KR101601451B1 - Method for installing pressure part panel of a boiler in a thermal power plant and steel frame structure of a boiler therefor - Google Patents

Abstract

The present invention relates to a method for installing a pressure part panel of a boiler for thermal power generation, comprising a pair of vertical members provided in parallel with each other, an intermediate member provided between the vertical members, And a reinforcing member for supporting the lower end of the intermediate member to form an entrance and an entrance for allowing the pressure part panel to enter, thereby improving workability for assembly of the pressure part panel, shortening the assembling time of the pressure part panel, The construction period of the entire sub-panel can be shortened.

Description

TECHNICAL FIELD The present invention relates to a method of installing a pressure-side panel of a boiler for thermal power generation, and a steel frame structure of the boiler,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a boiler of a thermal power plant and a construction method thereof, and more particularly, to a method of installing a pressure part panel of a boiler for thermal power generation and a steel structure of a boiler for the boiler.

Generally, a turbomachine such as a steam turbine or a gas turbine is used as a power generating device for converting thermal energy of a fluid into rotary power, which is a mechanical energy, for thermal power generation.

Steam turbines generate electricity by rotating a generator by connecting a high pressure (HP) turbine, a medium pressure (IP) turbine, and a low pressure (LP) turbine in series or in parallel. Will be different. A steam turbine is driven to generate a boiler for generating steam at high temperature and high pressure.

1 to 3, a boiler for thermal power generation is provided with a plurality of pressure part panels P inside a steel structure 101, generates a thermal power from a lower part of the pressure part panel P, The panel P is heated. The pressure part panel P is formed by bending a tube through which water passes, and the water in the tube is heated by the thermal power and steamed, and then supplied to the rotor blades of the turbine.

The steel structure 101 includes a plurality of vertical members 110 arranged parallel to each other and horizontal members 130 connecting the vertical members 110.

A plurality of pressure part panels P are installed inside the steel structure 101. As shown in Fig. 1, each pressure-side panel P incorporates materials and equipment inside a steel frame structure. When assembling is completed, the rope R is connected to one end of the pressure part panel P as shown in FIG. 2 to FIG. 3, lifted up by the lifting mechanism and vertically installed and moved to the installation position.

However, there is a space limitation in assembling the pressure part panel P in the inside of the steel frame structure 101, which results in a problem that the workability is low and the assembling time is long.

On the other hand, in the inside of the steel frame structure, the work space is narrow, and a large number of assembly materials and equipments are introduced, and a plurality of pressure part panels P can not be assembled at the same time. Therefore, the entire pressure sub-panel P is installed in such a manner that one pressure sub-panel P is assembled and installed at a time, and another pressure sub-panel P is assembled again. Thus, it takes a lot of time to install the entire pressure unit panel P.

The present invention has been made in order to solve the problems of the conventional method of installing the pressure part panel of the boiler for thermal power generation and the steel structure of the boiler for the same, And it is an object of the present invention to provide a method of installing a pressure unit panel of a boiler for thermal power generation that can shorten the assembling time of the panel and shorten the construction period of the boiler.

In order to achieve the above object, a steel structure of a boiler for thermal power generation according to the present invention comprises a pair of vertical An intermediate member provided between the vertical member and the vertical member in parallel with the vertical member, a horizontal member connecting the pair of vertical members and the intermediate member, and a vertical member interposed between the pair of vertical members, And a reinforcement member which is provided in the direction of the pressure member panel and forms an entrance for allowing the pressure member panel to enter, and supports the lower end of the intermediate member.

The reinforcing member includes a first reinforcing member having one end coupled to one of the vertical members and the other end coupled to a lower end of the intermediate member and a second reinforcing member having one end coupled to the other vertical member and the other end coupled to the lower end of the intermediate member, And a second reinforcing member provided at a predetermined angle? With the first reinforcing member.

Preferably, the first reinforcing member and the second reinforcing member satisfy 60 degrees < alpha < 130 degrees.

The steel structure of a boiler for thermal power generation according to an embodiment of the present invention is characterized in that the steel structure of the boiler for thermal power generation has a structure in which one end is coupled to the vertical member and the other end is coupled to the lower end of the intermediate member, 1 supporting member.

The steel structure of the boiler for thermal power generation according to an embodiment of the present invention may further include a second support member having one end coupled to one side of the reinforcing member and the other end coupled to the vertical member.

The steel structure of the boiler for thermal power generation according to an embodiment of the present invention may further include a reinforcing support member having one end coupled to one side of the first reinforcing member and the other end coupled to one side of the second reinforcing member .

In order to achieve the above object, a method of installing a pressure part panel of a boiler for thermal power generation according to the present invention comprises assembling the entire pressure part panel outside a steel structure of a boiler, Moving the pressure sub-panel to the inside of the steel frame structure through an entrance of the steel structure, and moving the pushing panel to the inside of the steel structure, And a step of arranging the same in line with the intermediate member.

The method of installing a pressure part panel of a boiler for thermal power generation according to an embodiment of the present invention further includes the step of connecting a rope to one end of a pressure part panel transferred to the inside of the steel frame structure and lifting the rope to a mounting position .

In the pressure assembly panel assembling step, it is also possible to assemble a plurality of pressure part panels at the same time and to move the plurality of pressure part panels successively into the inside of the steel frame structure, and then lift them.

As described above, according to the method of installing the pressure part panel of the boiler for thermal power generation and the steel frame structure of the boiler according to the present invention, since the pressure part panel is assembled from the outside of the steel structure, It is possible to shorten the assembling time of the pressure part panel.

Further, according to the present invention, a plurality of pressure part panels are simultaneously assembled from the outside, and a plurality of pressure part panels having been assembled are continuously lifted into the inside of the steel frame structure, so that the construction time of the entire boiler can be shortened .

1 is a schematic perspective view showing a steel structure of a boiler for thermal power generation according to the prior art,
FIG. 2 to FIG. 3 are schematic perspective views illustrating a process of installing a pressure unit panel of the boiler for thermal power generation shown in FIG. 1;
4 is a schematic perspective view illustrating a steel structure of a boiler for thermal power generation according to an embodiment of the present invention,
Fig. 5 is a front view of Fig. 4,
6 to 7 are front views showing a steel structure of a boiler for thermal power generation according to another embodiment of the present invention,
8 is a flowchart illustrating a process of assembling a pressure unit panel of a boiler for thermal power generation according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 to 5, a steel structure of a boiler for thermal power generation according to an embodiment of the present invention includes a pair of vertical members 10 provided parallel to each other, a pair of vertical members 10 A horizontal member 30 connecting the pair of vertical members 10 and the intermediate member 20 and an inlet 40 for allowing the pressure unit panel P to enter, And a reinforcing member for supporting the lower end of the intermediate member 20.

As shown in FIG. 4, the steel structure 1 is a skeleton of a boiler, and is formed as a whole by a plurality of vertical members 10 and horizontal members 30. The vertical members 10 are each provided with vertical members 10 at four corners in a rectangular frame structure, and vertical members 10 are also provided between the corners. The vertical members 10 are vertically provided on the floor and are provided parallel to each other. The vertical members 10 are connected to each other by horizontal members 30. The horizontal members 30 are provided orthogonally to the vertical member 10 and are provided at a predetermined interval along the longitudinal direction of the vertical member 10. The frame structure of the square frame has four side surfaces, and an entrance (40) through which the pressure part panel (P) enters is formed on one of the side surfaces.

The side surface on which the entrance 40 is formed is composed of a pair of vertical members 10, a plurality of horizontal members 30, an intermediate member 20 and a reinforcing member. Hereinafter, a limited description of members constituting the side surface on which the entrance 40 is formed is shown.

An entrance (40) through which the pressure part panel (P) enters and exits is formed between the pair of vertical members (10). Therefore, the pair of vertical members 10 are provided with a gap larger than the size of the pressure part panel P.

The entrance (40) is formed by a reinforcing member. The reinforcing member is composed of a first reinforcing member 41 and a second reinforcing member 42 forming both sides of an isosceles triangle forming a predetermined angle alpha with respect to each other. A horizontal member 30 and an intermediate member 20 are coupled together at a portion where the first reinforcing member 41 and the second reinforcing member 42 are connected.

The first reinforcing member 41 and the second reinforcing member 42 are provided in the direction transverse to the vertical member 10 and have an angle of? / 2 with respect to the vertical member 10 and the intermediate member 20, respectively Respectively. The first reinforcing member 41 and the second reinforcing member 42 have an angle of 90 deg. -? / 2 with respect to the horizontal member 30.

One end of the first reinforcing member 41 is coupled to one of the pair of vertical members 10 and the other end is coupled to the lower end of the intermediate member 20. One end of the second reinforcing member 42 is coupled to the other vertical member 10 and the other end is coupled to the lower end of the intermediate member 20.

The intermediate member 20 is supported by the first reinforcing member 41, the second reinforcing member 42 and the horizontal member 30. That is, the first reinforcing member 41 and the second reinforcing member 42 support the intermediate member 20 by being inclinedly coupled with the lower end of the intermediate member 20 at a predetermined angle? The member 30 is also coupled to the lower end of the intermediate member 20 across the intermediate member 20 to thereby support the intermediate member 20. As described above, since the intermediate member 20 is supported by the first reinforcing member 41 and the second reinforcing member 42, it is possible to prevent the intermediate member 20 and the horizontal member 30 from sagging, 20 can be supported. In addition, the pressure part panel P can be taken in and out through the entrance 40 formed by the first reinforcing member 41 and the second reinforcing member 42.

The supporting force of the first reinforcing member 41 and the second reinforcing member 42 depends on the angle? Between the two members. The greater the angle?, The smaller the supporting force for supporting the intermediate member 20 is. It is preferable that the first reinforcing member 41 and the second reinforcing member 42 satisfy 60 degrees <? <130 degrees. When the angle? Is larger than 130 degrees, the supporting force for supporting the intermediate member 20 becomes remarkably small, so that sagging can not be prevented. In contrast, when the angle? Is smaller than 60 degrees, the height of the entrance 40, that is, the lower end of the intermediate member 20 becomes significantly higher from the bottom, There is a fear that the overall structural stability of the steel structure may be impaired. The first reinforcement member 41 and the second reinforcement member 42 and the intermediate member 20 are combined so that the lower limit of the angle 留 is 130 占 with the first reinforcement member 41 and the second reinforcement member 41, It is desirable to add members for strengthening the coupling force and the supporting force of the intermediate member 42 and the intermediate member 20.

To this end, as shown in Fig. 6, a first support member 51, a second support member 52, and a reinforcement support member 53 are provided.

The first support member 51 has one end coupled to the vertical member 10 and the other end connected to the lower end of the intermediate member 20 and having an angle? do. The lower end of the first support member 51 is coupled to the lower end of the intermediate member 20 and the upper end of the first support member 51 is coupled to the engagement portion of the vertical member 10 and the horizontal member 30, 1 support member 51 supports the intermediate member 20.

One end of the second support member 52 is coupled to one side of the one reinforcing member or the second reinforcing member 42 and the other end is coupled to the vertical member 10. [ The lower end of the second support member 52 is coupled to the center of the first reinforcement member 41 or the second reinforcement member 42 and the upper end of the second support member 52 is connected to the horizontal member 30 and the vertical member 10 So that the second support member 52 supports the first reinforcement member 41 and the second reinforcement member 42.

The reinforcing support member 53 is provided between the first reinforcing member 41 and the second reinforcing member 42. One end of the reinforcing support member 53 is coupled to one side of the first reinforcing member 41 and the other end is coupled to one side of the second reinforcing member 42. The reinforcing support member 53 is provided between the first reinforcing member 41 and the second reinforcing member 42 so as to be removed in order to install a brace member 60 described later.

7, after the pressure part panel P is moved into the inside of the steel frame structure, since the entrance 40 is a passage for the pressure part panel P to enter, The member 60 is installed. When the reinforcing and supporting member 53 is installed, the reinforcing and supporting member 60 is installed.

The stiffening member 60 is provided on the same line as the intermediate member 20 to support the intermediate member 20 against the floor.

Hereinafter, a method of installing a pressure unit panel of a boiler for thermal power generation according to an embodiment of the present invention will be described.

First, the pressure part panel P is assembled from the outside of the steel structure of the boiler (S10). Here, since the pressure part panel P is assembled from the outside of the steel structure 1, the work space is not limited and the equipment for assembling can be easily accessed. Thus, the workability is greatly improved, Time can be shortened.

In addition, in the pressure part panel assembling step (S20), a plurality of pressure part panels P can be assembled from the outside of the steel structure 1 at the same time. Therefore, compared with the conventional assembling of the pressure part panels P one by one, the assembly time can be remarkably shortened.

Meanwhile, the entrance 40 of the steel frame structure 1 is formed during assembly of the pressure part panel P (S20). That is, in parallel with the assembling step S20 of the pressure part panel P, the steel structure 1 having the entrance 40 is manufactured (S30).

In step S30, the entrance 40 of the steel structure 1 is secured before the pressure part panel P is completely assembled from the outside of the steel structure 1. [ Therefore, when the pressure part panel P is completed, it can be moved to the inside of the steel structure 1 without delay.

When the assembly of the pressure part panel P is completed, the pressure part panel P is moved to the inside of the steel structure 1 through the entrance 40 of the steel structure 1 (S40). To this end, an accessory for transportation such as a rail may be installed at the entrance 40, and these transportation aids must be installed before the assembly of the pressure part panel P is completed. Here, when assembling the pressure part panel P on a conveying auxiliary mechanism such as a rail, the rail installation work must be performed prior to the assembly step (S20).

The pressure part panel P transferred to the inside of the steel structure 1 is lifted to the upper part of the steel structure 1 in step S40. In step S50, as shown in FIGS. 2 to 3, the rope R is connected to one end of the pressure part panel P, lifted up by the lifting mechanism, vertically installed, and then moved to the installation position.

Here, the plurality of pressure part panels P completed on the outside of the steel structure 1 are successively and continuously lifted. That is, after the plurality of pressure part panels P are assembled at once, the lifting work is intensively performed. Therefore, compared with the conventional process of assembling and installing the pressure unit panels P one by one, the time required for lifting all the pressure unit panels P is similar, but the entire pressure unit panel P is assembled The time can be shortened by the time of assembling one.

As shown in FIG. 8, the rear panel, the left panel, the right panel, and the front panel are assembled in this order from the inside of the steel frame structure. In the present invention, the rear panel and the left panel are assembled simultaneously A lifting operation (S50) is performed. It takes 15 days to assemble the rear panel in the conventional steel frame structure. However, when the rear panel is assembled from outside the steel frame structure as in the present invention, workability is improved and assembly can be performed within 12 days. Also, in the conventional art, it takes 12.5 consecutive days to assemble the left panel after assembling the rear panel. In the present invention, since the left panel can be assembled at the same time during assembling the rear panel, .

Particularly, when the two panels are assembled at the same time, for example, when the rear panel and the left panel are assembled at the same time, the assembling time (12 days, 10.5 days) of the rear panel and the left panel are different, (S50), the waiting time for the lifting operation (S50) is shortened. Then, the right panel and the front panel are assembled at the same time and a lifting operation (S50) is performed. At this time, the right panel having a shorter assembly time is assembled and lifted first.

When the lifting installation of all the pressure part panels P is completed, the entrance 40 of the steel structure 1 is removed and the supporting member 60 is installed (S60). Here, step S60 of installing the backing member 60 may be performed while the lifting operation (S50) of the last pressure part panel P is being performed.

In step S60, if there is a reinforcing support member 53, the reinforcing support member 53 is removed. In the case where the reinforcing support member 53 is not provided, the reinforcing member 60 is installed with all the members remaining. That is, the strut member 60 is sandwiched between the first reinforcing member 41 and the second reinforcing member 42 while leaving the first reinforcing member 41 and the second reinforcing member 42 as they are, (20). The stiffening member (60) is provided on the same line as the intermediate member (20).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious that the modification or the modification is possible by the person.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10: vertical member
20: intermediate member
30: Horizontal member
40: Entrance
41: first reinforcing member
42: second reinforcing member
51: first supporting member
52: second supporting member
53: reinforcing supporting member
60:

Claims (9)

In a steel structure of a boiler for thermal power generation in which a pressure part panel is installed,
A pair of vertical members provided parallel to each other with an interval larger than that of the pressure unit panel so that the pressure unit panel can be taken in and out;
An intermediate member disposed between the vertical members in parallel with the vertical members;
A horizontal member connecting the pair of vertical members and the intermediate member;
A first reinforcing member coupled to the lower end of the intermediate member having one end connected to the horizontal member and diagonally connected to one of the vertical members at the other end, And
A second reinforcing member connected to the lower end of the intermediate member connected at one end thereof to the lower end of the intermediate member so as to be coupled to the other vertical member so as to be coupled to the other vertical member and having a predetermined angle 留 with the first reinforcing member, absence;
The steel structure of the boiler for thermal power generation. delete 2. The apparatus according to claim 1, wherein the first reinforcing member
60 degrees < alpha < 130 degrees. The method according to claim 1,
Further comprising a first support member having one end coupled to the vertical member and the other end coupled to a lower end of the intermediate member and having an angle? Between the intermediate member and an acute angle, Steel structure of boiler for. The method according to claim 1,
And a second support member having one end coupled to one side of the reinforcing member and the other end coupled to the vertical member. The method according to claim 1,
And a reinforcing support member having one end coupled to one side of the first reinforcing member and the other end coupled to one side of the second reinforcing member.
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