JPS641719B2 - - Google Patents

Description

[Detailed Description of the Invention] [Object of the Invention] (Industrial Application Field) The present invention relates to a support frame, and particularly relates to a support frame for supporting an object whose bottom size changes depending on temperature changes, such as a heat exchanger. The present invention relates to a support frame capable of supporting an exchange cylinder on an installation surface without causing thermal distortion.

(Prior technology) A power generation system that generates steam by using the exhaust heat possessed by high-temperature gas discharged from a gas turbine and uses this steam as working steam for the steam turbine is known as an exhaust heat recovery type combined cycle power generation plant. Are known.

Figure 1 shows an example of this type of combined cycle power generation plant, in which high-temperature, high-pressure exhaust gas discharged from a gas turbine 1 is sent to an exhaust heat recovery heat exchanger 3 via an exhaust pipe 2. .

The exhaust gas that has entered the exhaust heat recovery heat exchanger 3 flows upward, passes through the evaporator 4 and the economizer 5, and exits from the outlet duct 3b to a chimney (not shown). The evaporator 4 and economizer 5 are composed of a large number of heat transfer tubes 6 formed in a meandering shape, and steam and water flow through these tubes. One end of a heat transfer tube 6 constituting the economizer 5 is connected to a condenser 8 via a water supply pipe 7, while the other end is connected to a canned water portion of a steam drum 9. Further, one end of the heat transfer tube 6 constituting the evaporator 4 is connected to the steam of the steam drum 9, and the other end is attached to the can water section via the pump 10. Further, a main steam pipe 11 is connected to the steam chamber of the steam drum 9, and the main steam pipe 11 is connected to a turbine inlet of a steam turbine 12. Furthermore, a condenser 8 is installed on the outlet side of the steam turbine 12. has been done.

In such a configuration, exhaust steam from the steam turbine 12 becomes condensed water in the condenser 8, and is force-fed to the economizer 5 from the water supply pipe 7 by the water supply pump 13. The feed water preheated by the economizer 5 flows into the can water section of the steam drum 9. The canned water in the steam drum 9 is fed from the bottom of the drum to the evaporator 4 by the transfer pump 10, evaporated in the heat transfer tube 6 to become steam, and returned to the steam chamber of the steam drum 9 again.
The steam in the steam drum 9 is extracted from the steam in the drum, introduced into the steam turbine 12 through the main steam pipe 11, performs work in the turbine, and then flows into the condenser 8 again.

It has been confirmed that in such an exhaust heat recovery type combined cycle power plant, the thermal efficiency of the plant is increased by several percent compared to conventional plants because the high temperature gas turbine exhaust gas is effectively used.

By the way, the heat exchange shell of this type of exhaust heat recovery heat exchanger 3 is supported on the installation surface 15 via a truss-type support frame, as shown in FIGS. 2 and 3. In the conventional support frame, the truss body is constructed by stacking a plurality of rectangular parallelepiped-shaped truss units 16 ₁ , 16 ₂ . . . 16 ₆ , and the heat exchanger 3
The four corners of the bottom of the heat exchange cylinder are supported via four support points S ₁ , S ₂ , S ₃ , and S ₄ on the upper surface of the truss body. One of the four corner support points
Only S ₄ is a fixed support point, and the remaining support points S ₁ ,
S ₂ and S ₃ are slidable sliding support points using sliding plates, which are configured to reduce friction and absorb thermal distortion caused by thermal expansion.

(Problem to be Solved by the Invention) However, in such a support frame, due to long-term use, the sliding plate may wear out or dirt may enter the sliding surface, causing the coefficient of friction to change over time. The horizontal force due to thermal expansion acting on the moving point also changed, which was different from the original design basis and was dangerous.

Furthermore, in order to replace the sliding plate after installation, the exhaust heat recovery heat exchanger must be dismantled and moved, and the upper mechanism must also be removed, making maintenance extremely difficult.

The present invention was made to solve the above-mentioned problems, and even when the size of the bottom of the supported object changes due to temperature changes, it absorbs thermal distortion and keeps the supported object on the installation surface. The purpose of the present invention is to provide a support frame that can support the

[Structure of the Invention] (Means for Solving the Problems) The support frame of the present invention is arranged on a horizontal installation surface and supports an object by placing it on the upper surface side. on the installation surface,
A truss body formed by horizontally connecting a plurality of box-shaped truss units each having the same shape so as to have a size commensurate with the bottom of the supported object, and one side of the top surface of the truss body. The fixing support portions are provided at opposing corners on each side and support the supported object in a fixed state, and correspond to the opposing corners on the other side of the top surface of the truss body or the bottom corner of the supported object. a movable support, which is provided on each of the installation surfaces and whose supporting end is fixed to the bottom of the supported object and elastically deforms to follow the horizontal displacement of the bottom of the supported object due to thermal expansion; The above-mentioned problems are solved by providing the above-mentioned parts.

(Function) In other words, in the present invention, even if the bottom of the supported object supported on the horizontal installation surface via the truss body is displaced in the horizontal direction due to thermal expansion, the opposing position on one side of the top surface of the truss body While the corner and the supported object are supported in a fixed state by the fixed support part, the mounting surface and the supported object correspond to the opposing corner on the other side of the top surface of the truss body or the corner of the bottom of the supported object. Since the movable support section interposed between the two is elastically deformed following the above-mentioned displacement, the above-mentioned displacement is absorbed.

(Example) Examples of the support frame according to the present invention will be described below.

In FIGS. 4 and 5, reference numeral 3 indicates a supported object supported on an installation surface using the support frame according to the present invention. In the embodiment of the present invention, the heat exchanger 3 as the supported object is a heat exchange shell of a heat exchanger in the above-mentioned waste heat recovery type combined cycle power generation plant, and this heat exchange shell is used for exhaust gas from a gas turbine. The size of the bottom plate changes due to thermal expansion to guide high-temperature, high-pressure gas.

This heat exchange cylinder as a supported object is supported by the support frame of the present invention, and this support frame includes five truss units 16 ₁ , 16 ₂ , 16 ₃ , 1
It is composed of a truss main body 16 constituted by 6 ₄ and 16 ₅ , and a fixed support part and a movable support part, which will be described later. Each truss unit 16 ₁ , 16 ₂ , 16
₃ , 16 ₄ , 16 ₅ are as shown in Figure 6,
An upper frame 17 framed in a rectangular shape, a lower frame 18 of equal size framed similarly, and four vertical columns 19 of equal length connecting the corresponding corners of these upper and lower frames.
19, 19, and between the diagonally opposing ridges there are two braced beams, that is, lattice beams 2.
0 and 21 are strung together to reinforce the strength. The number and size of these truss units may be appropriately determined in consideration of the weight of the object to be supported.

The bottom portion 22 of the heat exchanger 3 has two opposing locations on the right end of the truss body 16 and fixed support portions 23 and 2 formed by fixed hinges, for example.
Fixed via 3.

On the other hand, the bottom part 24 on the opposite side is a support end of a movable support part 27 formed by fixing a fixed hinge 26 fixed to the bottom part 24 to the tip of a column 25 supported in a cantilever manner with respect to the truss main body 16, for example. Supported by. Note that the cross-sectional dimensions of the support columns 25 are designed in advance with weight taken into consideration so as not to cause buckling. Further, in this embodiment, the support column 25 is supported on the truss body 16, but it goes without saying that the base end portion of the support column 25 may be directly supported on the installation surface 15.

Since the support frame of the present invention is constructed as described above, even when the heat exchange cylinder as a supported object is heated and expands in size at the bottom, the support columns 25 are It is possible to absorb changes in the support portion due to the expansion of the heat exchange cylinder by bending as shown by the broken line following the expansion of the exchange cylinder.

In order to compare the horizontal force due to thermal expansion between the support frame according to the present invention and the conventional support frame, the total weight of the supported object was 1000 tons, the rising temperature was 50°C, the moment of inertia of the column Iy = 80000 cm ⁴ , and the supported object was When the total length of is 2000 cm, the horizontal force is 2.80 tons per load point in the case of the support frame according to the present invention, whereas it can reach 25 tons per load point in the case of the conventional support frame. confirmed.

In the above embodiments, an exhaust heat recovery type heat exchanger was explained as an example of the object to be supported, but the present invention is not limited to this, and can be applied generally when supporting large equipment that causes thermal expansion. It is applicable.

[Effects of the Invention] As described above, according to the present invention, even if the bottom of the supported object supported on the horizontal installation surface via the truss body is displaced in the horizontal direction due to thermal expansion, the top surface of the truss body The opposite corners on one side of the truss and the supported object are supported in a fixed state by the fixed support part, while the opposite corners on the other side of the top surface of the truss body or the bottom corners of the supported object correspond to Since the movable support section interposed between the installation surface and the object to be supported elastically deforms following the above displacement, even when the support point is displaced due to thermal expansion of the object to be supported, the movable support section remains stable. The support end follows the displacement of the support point and absorbs thermal expansion. Furthermore, since the support end of the movable support section only moves and does not slip, there is no wear and tear, and the original design base can be maintained over a long period of time.Therefore, maintenance is free during many years of operation, and the horizontal force generated during thermal expansion is also small. The weight of the support frame can be reduced.

[Brief explanation of drawings]

Fig. 1 is a system diagram showing an example of an exhaust heat recovery type combined cycle power generation plant, Fig. 2 is a plan view of a conventional support frame, Fig. 3 is a side view of the same, and Fig. 4 is an embodiment of the present invention. Plan view of the support frame according to 5th
This figure is a side view of the same, and FIG. 6 is a perspective view showing one of the truss units. 3... Heat exchanger, 16 ₁ , 16 ₂ , 16 ₃ , 16 ₄ ,
16 ₅ ...Truss unit, 16...Truss body, 2
3... Fixed support part, 25... Pillar, 26... Hinge, 2
7...Movable support part.

Claims (1)

[Scope of Claims] 1. In a support frame that is placed on a horizontal installation surface and supports a supported object by placing it on the upper surface side, the support frame is provided with: A truss body consisting of a plurality of box-shaped truss units, each of which has the same shape, connected horizontally so as to have a commensurate size, and opposing corners on one side of the top surface of the truss body. a fixing support part provided at each of the parts and supporting the supported object in a fixed state; and a fixed support part provided at each of the mounting surfaces corresponding to the opposing corners on the other side of the top surface of the truss main body or the corner of the bottom part of the supported object. and a movable support part whose support end is fixed to the bottom of the supported object and elastically deforms when the bottom of the supported object is displaced in the horizontal direction due to thermal expansion, following this displacement. Characteristic support structure.