PL223560B1 - Method for building a boiler installation - Google Patents

Abstract

[Problem] The present invention relates to a large-size boiler and the construction of a building therefor, and the purpose of the present invention is to provide a method for constructing a boiler facility, the method being capable of reducing the time until a boiler is installed. [Solution] A method for constructing a boiler facility is characterized in that the method comprises: a main column installation step in which main columns (14) located at four places of a boiler building are installed; a large-beam installation step in which, after the main column installation step, large beams (22) are lifted and affixed between the main columns (14) by jack devices (40) provided to the upper portions of the main columns (14); a boiler installation step in which, after the large-beam installation step, a boiler body (30) is lifted and affixed through the jack devices (40) provided to the large beams (22); and a floor unit installation step in which, in parallel with both the large-beam installation step and the boiler installation step, a floor unit (14a) forming each floor of the main columns (14) is lifted and affixed by the jack devices (40) provided to the upper portions of the main columns (14).

Description

Description of the invention

The present invention relates to the construction of a large-size boiler and a building thereof, and more particularly to a method of constructing a boiler plant, allowing the construction time to be reduced for installing the power plant boiler in a building while hanging in the building.

Large-size boiler used in thermal power plant and the like expands due to heating. Thus, the boiler is constructed to hang from a structure, known as a gable girder, located in the ceiling of the power plant building. In order to construct a boiler having this type of construction, it is essential to improve the operational safety and to shorten the construction time.

A thermal power plant having a boiler essentially comprises side-span girders positioned in the side wall of the building and provided with pipes and the like, a gable girder located across a pair of side girders, and a boiler main body suspended from the gable girder.

In related prior art solutions, a thermal power plant having such a configuration is constructed as shown in Fig. 7. That is, after placing the main columns in the four directions, the side-span framers are assembled in one section, the storey unit is installed and the pipes are inserted into the span framers. the side and main columns of the assembled section. This operation is repeated as many times as sections are required to complete the side-span frame beams (steps 1 to 5). The gable girder running across the side-span frames is then lifted and attached to the upper parts of the side-span frames (step 6). The boiler then rises relative to the gable girder. Here, the boiler is divided into many units (three in Fig. 7). Lifting and installing the boiler can be done simultaneously by assembling the lower unit in sequence while the upper unit is lifted (steps 7 to 9). A thermal power plant assembled in this way is disclosed, for example, in Patent Document 1.

A building method to reduce the building time of a thermal power plant having such a configuration is disclosed in Patent Document 2. According to the building method disclosed in Patent Document 2, the four main columns included in the side-span frame frame are first erected. Then a floor module is placed between the main columns by assembling the floor unit, pipes and the like. In this case, each floor module is pre-assembled at the factory, then lifted and installed in a predetermined position using a crane at the top located at the top of the main column. In addition, a connecting element is placed between the main columns to prevent the side-bay frame frame from falling.

Then the boiler module is lifted with the use of a crane located in the upper part of the main column. The boiler module disclosed in Patent Document 2 is a separate module comprising an upper module having a top girder used to suspend the boiler and upper boiler unit, and a lower module having a lower boiler unit. In this case, both the upper and lower modules are loaded when assembled at the factory.

List of cited publications

Patent literature

Patent document 1: Japanese patent publication, 2927320

Patent Document 2: Japanese Unexamined Patent Publication No. 2002-213707

When building a thermal power plant, the connecting element or pipes are connected taking into account the condition of the boiler system. For this reason, it is foreseen that the total build time can be shortened if the installation time of the boiler can be reduced.

In view of the above-mentioned problems, the object of the present invention is therefore to provide a method of constructing a boiler installation, relating to the construction of a large-size boiler and its building, which allows to shorten the installation time of the boiler.

The method of constructing a boiler system according to the invention is characterized in that it comprises the process of installing a main column of a plurality of columns in which the main column of the boiler building is installed, and the side-span frame frame comprising the main girder in such a way that the main girder is connected to a pair of main columns. selected from the four main columns, and the front frame is connected to the side-span frame. The method of the invention further comprises a girder installation process in which the gable girder rises and is secured between the main columns using a plurality of lifting devices positioned at the top of the main column after the main column installation process. The method of the invention further comprises a process of installing a boiler with which the main body of the boiler is lifted and secured by means of a plurality of lifting devices arranged in the girder after the girder installation process. Finally, the method of the invention includes a storied unit installation process in which the storied unit contained in each storey of the main column is lifted and secured by a plurality of lifting devices arranged at the top of the main column, simultaneously with the girder installation process and the boiler installation process.

Preferably, in the process of installing the story unit, each floor unit is lifted and installed on the target floor by carrying out the connecting process of the bar of the lifting device and the uppermost story unit and lifting the floor unit, and then repeatedly connecting the next floor unit which is located on the lower floor. layer, under the raised floor unit, using a temporary hanger element and by lifting the floor unit.

Preferably, the process of installing the floor unit is completed before the process of installing the boiler is completed.

Preferably, in the process of installing the main column, simultaneously with the process of installing the story unit, the rear framing is installed, which faces the front framing and connects to the side-span fram.

Preferably, some or all of the lifting devices are used together in each of the girder installation process, the boiler installation process and the story unit installation process.

Preferably, the elevator device used in common with each of the processes moves in the course of the other process after each of the processes has ended.

Preferably, the bars of the lifting devices used in the girder installation process, the boiler installation process and the story unit installation process are of equal size and used together.

Preferably, the outdoor crane is used in the main column installation process and then removed after the main column installation process, and the girder installation process, the boiler installation process and the story unit installation process use a lift apparatus.

In accordance with one aspect of the present invention, there is provided a method of constructing a boiler plant, comprising: a main column installation process in which the main column of a boiler building is installed; a girder installation process in which the gable girder rises and is secured between the main columns using a plurality of lifting devices located at the top of the main column after the main column installation process; a boiler installation process in which the boiler main body is raised and secured using a plurality of lifting devices placed in the gable after the girder installation process; and a storied unit installing process in which the storied unit included in each tier of the main column is lifted and secured by a plurality of lifting devices located at the top of the main column, simultaneously with the girder installing process and the boiler installation process.

In the above-described method of building a boiler plant, the process of installing the floor unit can be carried out such that each floor unit is lifted and installed on the target floor by carrying out the connecting process of the lift device rod and the uppermost floor unit and lifting the floor unit, and then carrying out the connecting process repeatedly. another story unit that is located in the lower layer, under the raised story unit, using a temporary hanger element and by lifting the story unit. As a result, the frequency of the lifting process with the use of lifting equipment can be reduced when the storey unit is installed. Moreover, it is not necessary to move the lifting device itself in order to lift the story unit of the lower tier.

In the above-described method of building a boiler system, the process of installing the floor unit can be completed before the process of installing the boiler. If during this time the process of installing the floor unit is completed, then the general processes come to an end when the boiler installation process is complete. Thus, the total construction time for construction work can be reduced as many processes are carried out simultaneously.

In the above-described method of building a boiler plant, in the process of installing the main column, a beam or frame can be installed to prevent the main column from falling down.

PL 223 560 B1

As a result, when a gable girder with a relatively high weight is lifted, the center of the side-span frame frame can be prevented from collapsing.

In the above-described method of constructing a boiler plant, some or all of the lifting devices may be used jointly in each of the girder installation process, the boiler installation process and the story unit installation process. As a result, it is not necessary to lift or lower consecutively inactive lifting devices or lifting devices for which work is planned between the top of the building and the ground. For this reason, the time required for lifting, lowering or deploying lifting equipment can be reduced.

The elevator apparatus used in common in each of these processes may be moved in the other process after each of the processes has been completed. As a result, the time required to move the lifting device itself can be eliminated and the time required to complete each process can be shortened.

In the above-described method of constructing a boiler plant, the bars of the lifting devices used in the girder installation process, the boiler installation process and the story unit installation process can be of equal size and used together. As a result, you can facilitate the management of the bars and reduce the number of non-working bars by using the bars together. Thus, the overall number of member uses can be limited.

In the above-described method of building a boiler plant, an external crane can be used in the main column installation process, and it is removed after the main column installation process, and in the gable girder installation process, boiler installation process and floor unit installation process, a lifting device can be used. As a result, compared to the solutions known from the prior art, the use time of the external crane can be reduced. Thus, it is possible to reduce the construction cost necessary for the use of an external crane and reduce construction costs for all construction works.

In the above-described method of constructing a boiler system for building a large-size boiler and its building, the construction time for installing the main body of the boiler can be reduced. For this reason, the build time to build the entire boiler system can also be shortened.

An embodiment of the invention will now be described with reference to the drawing figures, in which Fig. 1 is a front view showing an exemplary boiler plant constructed using a method of building according to an embodiment; Fig. 2 is a side view showing an exemplary boiler plant built using a construction method according to an embodiment; Figures 3-1 is a schematic front view showing each process of the method of building a boiler system according to the embodiment; Figures 3-2 is a schematic plan view showing each process of the method of building a boiler system according to the embodiment; Fig. 4 is a perspective view showing a particular example of a process for installing a storey unit according to an embodiment; Fig. 5 is a diagram comparing the flow of a building process for a building method for a related prior art and the flow of a building process according to an embodiment; Fig. 6 is a diagram showing a schematic configuration of an elevator system used to implement the method of constructing a boiler installation according to the embodiment; Fig. 7 is a diagram showing each process of the boiler plant building method of the related art.

The method of constructing a boiler plant according to an embodiment of the invention will be described in detail below with reference to the accompanying drawings.

First, with reference to Figures 1 and 2, a schematic configuration of an exemplary boiler plant constructed in accordance with the present embodiment will be described. Fig. 1 is a diagram showing a front side configuration of a boiler line and Fig. 2 is a diagram showing a side configuration of a boiler line.

The boiler plant 10 comprises a boiler building 12 and a boiler main body 30 installed in the boiler building 12. The boiler building 12 comprises a side-span frame 20 contained in the side wall where pipes and the like (not shown) are installed, a front frame 16 which prevents the collapse of the side-span frame 20, a rear frame 15 (see Figs. 3-2), gable girder 22, frame girder 24 and the like. The side-span frame 20 comprises 4-6 main columns 14, installed in 4-6 directions of the building, and a main girder 18, contained in the side wall and installed by joining a pair of main columns of four main columns 14. Main columns 14 are formed by four columns 13. In addition, the frame 20 of the side span

The PL 223 560 B1 is divided into a plurality of layers with a story unit 14a or pipes (not shown) installed in each layer.

The front frame 16 is a beam placed between the pair of the frame frames 20 of the side spans to form the front wall of the boiler building 12. The front frame member 16 counteracts the side-span frame 20 from falling inwards (in the opposite direction) when a heavy material, such as the gable girder, is lifted onto the side-span frame frame 20. The rear framing 15 is a beam that faces the front framing 16 described above and is included in the rear wall of the boiler house.

The gable girder 22 is a beam connected to a connector 21 located at the upper end of the main column 14 contained in the side-span frame frame 20 and guided through the upper ends of the pair of side-span frames 20. As shown in Figures 3-1, the connecting surface between the connector 21 and the gable girder 22 is inclined for use in the building method disclosed in Japanese Patent Publication No. 3389839. A plurality of small beams, called support frames 24, run towards the anterior-rear of the boiler building 12. below the girder girder 22. The boiler main body 30, which will be described in detail below, is suspended from the support frame 24 from the gable girder 22.

The boiler main body 30 is suspended from a support frame 24 installed with respect to the gable girder 22. The boiler main body 30, according to an embodiment, comprises a plurality of units. In addition, in the example of Figures 1, 2, 3-1 and 3-2, three units (upper unit 32, middle unit 34 and lower unit 36) are shown for simplicity.

In the following, a method of constructing a boiler system 10 will be described with reference to Figs. 3-1 and 3-2 having such a configuration. Fig. 3-1 is a diagram showing the configuration from the front, and Fig. 3-2 is a diagram showing the configuration from above.

First, first and second sections of main columns 14, including multiple layers, are installed (the four sections in the example in Figs. 3-1 and 3-2). When the main columns 14 of the second section are installed, the main girder 18 and the front frame 16 are installed between the main columns 14 of the first section. The works for installing the main columns 14 and the works for installing the main girder 18, front frame 16 and rear frame 15 are performed using an external crane (not shown), located close to the construction site of the boiler building.

Then the third and fourth sections of the main column 14 are installed. When the third section is installed, the main girder 18 and the front frame 16 are installed between the main columns 14 of the second section. When the fourth section is installed, the main girder 18 is installed between the main columns 14 of the second section and front frame 18 (step 2). In addition, after the installation of the fourth section of the main columns 14 is completed, the main girder and front frame 16 are installed between the main columns 14 of the fourth section.

A connector 21 is mounted at the upper end of the main column to serve as a base for securing the gable 22, the lifting device 40 for lifting the gable 22 or a storied unit 14a is lifted to the upper end of the main column 14. After lifting of the lifting device 40 is completed, the unit is lifted. of floor 14a and the installation begins (step 3: floor unit installation process). In the process of installing a story unit as shown in Fig. 4, lifting is carried out while the story units 14a arranged in the lower layers are sequentially attached to the story units 14a located in the upper layers. In particular, the bar 40a of the lifting device 40 located in the upper part of the main column 14 is connected to the uppermost part (the story unit 14a located in the uppermost layer) and carries out the lifting process. After the story unit 14a located in the uppermost tier has been lifted to a predetermined height (e.g., between the tiers), the story unit 14a located in the lower tier is positioned beneath the story unit located at the uppermost part such that the story unit 14a located in the upper tier is and the story unit 14a located in the lower tier are connected to each other by a temporary hanger element 50. The story units 14a connected vertically using a temporary hanger element 50 are further raised to a predetermined height. Thereafter, the floor unit 14a located in the lower tier is positioned and connected using a temporary hanger element. This inter-layer bonding and lifting process is carried out repeatedly until each of the floor units 14a is lifted and installed on the target floor. Furthermore, after the installation of each of the story units 14a is completed, the temporary hanger element used to connect the story units 14a to each other is removed.

PL 223 560 B1

Any material or shape may be used in the temporary hanger element as long as it provides the integrity to suspend the story unit 14a. For example, wire or chain can be used.

When the lifting process is performed for each story unit 14a of each layer, it is necessary to move the lifting apparatus 40 to lift the story unit 14a of each layer, whereby the frequency of the lifting process is also increased. In the building method of the embodiment, the lifting process is performed once (in one set of target story units 14a). Thus, the time it takes to raise or lower the bar 40a can be significantly reduced. Moreover, a plurality of target story units 14a can be lifted without moving the elevator device 40. Thus, the time required for the movement of the elevator device 40 can be reduced.

Simultaneously with the process of installing the floor unit, the installation of the rear frame 15 is carried out (the process of installing the main column). After the main girder 18, the front frame 16 and the rear frame 15 have been installed, the outer crane (not shown) is removed. Moreover, simultaneously with the process of installing the floor unit for lifting and installing the floor units 14a, the gable girder 22 is installed. According to the present embodiment, the lifting device 40 is used jointly in the process of installing the floor unit and in the process of lifting the gable 22 or main body 30 of the boiler. which processes are carried out simultaneously. As a result, lifting apparatus 40 can be jointly used in each of the processes, and the time required to raise or lower the idle lifting apparatus in operation is reduced.

For this reason, after the story units 14a are fully installed in the main columns 14, the lifting device 40 is moved to the upper end of the main girder 18 or the gap between the installed gable girders 22 in order to prepare for lifting work in the next process. To move the lifting device 40, a crane may be used, such as a boom crane (not shown), located at the upper end of the main column 14 (step 4: gable installation process).

After lifting the gable 22, he installs the frame girder 24 (see Figures 1 and 2). By means of the above-described stage installation process, the boiler main body 30 is lifted by means of a lifting device 40 placed in the upper part of the gable girder 22. The boiler main body 30 is lifted in such a way that the segmented boiler units are raised sequentially and assembled. For this reason, a plurality of lifting devices 40 are required to lift the units, whereby a further lifting device 40 is used for lifting if necessary. In the example of Figs. 3-1 and 3-2, six lifting devices 40 were added after the gable installation process, resulting in a total of thirty-two lifting devices 40 in the top of the boiler building 12. However, according to the invention, the number of lifting devices 40 is not limited.

The lifting of the boiler main body 30 is integrated in an integrated manner from the upper side of the unit. In the example of Figs. 3-1 and 3-2, in step 5, while lifting the auxiliary module (such as the upper unit 32), the lifting device 40 is prepared to lift the reheater module (such as the middle unit 34).

Then the reheater module rises. Simultaneously with the work of lifting the reheater, the lifting device 40 used to raise the auxiliary module and the lifting device 40 used to raise the floor unit 14a move to raise the air box (step 6).

After the air box is raised, simultaneously with the reheater lifting process, the lifting device 40 moves to raise the superheater module (e.g., lower unit 36). The main body 30 of the boiler is raised to be suspended from the gable 22 or frame 24 (step 7: boiler installation process).

In a boiler plant 10 constructed in this way, the build time can be significantly reduced compared to the related prior art as shown in Fig. 5. In a related art, installation of the main column and installation of the storied unit are performed sequentially and repetitively for each section (layer) in the art. to form the main columns and side frames of the spans. Then it rises and installs the gable girder. On the contrary, in the method of constructing a boiler plant according to the present embodiment, the installation of the main columns 14 (installation of the frame frame 20 of the side span without considering the story unit 14a) is carried out in advance. Moreover, the installation of the story unit 14a in each section is carried out simultaneously with the lifting of the gable 22 or the main body 30 of the boiler. Thus, the total build time can be shortened. Specifically, in the related art process, the time required to install a floor unit takes about 1/4 of the total building time even using the dump building method using the story unit in the main column. Conversely, in the building method of the present embodiment, the time required to install a story unit increases, but the total building time is reduced to about 3/4 compared to the related prior art method by running this building process simultaneously with another building process, such as lifting the main body 30 of the boiler.

By reducing the construction time, you can reduce the cost of construction and the time involved. Moreover, the order in which the boiler main body is lifted, the number of lifting devices 40 used for lifting, or the like may be appropriately changed depending on the particular application.

In the method of constructing a boiler system according to the present embodiment, after assembling the girder frames such as main girder 14, main girder 18, front framing 16 and rear framing 15 using an external crane 5 (not shown), the external crane is removed. The story unit 14a is then installed using a lifting device 40 located in the main column 14 or the like. Thus, you can shorten the time of using an external crane and reduce the cost of construction.

Moreover, in the method of constructing a boiler plant according to the present embodiment, the story unit 14a of the side-span frame frame 20 or each boiler main body 30 unit near the ground may be assembled. Thanks to this, it is possible to limit the scope of dangerous works performed by the operator at height and increase the safety of construction works.

Moreover, in the method of constructing a boiler plant according to the present embodiment, the lifting device 40 is used jointly when lifting the storied unit 14a or log girder 22 and when lifting the main body 30 of the boiler. Thus, the elevator apparatus 40 may be shared between these processes. In this way, the time required for the subsequent lifting or lowering of lifting devices 40 which has already been in operation or lifting devices 40 which are yet to be operated can be reduced.

In the lifting devices 40 used in the method of constructing a boiler plant according to the present embodiment, the console 60, the pump units 42, and the lifting devices 40 form a lifting unit as shown in Figure 6. Each pump unit 42 is configured to receive a signal from the console 60 and operate individually. to supply hydraulic fluid to each lifting apparatus 40 in response to a signal.

By using such a lifting unit, it is possible to individually adjust the lifting condition of each lifting device and stably lift suspended materials in a horizontal position or in an inclined position.

While each of the lifting devices 40 shown in Figs. 3A and 3B individually has a pump unit 42, a pump unit 42 may be provided in any set of synchronously operating lifting devices. In such a case, a manifold (distributor), regulating valve and the like may be provided between the pump unit 42 and the lifting device 40 to divide and regulate the flow of the hydraulic fluid. As a result, each lifting apparatus 40 can be individually controlled.

While it is indicated in the illustrated embodiment that the lifting devices 40 can be added as needed, the lifting devices 40 can be lifted in advance to the face required for all construction work, as long as a free space is available at the top of the boiler building 12. As a result, the work of lowering additional lifting devices to the ground or lifting the necessary lifting devices during the building construction process can be eliminated.

In the above-mentioned embodiment, the bars 40a of the lifting devices 40 used in the girder installation process, the boiler installation process and the installation process of the storey units are of the same size in length or diameter, and are used together in each process. As a result, the need to arrange multiple types of bars 40a in the top of the boiler building 12 can be avoided, and the number of non-working bars can be reduced. Obviously, the size of the bar 40a used may vary when heavy materials such as the boiler main body 30 are lifted and when relatively light materials are lifted.

With a heavy load, such as a floor unit 14a. In some cases, the construction cost may be further reduced by using a small diameter bar rather than increasing the number of large diameter bars. In this case, when additional measures such as a spacer are introduced into the lifting device, only the size of the bar can be changed, while the lifting device 40 is used jointly.

Explanation of letters and numbers 10 boiler system boiler building column main column

14a floor unit rear frame frame front frame frame main girder side-span frame frame gable girder support frame bearing main body boiler upper unit middle unit lower unit lifting device pump unit temporary suspension element (60a, 60b) console

Claims (8)

Patent claims 1. The method of building a boiler installation, characterized in that it includes: the process of installing a main column (14) consisting of multiple columns (13), in which the main column (14) of the boiler building (12) is installed, and the side-span frame (20) containing the main girder (18) in such a way that the main girder (18) is connected to a pair of main columns (14) selected from the four main columns (14), and the front frame (16) is connected to the side-span frame (20); the girder (22) installation process in which the top girder (22) rises and is secured between the main columns (14) using a plurality of lifting devices (40) placed at the top of the main column (14) after the main column (14) installation process ; a boiler installation process in which the boiler main body (30) is raised and secured by a plurality of lifting devices (40) positioned in the girder (22) after the girder (22) installing process; and a process for installing the story unit (14a) in which the story unit (14a) contained in each story of the main column (14) is lifted and secured by a plurality of lifting devices (40) located at the top of the main column (14) simultaneously with the process of installing the gable girder (22) and the process of installing the boiler. 2. The method according to p. 5. A method as claimed in claim 1, characterized in that in the process of installing the story unit (14a) each floor unit (14a) is lifted and installed on the target story by carrying out a joining process of the rod (40a) of the lift device (40) and the uppermost story unit (14a) and lifting a floor unit (1 4a), and then repeatedly carrying out the process of attaching another floor unit (14a) that is located in the lower layer, under the raised story unit, using a temporary suspension element (50) and by lifting the floor unit (14a) ). 3. The method according to p. A process as claimed in claim 1 or 2, characterized in that the process of installing the storey unit (14a) is completed before the process of installing the boiler is completed. 4. The method according to any one of claims 1 to 4 3. The method of 1 to 3, characterized in that in the process of installing the main column (14), simultaneously with the process of installing the storey unit (14a), the rear fixture (15) is installed, which is directed towards the front frame frame (16) and connects with the frame of the side span (20). 5. The method according to any one of claims 1 to 5 A process as claimed in any one of claims 1 to 4, characterized in that some or all of the lifting devices (40) are used together in each of the girder (22) installation process, the boiler installation process and the storey unit installation process (14a). 6. The method according to p. 5. The process of claim 5, characterized in that the elevator device (40) used in common in each of the processes moves during the different process after each of the processes has ended. 7. The method according to any one of claims 1 to 7 A method as claimed in any one of claims 1 to 6, characterized in that the bars (40a) of the lifting devices (40) used in the girder (22) installation process, the boiler installation process and the story unit installation process (14a) are of equal size and used together. 8. A method according to any one of claims 1 to 8 The method of any of claims 1 to 7, characterized in that the external lift is used in the process of installing the main column (14) and then it is removed after the installation process of the main column (14), and in the process of installing the gable girder (22), the process of installing the boiler and the installation process In the story unit (14a), a lifting device is used.