the bogie moves in the X and Y directions on the base surface with the bogie supporting the air cooler by the spring support and the support, and receives the force in all directions, up and down, left and right. Is not affected by the reaction force
The piping does not need to be long as in the prior art, and can be arranged as short as possible.

A third aspect of the present invention comprises a plurality of support structures that are erected from a foundation around a gas turbine air cooler and suspend the air cooler, and the support structure is the air cooler. A pair of struts arranged on both sides of a support portion protruding from the periphery, a support bracket attached to an upper portion of the same pair of struts, and the air cooler connected between the support bracket and the support portion. And a suspending spring. With such a configuration, when the air cooler receives a reaction force due to the thermal expansion of the pipe, the movement in all directions up and down, left and right is caused by the expansion and contraction of the spring and the swing around the suspended air cooler. The air cooler is not affected by the reaction force, and the thermal expansion of the piping is also absorbed, so that the piping does not need to be long as in the conventional case, and can be minimized.

(4) The present invention provides a plurality of columns suspended from a building ceiling beam around a gas turbine air cooler,
A spring is provided between the lower end of each of the columns and a support protruding from the periphery of the air cooler, and a spring for suspending the air cooler is provided. With such a configuration, when the air cooler receives a reaction force due to thermal expansion of the pipe, the air cooler suspended by the spring swings in all directions, up and down, left and right, and absorbs the reaction force. 3)
Similarly to the invention, the air cooler is not affected by the reaction force due to the thermal expansion of the pipe, and the pipe can be disposed in the shortest time.

[Brief description of the drawings]

FIG. 1 shows a support structure of an air cooler according to a first embodiment of the present invention, wherein (a) is a top view and (b) is a side view.

FIG. 2 is a detailed side view of the support device shown in FIG.

3A and 3B show a support structure of an air cooler according to a second embodiment of the present invention, wherein FIG. 3A is a side view, and FIG. 3B is a view taken along line AA in FIG.

4A and 4B show a support structure of an air cooler according to a third embodiment of the present invention, wherein FIG. 4A is a top view and FIG. 4B is a view taken along the line BB in FIG.

FIG. 5 is a side view of a support structure for an air cooler according to a fourth embodiment of the present invention.

FIG. 6 is a general system diagram showing an air cooling system of a gas turbine.

FIG. 7 is a plan view showing piping of an air cooling system of a conventional gas turbine.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Support device 2,6 Bracket 3,5 Rod 4 Adjustment pipe 7,27 Spring support 8,9 Pin 10,11 Lock nut 21,31 Support post 22 Upper carriage 23,26 Roller 24 Lower carriage 25,28 Guide groove 32 Support bracket 33, 42 Spring 40 Ceiling beam 41 Suspension support 81 Air cooler 83 Support

Continuation of the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) F02C 7/20 F02C 7/18 F02C 7/143 F28F 9/00

Claims (4)

(57) [Claims] 1. A support structure for supporting a gas turbine air cooler as a foundation, the support structure including an upper bracket fixed to a bottom surface of a support portion protruding from the periphery of the air cooler; A support tube connected to the bottom surface of the lower bracket and extending vertically downward and having a lower end connected to the lower bracket; and a spring support elastically supporting the bottom surface of the lower bracket so as to be vertically movable and fixed to a foundation. A support structure for an air cooler, wherein a pipe is rotatably connected to upper and lower brackets at upper and lower ends via spherical bearings. 2. A support for supporting a bottom surface of a support portion protruding from the periphery of a gas turbine air cooler, a plurality of columns extending vertically downward, and connected to lower ends of the plurality of columns, respectively, to elastically support the column to be vertically movable. An air cooler, comprising: a spring support that supports each of the spring supports; and a bogie that is disposed movably back and forth and left and right on a base surface, and that supports the air cooler on a base. Support structure. 3. A gas turbine air cooler comprising a plurality of support structures standing upright from a foundation and suspending the air cooler, wherein the support structure protrudes from the periphery of the air cooler. A pair of columns arranged on both sides of the pair, a support bracket attached to the top of the same pair of columns, and a spring that is connected between the support bracket and the support section and suspends the air cooler. A support structure for an air cooler, comprising: 4. A plurality of pillars suspended from a building ceiling beam around a gas turbine air cooler, and the air cooler connected between a lower end of each of the pillars and a support projecting from the periphery of the air cooler. And a spring for suspending the air cooler.