JP2012111599A - Processing method for adhered material, installation method for partition, and partition - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a processing method for an adhered material for easily dividing, in a sealed manner, the inside of a hollow structure in which at least three lifting spaces are set in parallel from side to side in a horizontal direction, and processing the adhered material, etc.SOLUTION: The processing method for adhered material for processing an adhered material in the inside of the hollow structure having an internal space in which at least three lifting spaces for moving an object up and down are set in parallel from side to side in a horizontal direction has the dividing step for forming a partition to divide, in a sealed manner, the inside of the hollow structure into the preceding working space where the adhered material is processed precedingly and the succeeding working space where the adhered material is processed succeedingly in the intermediate lifting space other than the lifting spaces located at both ends, and the adhered material processing step for putting the succeeding working space into a state in which the object can move up and down, and performing the processing in the preceding processing space.

Description

  The present invention relates to a method for treating deposits, a partition wall, and a partition wall installation method in a hollow space of a building in which an elevator or the like is provided.

  As a hollow space of a building, for example, there is an elevator shaft configured such that a car moves up and down in an interior space that is long in the vertical direction. The elevator has a so-called multiple elevator system in which multiple cars are arranged in parallel on the left and right sides. The elevator shaft of the multiple elevator system moves up and down independently of each other for each car. An elevating space is provided so that it can be performed.

  In addition, asbestos constructed for the purpose of fire-resistant coating of steel frames may remain in the elevator shaft as it is attached to the steel frame, and such asbestos is harmless, such as removing it as soon as possible before scattering. It is necessary to apply a process.

  As a method for removing deposits in the elevator shaft, for example, a method of cleaning dust such as cotton dust as deposits is known (see, for example, Patent Document 1).

JP 2007-145448 A

  By the way, generally, when processing asbestos in a building, it is obliged to form a work space that is isolated and sealed by a curing sheet or the like, and to perform the processing work in that space. However, in the case of a multiple elevator as described above, if the entire elevator shaft is isolated and sealed, all the elevators cannot be used, which is extremely inconvenient. For this reason, it is desirable to isolate and seal at least one elevator space so that processing operations can be performed while the elevator is in operation.

  However, in the case of a multiple-type elevator, the interval between two elevator spaces adjacent in the left-right direction is narrow, and a plurality of intermediate beams and beams are provided between the elevator spaces adjacent in the left-right direction. In some cases, it is difficult to isolate and seal between the adjacent lift spaces, which is difficult because of being blocked by intermediate beams or beams, and the work is complicated.

  The present invention has been made in view of such a conventional problem. The object of the present invention is to easily seal and divide a hollow structure in which at least three elevating spaces are set side by side in the horizontal direction. An object of the present invention is to provide a method for treating a deposit, a method for installing a partition wall, and a partition wall for treating the deposit.

  In order to achieve such an object, the deposit processing method of the present invention provides a deposit in a hollow structure having an internal space in which at least three lifting spaces for moving up and down the object are set in parallel in the horizontal direction. In the method for treating deposits, the deposit is first processed in the hollow structure in an intermediate lifting space excluding the lifting spaces located at both ends of the at least three lifting spaces. A partitioning step for forming a partition wall for hermetically partitioning into a work space and a later work space to be processed later, and a state in which the object can be moved up and down in the rear work space, and the processing is performed in the previous work space. And a deposit processing step, wherein the deposit processing method comprises:

  Since the elevating space is a space in which an object moves up and down, a beam, an intermediate beam, or the like is not provided between adjacent elevating spaces. For this reason, when a partition wall that is hermetically partitioned into a preceding work space and a rear work space is formed in the lifting space as in the above-described method for treating an attached matter, it is not necessary to avoid beams and intermediate beams, so that A partition wall can be formed. At this time, if the lifting space provided with the partition wall is an intermediate lifting space excluding the lifting spaces located at both ends of at least three lifting spaces set in parallel on the left and right, it is included in the partitioned rear work space While making it possible to move the object up and down in the up and down space, it is possible to process the deposits in the previous work space.

In this depositing method, the partitioning step includes a base disposing step of providing a wall base material from the ceiling surface to the floor surface of the hollow structure in the intermediate lifting space, and the wall base material provided. A wall surface forming step for providing a wall material by providing a gap between the inner peripheral surface of the hollow structure and a relay member for connecting an end of the wall material and the inner peripheral surface of the hollow structure; And a closing step for closing the gap.
According to such a deposit processing method, the wall surface material is configured by attaching the wall surface material to the wall base material provided from the ceiling surface of the hollow structure body to the floor surface in the intermediate lifting space. It is possible to easily provide a wall surface covering almost the entire surface up to the floor surface. At this time, since the wall surface material is provided with a space between the inner peripheral surface of the hollow structure body and attached to the wall base material, the space between the wall surface material and the inner and inner surface is blocked by the relay member. Can be hermetically sealed over the entire surface.

In this method of treating a deposit, when the gap that is blocked by the relay member is a gap between the end of the wall surface material and the deposit, a scattering prevention sheet is provided on the surface of the deposit. It is desirable that the inner peripheral surface be formed by providing.
According to such a treatment method for deposits, the gap between the end of the wall surface material and the deposits is provided on the surface of the deposits with an anti-scattering sheet as an inner peripheral surface. It is possible to prevent the deposits from scattering due to the blockage.

In this deposit treatment method, the relay member is fixed to the wall surface material from the rear work space side, and in the deposit treatment step, the deposit is removed on the front work space side, A coating member is applied to the removed part, and a covering member that covers the part where the preceding work space and the rear work space communicate with each other when the relay member in contact with the scattering prevention sheet is removed Fixed to the wall material from the previous work space side, and a new deposit different from the deposit is attached to the previous work space side from the covering member of the portion coated with the anti-scattering agent on the previous work space side. After that, it is preferable to remove the adhering substance in the rear work space by removing the relay member from the rear work space side.
According to such a deposit treatment method, the deposit on the front work space side is removed after the front work space and the rear work space are hermetically partitioned by the wall surface material and the relay member. It is possible to reliably prevent the kimono from splashing outside. At this time, since the removed deposits do not scatter in the rear work space, the rear work space can be used regardless of the deposit removal process in the previous work space. For this reason, it is possible to raise and lower the object in the lifting space included in the rear work space while processing the deposit in the previous work space. In addition, since the anti-scattering agent is applied to the site where the deposit is removed, it is possible to more reliably prevent the deposit from scattering. Furthermore, since the relay member that closes the gap between the anti-scattering sheet and the wall surface material is removed after the cover member is attached, the previous work space is maintained in a sealed state, i.e., the front work space and the rear work space. It is possible to remove the relay member without communicating with the work space. In addition, after attaching the cover member, the process of attaching the new deposit to the work space side of the cover member is executed. It is possible to cover.

In this method of treating an attached matter, the anti-scattering agent is applied to a portion where the attached matter has been removed in the rear working space, and then the newly attached matter is attached to the rear working space side of the covering member. It is desirable to make it.
According to such a method for treating an adhering matter, after the anti-scattering agent is applied to the site where the adhering matter in the rear working space has been removed, the new adhering matter is adhered to the rear working space side of the covering member. In this case, it is possible to attach the new deposit while preventing the deposit from scattering.

In this method of treating a deposit, the covering member has a flat plate shape and is disposed along a crossing direction intersecting with a portion coated with the anti-scattering agent, and the edge of the covering member is prevented from scattering. It is preferable that the covering member is pulled out in the intersecting direction and removed after the agent is brought into contact with the coated portion and the newly attached matter is adhered to the rear working space side of the covering member.
According to such a deposit processing method, the flat cover member is arranged in a direction intersecting with the part coated with the anti-scattering agent, and its edge abuts on the part coated with the anti-scattering agent. Therefore, it is possible to reduce the contact area between the covering member and the inner peripheral surface, and it is possible to attach the newly attached material to a wider area. For this reason, the anti-scattering agent is applied after removing the adhering substance on the rear working space side of the covering member that is in contact with the part where the anti-scattering agent is applied in the previous work space. It is possible to apply the anti-scattering agent over almost the entire area. And it is possible to make a new deposit adhere to the region where the covering member is in contact, that is, the region excluding the thickness of the covering member. Moreover, since the covering member is pulled out and removed in a direction intersecting with the portion where the covering member is in contact, even if the covering member is removed, only a gap corresponding to the plate thickness of the covering member is formed, and the newly attached material is peeled off. It is possible to remove the covering member.

In this depositing method, it is desirable that the site where the covering member is pulled out is filled with the new deposit.
According to such a deposit treatment method, since the new deposit is filled in the gap formed by pulling out the covering member, the new deposit can be provided over the entire area where the deposit has adhered. It is.

In this depositing method, it is preferable that a sealing material is filled between the relay member and the scattering prevention sheet.
According to such a deposit processing method, since the sealing material is filled between the relay member and the inner peripheral surface, the space between the relay member and the inner peripheral surface can be reliably sealed.

In this partitioning process, in the partitioning step, a wire is stretched from the ceiling surface to the floor surface of the hollow structure in the foundation disposing step, and the wire is stretched up and down. A plurality of plate-like members extending in the front-rear direction intersecting the left-right direction at intervals in the direction are fixed, and in the wall surface forming step, an airtight sheet is used as the wall surface material from each of the left and right sides. It is desirable to stick to the plurality of plate-like members.
According to such a deposit processing method, a plurality of plate-like members extending in the front-rear direction are fixed to the wire stretched from the ceiling to the floor of the hollow structure with a space in the vertical direction. It is possible to form a base of a wall surface having high rigidity by forming a lattice shape with the shaped member. And since an airtight sheet | seat is affixed on the wire and plate-shaped member which make a grid | lattice form, it is possible to form the wall surface which was lightweight and high rigidity and was excellent also in airtightness.

  In addition, a partition wall for partitioning the hollow structure when processing the deposits in the hollow structure having an internal space in which at least three lifting spaces for moving up and down the object are set in parallel in the horizontal direction on the left and right An installation method comprising: a base disposing step of providing a wall base material from a ceiling surface to a floor surface of the hollow structure in an intermediate lifting space excluding the lifting space located at both ends of the at least three lifting spaces; A wall surface forming step of attaching a wall surface material by providing a gap between the wall base material and the inner peripheral surface of the hollow structure, and connecting an end portion of the wall surface material and the inner peripheral surface of the hollow structure. And a closing step of closing the gap by attaching a relay member.

  Since the elevating space is a space in which an object moves up and down, a beam, an intermediate beam, or the like is not provided between adjacent elevating spaces. For this reason, it is not necessary to avoid beams and intermediate beams when forming a partition wall that is hermetically partitioned into a front work space and a rear work space in the lift space as in the above partition wall installation method. A partition wall can be formed.

  And a partition wall for partitioning the hollow structure when processing the deposits in the hollow structure having an internal space in which at least three lifting spaces for moving up and down the object are set in parallel in the horizontal direction. A wall base material provided from the ceiling surface to the floor surface of the hollow structure in the intermediate lift space excluding the lift space located at both ends of the at least three lift spaces, and the wall base material provided The wall surface material attached with a gap between the inner peripheral surface of the hollow structure and the end of the wall material and the inner peripheral surface of the hollow structure are connected to block the gap. It is a partition wall characterized by having the relay member attached to a material.

  Since the elevating space is a space in which an object moves up and down, a beam, an intermediate beam, or the like is not provided between adjacent elevating spaces. For this reason, when a partition wall that is hermetically partitioned into a front work space and a rear work space is formed in the lifting / lowering space like the above partition wall, there is no need to avoid beams and intermediate beams, which is simpler. With the structure, it is possible to divide the space into a front work space and a rear work space.

  ADVANTAGE OF THE INVENTION According to this invention, the processing method of the deposit | attachment which installs the hollow structure internal body in which the at least 3 raising / lowering space was set in parallel with right and left of a horizontal direction easily sealed, and processed a deposit, The installation method of a partition And a partition wall can be provided.

It is an image figure for demonstrating the elevator shaft provided with the partition wall of this embodiment. It is the schematic of the cross section for demonstrating the hollow structure provided with the partition wall of this embodiment. It is a front view of the partition wall of this embodiment. It is a longitudinal cross-sectional view of the partition wall of this embodiment. It is a plane sectional view of the partition wall of this embodiment. It is a figure for demonstrating the wire stretched by the elevator shaft. It is a figure for demonstrating arrangement | positioning of the relay member attached so that a scattering prevention sheet may be enclosed. It is a front view which shows a wall member. It is a figure which shows the scattering prevention sheet affixed on the surface of asbestos, Fig.9 (a) is a front view, FIG.9 (b) is a longitudinal cross-sectional view, FIG.9 (c) has shown the plane cross-sectional view. FIG. 9A is a front view, FIG. 9B is a longitudinal sectional view, and FIG. 9C is a plan sectional view. It is a figure for demonstrating a relay member, Fig.11 (a) is a front view, FIG.11 (b) is a longitudinal cross-sectional view, FIG.11 (c) has shown the plane cross-sectional view. It is a figure for demonstrating the asbestos removal process of a previous work space, and the coating process of a scattering inhibitor, FIG. 12 (a) is a front view, FIG.12 (b) is a longitudinal cross-sectional view, FIG.12 (c) is a plane cross section. The figure is shown. It is a figure which shows the state which attached the abutting member, Fig.13 (a) is a front view, FIG.13 (b) is a longitudinal cross-sectional view, FIG.13 (c) has shown the plane sectional view. It is a figure for demonstrating the asbestos removal process of a back work space, and the coating process of a scattering prevention agent, Fig.13 (a) is a longitudinal cross-sectional view, FIG.13 (b) has shown the plane cross-sectional view. It is a figure which shows the clearance gap between the rock wool formed after removing an abutting member, Fig.15 (a) is a longitudinal cross-sectional view, FIG.15 (b) has shown the plane cross-sectional view. It is a perspective view which shows the other attachment method of a wall surface material.

  Hereinafter, an example of a deposit processing method, a partition wall installation method, and a partition wall according to the present embodiment will be described in detail with reference to the drawings.

In the present embodiment, an elevator shaft will be described as an example of the internal space of the hollow structure to which the deposit to be processed is attached.
Drawing 1 is an image figure for explaining an elevator shaft provided with a partition wall of this embodiment. FIG. 2 is a schematic cross-sectional view for explaining a hollow structure provided with a partition wall according to the present embodiment.

  In the elevator shaft EVS as an example of the internal space of the hollow structure 10, the partition wall 30 according to the present embodiment is made harmless such as removal of asbestos as a deposit already sprayed on the steel beam 21 a as a fireproof coating. It is used when performing a fireproof coating process in which rock wool as a new deposit to be newly applied is applied to the steel beam 21a as a fireproof coating. In the following description, as shown in FIG. 1, three directions perpendicular to each other are provided in the vertical direction (vertical direction) in which the car moves up and down in the elevator shaft, and openings for getting on and off the car are provided. The direction along the wall surface is referred to as the left-right direction (horizontal direction), and the direction that is the depth direction with respect to the car is referred to as the front-rear direction (horizontal direction).

=== About Elevator EV ===
As shown in FIGS. 1 and 2, the elevator EV includes an elevator shaft EVS partitioned in a part of a building such as a building, and a car that is guided so as to be movable up and down along the vertical direction in the elevator shaft EVS. 13 and a hoisting machine 19 that is disposed in the machine room MR above the elevator shaft EVS and moves up and down while suspending the car 13 using a suspension rope R having a counterweight W. .

  The elevator EV is a so-called triple elevator EV, and three elevator cars 13 are provided in parallel on the left and right in the elevator shaft EVS, and each elevator car 13 corresponds to a machine room. The hoisting machines 19 installed in the MR perform the lifting operation independently along the lifting spaces TR (TRL, TRC, TRR).

  The elevator shaft EVS is a rectangular parallelepiped space that is long in the vertical direction. Specifically, the steel beam 21a and the steel column 21b are assembled in a substantially rectangular parallelepiped shape that is long in the vertical direction, and the column beam frame 21 of the elevator shaft EVS is constructed. An intermediate beam 24 is provided between the elevating spaces TR of the three passenger cars 13 provided in parallel on the left and right sides so as to span the steel beam 21a between the floors in the front-rear direction. Here, both the steel beam 21a and the steel column 21b are H-shaped steel.

  Further, a concrete panel such as an ALC (aerated concrete) plate is disposed between the steel beams 21a adjacent to each other in the vertical direction, and the side wall 28 of the elevator shaft EVS is formed to surround the front, rear, left and right sides by this concrete panel. Yes. Further, a ceiling surface 10a and a floor surface 10b are formed at the upper end and the lower end of the four side walls 28, respectively, so that the elevator shaft EVS is substantially closed in all of the six directions up, down, front, rear, left and right. It is a closed space.

  The front side wall 28 of the four side walls 28 has an opening 28a for the elevator EV corresponding to each car 13 and each floor of the building, and each landing door 28a has An open / close door 25 that slides left and right is provided. Therefore, when the door 25 is opened in a state where there is no car 13, the interior of the elevator shaft EVS is in communication with the elevator hall EVH that is a space on the building side.

  By the way, as can be seen from the above, generally, the steel beam 21a of the column beam frame 21 is partially exposed in the elevator shaft EVS. Fire protection coating is indispensable for such steel exposed parts in the Building Standards Act, and asbestos was used as the material before. For this reason, asbestos may be exposed in the existing elevator shaft EVS even now.

  For such asbestos, for example, a detoxification process is performed in conjunction with the facility renewal work for the existing elevator EV. The detoxification treatment includes physical removal such as peeling asbestos, confinement treatment that hardens the surface of the application site by chemical solution application, etc. For example, an enclosing process for enclosing and not exposing to the outside.

  In any processing, it is obliged to isolate and seal the working space WS so that asbestos does not scatter around.

  However, in the case of the multiple elevators EV such as the above-described triple type, if the entire elevator shaft EVS is isolated and sealed and cured, all the elevator EVs cannot be used and become extremely inconvenient, so at least one elevator EV is operated. It is desirable that the detoxification process can be performed while the state is maintained.

  For this reason, it is required to partition the interior of the elevator shaft EVS horizontally to the left and right to divide the work space WS in units of the car 13, that is, the elevator space TR (elevator EV). However, since the space between adjacent elevator spaces in the elevator shaft EVS is narrow and must be hermetically partitioned while avoiding beams and intermediate beams, the structure of the partition wall is complicated and the construction for providing the partition wall is complicated. is there.

  Therefore, the partition wall according to the present embodiment is provided in an elevating space where no beam or intermediate beam is provided, so that a plurality of hollow structures having beams or intermediate beams between adjacent elevating spaces can be easily provided. The space is sealed and the operation of the car 13 (elevating space TR, elevator EV) outside the partitioned work space WS is secured.

== Partition Wall According to the Present Embodiment, Partition Wall Installation Method, and Deposited Material Treatment Method ===
<< Partition wall >>
FIG. 3 is a front view showing the partition wall according to the present embodiment, FIG. 4 is a longitudinal sectional view of the partition wall according to the present embodiment, and FIG. 5 is a plan sectional view of the partition wall according to the present embodiment. is there. FIG. 6 is a view for explaining a wire stretched on the elevator shaft.

  The partition wall 30 is, for example, as shown in FIGS. 1 to 5, an elevator space (hereinafter referred to as “elevator space”) excluding the elevator spaces located at both ends of the three or more elevator spaces set in parallel in the horizontal direction. A wall base material having a plurality of wires 32 stretched from the ceiling surface 10a to the floor surface 10b of the elevator shaft EVS and a flat bar 62 as a plate-like member fixed to the wires 32 in an intermediate lifting space) A wall member 34 to which an airtight sheet 40 as a wall member 35 is attached, a relay member 36 attached to a peripheral end of the wall member 34, and a closing plate 37 provided at a joint portion between the wall member 34 and the asbestos 31. And have.

  As shown in FIG. 6, the wire 32 is stretched by introducing tension between the upper and lower temporary steel beams 61 fixed along the front-rear direction on the ceiling surface 10 a and the floor surface 10 b of the elevator shaft EVS. ing. More specifically, the wires 32 are stretched around a plurality of wire locking portions 61a provided at positions facing the upper and lower sides of the upper and lower temporary steel beams 61 at intervals in the front-rear direction.

  One end of the inserted wire 32 is folded back and fixed to a wire clip 61b in the upper wire locking portion 61a of the wire locking portions 61a facing vertically. The lower wire locking portion 61a is provided with a turnbuckle 61d and a load meter 61e through a shackle 61c provided at the other end of the wire 32 with a wire clip 61b, and a shackle 61c provided further on the turnbuckle 61d. Is fixed. In the example of FIG. 3 and FIG. 6, six wires 32 are provided along the vertical direction at intervals in the front-rear direction.

  On the plurality of wires 32 stretched in the vertical direction, a plurality of flat bars 62 made of steel that are flat and spaced apart from each other in the vertical direction are arranged along the front-rear direction. 62 is fixed by a U-bolt 63 having a U-shape. The front and rear end portions of the flat bar 62 that are fixed in the wire 32 along the front-rear direction are spaced from the side wall 28. That is, a gap 10 c (see FIG. 8) is provided between the front and rear ends of the flat bar 62 and the side wall 28.

  Further, flat bars 62 extending substantially in the vertical direction except for the vicinity of asbestos 31 covering the steel beam 21a are fixed to both ends of each flat bar 62 across a plurality of flat bars 62 extending in the front-rear direction. Has been. Further, in the vicinity of the asbestos 31 covering the steel beam 21a, an airtight sheet 40 to be attached later is provided so as to extend from the flat bar 62 above the upper edge of the asbestos 31 to the flat bar 62 below the lower edge of the asbestos 31. A flat bar 62 extending substantially in the vertical direction is fixed to the flat bar 62 extending in the front-rear direction at a position away from the periphery of the asbestos 31.

  The wall member 34 is used as two wall surface materials that cover a wall base material that integrates six wires 32 stretched in the vertical direction and a flat bar 62 fixed to the wires 32 from both left and right sides. An airtight sheet 40. The airtight sheet 40 is, for example, a polyethylene sheet, a PET sheet, or the like, and the left and right sides of the wire 32 stretched along the vertical direction and the flat bar 62 fixed to the wire 32 to partition the hollow structure 10. It is pasted from both sides. Specifically, the airtight sheet 40 is attached in a surface contact state with a double-sided tape or the like attached to both surfaces of the flat bar 62. The airtight sheet 40 is provided with a gap 10c (see FIG. 8) at a slight gap at the boundary with the inner peripheral surface of the hollow structure 10. The gap 10 c is closed by the relay member 36 and the closing plate 37. Here, the inner peripheral surface of the hollow structure 10 refers to the slab 12 exposed in the elevator shaft EVS between the front and rear side walls 28, the ceiling surface 10a and the floor surface 10b of the hollow structure 10, and each floor. The surface of the asbestos 31 covering the end portion and the steel beam 21a corresponds to the inner peripheral surface connected to the airtight sheet 40 by the relay member 36, but the side wall 28, the ceiling surface 10a, the floor surface 10b, and the end of the slab 12 And the surface of the anti-scattering sheet 38 attached to the surface of the asbestos 31. The scattering prevention sheet 38 is a member having fire resistance provided to prevent the asbestos 31 from scattering when the relay member 36 is attached.

  FIG. 7 is a view for explaining the arrangement of relay members attached so as to surround the scattering prevention sheet.

  The relay member 36 is a steel plate having an L-shaped cross section, and one plate portion having an L shape forms an abutting plate portion 36a that contacts the inner peripheral surface of the hollow structure 10, and the other plate portion. However, it forms a fixed plate portion 36b that is brought into contact with one surface of the airtight sheet 40 and fixed with a tape material.

  Since the asbestos 31 is sprayed onto the surface of the steel beam 21a, the asbestos 31 has a curved surface so as to cover the surface of the steel beam 21a, and the surface of the anti-scattering sheet 38 attached to the surface is also curved. . That is, the surface of the anti-scattering sheet 38 is not flat unlike the side wall 28 and the like, and since the flange of the H-shaped steel forming the steel beam 21a protrudes, the relay member 36 made of an L-shaped steel plate is The steel plate 21a is disposed around the steel beam 21a so that the contact plate 36a contacts the surface of the scattering prevention sheet 38 as much as possible. For this reason, as shown in FIG. 7, the relay member 36 that is in contact with the anti-scattering sheet 38 has a narrow width, and the air-tight sheet covers the periphery of the steel beam 21a with the plurality of relay members 36. 40. A sealing material 39 is filled between the adjacent relay members 36 and the scattering prevention sheet 38 of the plurality of relay members 36 so as to fill the gaps therebetween.

  The blocking plate 37 is a flat sheet metal having an abutting portion formed in a shape substantially along the outline of the anti-scattering sheet 38 attached to the surface of the asbestos 31 covering the steel beam 21a, and is airtight. The edge part of the sheet | seat 40 is fixed, and it arrange | positions so that the edge part of the scattering prevention sheet | seat 38 and the airtight sheet | seat 40 may be connected. For example, the closing plate 37 includes a plurality of prismatic pieces of wood having a square shape with a 1 cm square cross section, which are arranged along the same direction and overlapped while being guided to be slidable independently in the longitudinal direction. The tool is formed on the basis of the surface shape of the anti-scattering sheet 38, that is, the shape in which the contour is formed.

  Specifically, a plurality of pieces of wood included in the jig are stacked wider than the vertical width of the asbestos 31 exposed in the hollow structure 10, and the asbestos is in a state where the tip portions of the pieces of wood are aligned. Each wooden piece is slid along the shape of the surface of the anti-scattering sheet 38 by bringing it into contact with the anti-scattering sheet 38 provided on the surface of 31 from the front, that is, from the direction along the airtight sheet 40. Then, after the wooden pieces on the upper and lower ends contact the side wall 28, the jig is pulled away from the anti-scattering sheet 38 so that the wooden pieces are not displaced, and the wooden pieces are arranged flat on the sheet metal material as they are. . Thereafter, the outline of the tip of each piece of wood is copied to the sheet metal material, and the sheet metal material is cut along the copied outline to form the closing plate 37.

<< Partition wall installation method and asbestos treatment method >>
In the present embodiment, the processing of asbestos 31 is performed from the work space WS including the leftmost lift space TRL in the elevator shaft EVS of the triple elevator EV in which the three passenger cars 13 are provided in parallel on the left and right. It will be described as what to do. Here, the treatment of asbestos 31 includes a removal treatment that removes existing asbestos 31 and a fireproof coating treatment that applies rock wool 46 as a new fireproof coating to the site from which asbestos 31 has been removed.

  When the asbestos 31 removal process is performed in the work space WS including the leftmost lift space TRL of the elevator shaft EVS, first, the partition wall 30 is installed in the lift space TRC located in the center. First, the partition wall 30 is installed by extending a wire 32 in the vertical direction in the vicinity of the center of the central lift space TRC. In the following description, in order to clarify the installation method of the partition wall, the periphery of the steel beam 21a provided between the floors and covered with asbestos will be mainly described. Further, the work space including the leftmost lift space TRL and performing the process first is referred to as a pre-work space WSB, and the work space including the lift space TRR located from the left to the right is processed after the previous work space WSB. This is called a work space WSA.

  When installing the partition wall 30, first, the left elevator space TRL to be processed and the elevator car 13, the suspension rope R, and the like located in the central elevator space TRC are removed. Here, since the central lift space TRC is partitioned by the partition wall 30 and divided into the front work space WSB and the rear work space WSA, the car 13 and the suspension rope R are removed together with the left lift space TRL. Keep it.

  Then, as shown in FIG. 1, the suspension wire 73 is suspended from the ceiling surface 10 a of the hollow structure 10 into the left lifting space TRL included in the previous work space WSB to be processed first. In addition, the work gondola 71 is carried onto the floor surface 10 b of the elevator shaft EVS, and the lower end of the suspension wire 73 is set on the hoisting machine 75 of the work gondola 71. Thus, the work gondola 71 becomes usable in the lift space TR of the elevator EV to be processed. The operator performs the removal process of the asbestos 31 and the fireproof coating process while moving the work gondola 71. The elevator shaft EVS is provided with a dust collector that sucks air in the work space in order to ventilate the work space.

  First, as shown in FIG. 6, a temporary steel beam 61 in which a plurality of wire locking portions 61a are provided at appropriate intervals in the longitudinal direction on the ceiling surface 10a and the floor surface 10b of the hollow structure 10 is moved up and down on the left side. The longitudinal direction is along the front-rear direction between the space TRL and the central lift space TRC, and is fixed at a position facing vertically.

  The wire 32 to which the turnbuckle 61d, the load meter 61e, and the shackle 61c are coupled is joined to each of the engaging portions 61a arranged above and below, and the tension is confirmed with the load meter 61e while rotating the turnbuckle 61d. An appropriate tension is introduced to stretch the wire 32 (underlaying step).

FIG. 8 is a front view showing the wall member.
Next, as shown in FIG. 8, flat bars 62 are arranged on a plurality of wires 32 stretched in the vertical direction at intervals in the vertical direction, and fixed to the wires 32 with U bolts 63. At this time, a gap 10 c is provided between the end of the flat bar 62 in the front-rear direction and the side wall 28.

  Next, an airtight sheet 40 having a size that partitions substantially the entire hollow structure 10 from both sides of the front work space WSB and the rear work space WSA is attached to the wire 32 to which the flat bar 62 is attached (wall surface forming step). ). At this time, a gap 10c is provided between the end of the airtight sheet 40 and the inner peripheral surface of the hollow structure, that is, between the ceiling surface 10a, the floor surface 10b, the surface of the side wall 28, and the surface of the asbestos 31. Keep it.

  FIG. 9 is a view showing a scattering prevention sheet attached to the surface of asbestos. FIG. 9 (a) is a front view, FIG. 9 (b) is a longitudinal sectional view, and FIG. 9 (c) is a plan sectional view. Show.

  Next, as shown in FIG. 9, based on the position of the airtight sheet 40 that forms the partition wall 30, the relay member 36 that is attached to the end of the airtight sheet 40 and abuts on the side wall side and the obstruction Assuming the position of the plate 37, the position where the relay member 36 and the closing plate 37 located in the vicinity of the peripheral edge of the wall member 34 are in contact, that is, the steel beam 21a exposed to the elevator shaft EVS is covered. A scattering prevention sheet 38 is adhered to the surface of the asbestos 31. In this operation, the operation proceeds while sucking the suction port of the vacuum cleaner with the HEPA filter toward the place where the scattering prevention sheet 38 is adhered. At this time, the width of the anti-scattering sheet 38 to be adhered is set wider than the width in the left-right direction of the contact plate portion 36a of the relay member 36. Moreover, the anti-scattering sheet 38 is stuck so as not to protrude from the left side of the wall surface material to be formed (to the previous work space WSB side).

  10A and 10B are diagrams for explaining the closing plate. FIG. 10A is a front view, FIG. 10B is a longitudinal sectional view, and FIG. 10C is a plan sectional view.

  Next, as shown in FIG. 10, the closing plate 37 that blocks between the scattering prevention sheet 38 and the end of the airtight sheet 40 is fixed from the rear work space WSA side. The closing plate 37 has an edge substantially along the contour of the surface of the anti-scattering sheet 38 adhered on the asbestos 31 in contact with the surface of the anti-scattering sheet 38 so that the airtight sheet 40 is coated with a double-sided tape or the like. And fix.

  11A and 11B are diagrams for explaining the relay member. FIG. 11A is a front view, FIG. 11B is a longitudinal sectional view, and FIG. 11C is a plan sectional view.

  Next, as shown in FIG. 11, the contact plate portion 36a of the relay member 36 is brought into contact with the inner peripheral surface of the hollow structure 10, and the fixed plate portion 36b is overlapped on the airtight sheet 40 from the rear work space WSA side. Fix with double-sided tape etc. (blocking process). At this time, in the part where the blocking plate 37 is provided, the relay member 36 is fixed with the blocking plate 37 sandwiched between the airtight sheet 40.

  Moreover, although the edge part of the slab 12 which forms each floor is inside the side wall 28 in the upper surface of the slab 12, and the part which is not covered with the asbestos 31 in the end surface of the slab 12, the slab 12 is exposed in the elevator shaft EVS. The relay member 36 is formed in such a size that the width in the left-right direction exposed at the upper surface of 12 and the width in the vertical direction exposed at the end surface of the slab 12 are overlapped and the adjacent relay members 36 overlap each other. Are respectively brought into contact with the upper surface of the slab 12 and the end surface of the slab 12 and fixed to the airtight sheet 40 from the rear work space WSA side.

  Since the scattering prevention sheet 38 is affixed on the asbestos 31 covering the steel beam 21a, the surface is not flat but curved. For this reason, as shown in FIG. 7, the relay member 36 provided between the scattering prevention sheet 38 and the steel plate panel 49 first has the contact plate portion 36a of the relay member 36 regardless of the curved surface of the scattering prevention sheet 38. It is made to contact with the scattering prevention sheet 38 in a state along the vertical or horizontal. That is, the abutting plate portion 36a is brought into contact with the anti-scattering sheet 38 in the direction facing the inner surface of the side wall 28 and upward and downward to fix the fixed plate portion 36b to the closing plate 37 from the rear work space WSA side. In this state, a portion that is not connected is formed between the adjacent relay members 36 on the curved surface portion of the scattering prevention sheet 38. For this reason, the relay member 36 is further fixed to the closing plate 37 from the rear work space WSA side so as to cover a portion having a gap between the contact plate portions 36a of the relay members 36 adjacent to each other at this time. To do.

  Specifically, the relay members 36 are arranged in a direction in which the contact plate 36a faces the inner surface of the side wall 28 and the contact plate 36a is directed upward and downward. Among them, the relay member 36c is arranged on the closing plate 37 such that the edge of the contact plate 36a of the relay member 36c provided further contacts each edge of the contact plate 36a of the relay member 36 adjacent to each other. Fix from the rear work space WSA side. In the example of FIG. 7, the relay member 36 c provided for closing between the adjacent relay members 36 is arranged such that the contact plate portion 36 a forms approximately 45 degrees with the vertical and horizontal directions.

  Since there is a gap between the anti-scattering sheet 38 affixed on the asbestos 31 and the relay member 36c provided to block between the adjacent relay members 36, as shown in FIG. A sealing material 39 is filled between the sheet 38 and the contact plate portion 36a of the relay member 36c provided to close the space between the adjacent relay members 36.

  Moreover, between the edge part of the airtight sheet | seat 40, and the internal peripheral surface of the hollow structure 10, ie, the edge part of the airtight sheet | seat 40, the ceiling surface 10a of the elevator shaft EVS, the floor surface 10b, and the inner surface of the side wall 28 The fixing plate portion 36b of the relay member 36 is airtight with the contact plate portion 36a of the relay member 36 being in contact with the inner surface of the side wall 28, the ceiling surface 10a and the floor surface 10b of the elevator shaft EVS. It sticks to the edge part of the adhesive sheet 40 from the rear work space WSA side (partition process).

  At this time, since the inner surface of the side wall 28, the ceiling surface 10a and the floor surface 10b of the elevator shaft EVS are flat, the contact plate portion 36a of each one relay member 36 along the vertical direction or the horizontal direction is used as the inner surface of the side wall 28. Then, the fixed plate portion 36b of the relay member 36 is affixed to the end portion of the airtight sheet 40 from the rear work space WSA side in a state of being in contact with the ceiling surface 10a and the floor surface 10b of the elevator shaft EVS. Here, the number of the relay members 36 that are in contact with the inner surface of the side wall 28 between the steel beams 21a vertically adjacent to each other and the ceiling surface 10a and the floor surface 10b of the elevator shaft EVS is not limited to one. Since no seam is generated, it is easy to ensure an airtight state.

  In this state, the partition wall 30 that partitions the previous work space WSB and the rear work space WSA and hermetically seals is completed.

  After the front work space WSB and the rear work space WSA are partitioned in a sealed state by the partition wall 30, the front work space is moved up and down in the lift space TRR on the right side of the rear work space WSA while operating the elevator EV. The removal process of asbestos 31 is executed by the dry ice blasting method in WSB (attachment treatment process).

The removal process of asbestos 31 is performed in the following procedure.
12A and 12B are diagrams for explaining the asbestos removal process and the anti-scattering agent coating process in the previous work space. FIG. 12A is a front view, FIG. 12B is a longitudinal sectional view, and FIG. ) Shows a cross-sectional plan view.
First, a gap such as the landing entrance 28a with respect to the previous work space WSB is hermetically sealed with a polyethylene sheet or the like. Further, a curing sheet is laid and covered on the entire floor surface 10b.
Next, the dust collector is operated, and the work space WS is brought into a negative pressure state.

  The worker moves up and down in the previous work space WSB while riding on the work gondola 71 to approach the attachment site of the asbestos 31 covering the steel beam 21a, and is closer to the front work space WSB side than the anti-scattering sheet 38. The asbestos 31 is scraped off with a spatula or the like, and the remaining asbestos 31 is removed using a dry ice blasting apparatus. At this time, as shown in FIG. 12, the anti-scattering sheet 38 present on the side of the previous work space WSB is deleted at the position where the blocking plate 37 is in contact, and until the deleted anti-scattering sheet 38. Asbestos 31 is removed. Here, the dry ice particles sprayed from the dry ice blasting device sublimate after colliding with asbestos and become carbon dioxide gas, and accumulate in the lower part of the work space WS. However, the accumulated carbon dioxide gas is sucked from the intake port of the dust collector. Quickly exhausted to the external space.

  Then, liquid anti-scattering agent 42 is sprayed onto the exposed portion of asbestos 31 removed. At this time, asbestos 31 dropped on the curing sheet on the floor surface 10b by suction is sucked with a vacuum cleaner or the like and discharged from the previous work space WSB.

  FIGS. 13A and 13B are views showing a state in which the abutting member is attached. FIG. 13A is a front view, FIG. 13B is a longitudinal sectional view, and FIG. 13C is a plan sectional view.

  After spraying the anti-scattering agent 42, as shown in FIG. 13, at the part where the partition wall 30 and the inner peripheral surface are in contact with each other, it projects against a wider range in the vertical direction than the part covered with the asbestos 31. The abutting member 44 as a covering member to be applied is attached to the airtight sheet 40 from the previous work space WSB side. The abutting member 44 is located on the lower end side of the side wall 28 located above the asbestos 31 covering the steel beam 21a, the end of the slab 12, the exposed steel beam 21a, and the lower side of the asbestos 31 covering the steel beam 21a. It is a flat member formed along the contour of the upper end side of the side wall 28.

  Since the asbestos 31 is already removed and the contour of the surface does not include a curve, the portion where the abutting member 44 is abutted is formed by being cut linearly along the inner peripheral surface of the hollow structure 10. Yes. The abutting member 44 is fixed to the airtight sheet 40 from the previous work space WSB side, and is in contact with the inner surface of the upper side wall 28 and the inner surface of the lower side wall 28 to be fixed to the airtight sheet 40. It faces the relay members 36 and 36c. For this reason, after the abutting member 44 is attached, the preceding work space WSB and the rear work space WSA are not communicated with each other even if the relay members 36 and 36c and the closing plate 37 facing the abutting member 44 are removed. ing.

  The abutting member 44 is located on the front work space WSB side of the airtight sheet 40, and the steel beam 21a sprayed with the anti-scattering agent 42 on the left side (rear work space WSA side) of the anti-scattering sheet 38 and the upper and lower sides thereof. In the state of being struck over the part, the sheet is attached to the airtight sheet 40 on the left side of the scattering prevention sheet 38 so as to be substantially orthogonal to the contact surface.

  After attaching the abutting member 44, rock wool 46 is sprayed as a new fireproof covering material on the portion of the previous work space WSB where the anti-scattering agent 42 has been sprayed to complete the asbestos removal process in the previous work space WSB.

  Next, asbestos removal processing on the rear work space WSA side is executed. At this time, since the present embodiment is a triple elevator EV, the right lifting space TRR is included on the rear work space WSA side. For this reason, the work gondola 71 is moved up and down in the right lifting space TRR to remove the asbestos 31 from the rear working space WSA.

  First, as in the case of the left elevating space TRL, the car 13 and the suspension rope R etc. of the right elevating space TRR are removed. Then, the suspension wire 73, the work gondola 71, the hoisting machine 75 of the work gondola 71, the dust collector and the like are removed from the left lifting space TRL where the asbestos 31 removal process has already been completed, and set in the central lifting space TRC. Also, the elevator EV is operated by setting the car 13 and the hanging rope R in the left lifting space TRL.

  Then, when the gap such as the landing doorway 28a existing in the rear work space WSA is hermetically cured with a polyethylene sheet or the like, the rear work space WSA becomes a sealed work space WS. Further, the floor surface 10b is covered and covered with a curing sheet over the entire surface, the dust collector is operated, and the work space WS is brought into a negative pressure state.

  FIGS. 14A and 14B are diagrams for explaining the asbestos removal process and the anti-scattering agent coating process in the rear work space. FIG. 14A is a longitudinal sectional view, and FIG. 14B is a plan sectional view. .

  In the asbestos removal process of the rear work space WSA, first, as shown in FIG. 14, the relay member 36 and the blocking plate 37 that cover the portion where the abutting member 44 is attached from the rear work space WSA side are removed from the rear work space WSA. Remove from the side. Even when the relay member 36 provided at a position facing the abutting member 44 is removed, the sealed state of the rear work space WSA is maintained.

  As shown in FIG. 14, the anti-scattering sheet 38 with which the relay member 36 is in contact is removed, and the removal process of the asbestos 31 in the rear work space WSA is executed. The removal process of the asbestos 31 is the same as that in the case of the left elevating space TRL. When the removal of asbestos 31 is completed in the post-work space WSA, as shown in FIG. 14, a portion where the asbestos 31 is removed and the liquid scattering prevention agent 42 is sprayed on the exposed portion, and the scattering prevention agent 42 is sprayed. Then, rock wool 46 is sprayed as a new fireproof covering material.

  15A and 15B are views showing a gap of rock wool formed after removing the abutting member. FIG. 15A is a longitudinal sectional view, and FIG. 15B is a plan sectional view.

  After the spraying of the rock wool 46 is completed, the airtight sheet 40, the wire 32, the flat bar 62, the abutting member 44, that is, the partition wall 30, which are in contact with the side wall 28, the ceiling surface 10a, and the floor surface 10b are removed. To do. At this time, the abutting member 44 is substantially orthogonal to the portion where the anti-scattering agent 42 is sprayed between the rock wool 46 sprayed in the previous work space WSB and the rock wool 46 sprayed in the rear work space WSA. Remove to pull in the direction.

  After removing the abutting member 44, as shown in FIG. 15, the abutting member 44 is interposed between the rock wool 46 sprayed in the previous work space WSB and the rock wool 46 sprayed in the rear work space WSA. Since a gap 46a corresponding to the thickness is generated, the gap 46a is filled with rock wool 46 and repaired. When the repair of the rock wool 46 is completed, the removal process of the asbestos 31 in the elevator shaft EVS, that is, the left elevating space TRL, the central elevating space TRC, and the right elevating space TRR is completed.

  Since the elevator space TR is a space in which the car 13 moves up and down, the steel beam 21a, the intermediate beam 24, and the like are not provided between the adjacent elevator spaces TR. For this reason, when the partition wall 30 that is hermetically partitioned into the preceding work space WSB and the rear work space WSA is formed in the lift space TR as in the processing method for the asbestos 31 of the present embodiment, the steel beam 21a and the intermediate Since it is not necessary to avoid the beam 24, the partition wall 30 can be easily formed. At this time, when the lifting space TR provided with the partition wall 30 is an intermediate lifting space TRC excluding the lifting spaces TRL, TRR located at both ends of at least three lifting spaces TRL, TRC, TRR set in parallel on the left and right The asbestos 31 can be processed in the preceding work space WSB while the car 13 can be raised and lowered in the lift space TRR included in the partitioned work space WSA.

  Moreover, since the airtight sheet 40 is attached to the wire 32 and the flat bar 62 which are the wall base materials provided from the ceiling surface 10a to the floor surface 10b of the hollow structure 10 in the intermediate lifting space TRC, the wall surface is configured. It is possible to easily provide a wall surface covering almost the entire surface from the 10 ceiling surfaces 10a to the floor surface 10b. At this time, the airtight sheet 40 is provided with a gap 10c between the airtight sheet 40 and the inner peripheral surface of the hollow structure 10, and is attached to the wire 32 and the flat bar 62 forming a lattice shape, and between the airtight sheet 40 and the inner peripheral surface. Since the gap 10c is closed by the relay members 36 and 36c, the hollow structure 10 can be hermetically partitioned over the entire surface.

  Further, since the air gap 10c between the end portion of the airtight sheet 40 and the asbestos 31 is provided with a scattering prevention sheet 38 on the surface of the asbestos 31, the air gap 10c is blocked by the relay members 36 and 36c. It is possible to prevent the asbestos 31 from being scattered.

  In addition, since the asbestos 31 on the front work space WSB side is removed after the airtight sheet 40 and the relay members 36 and 36c are hermetically partitioned into the front work space WSB and the rear work space WSA, the asbestos 31 that has been removed is removed. It is possible to reliably prevent scattering to the outside. At this time, since the removed asbestos 31 does not scatter into the rear work space WSA, the rear work space WSA can be used regardless of the removal process of the asbestos 31 in the previous work space WSB. For this reason, it is possible to raise and lower the car 13 in the elevating space TRL included in the rear work space WSA while processing the asbestos 31 in the previous work space WSB. Moreover, since the anti-scattering agent 42 is applied to the site from which the asbestos 31 has been removed, the asbestos 31 can be more reliably prevented from scattering. Further, since the relay members 36 and 36c for closing the gap 10c between the anti-scattering sheet 38 and the airtight sheet 40 are removed after the closing plate 37 is attached, the state where the previous work space WSB is hermetically partitioned is maintained. In other words, the relay members 36 and 36c can be removed without communicating the preceding work space WSB and the rear work space WSA. In addition, since the process of attaching the rock wool 46 to the work space WSB side ahead of the closing plate 37 is performed after the closing plate 37 is attached, the work space WSB side from the closing plate 37 where the asbestos 31 is attached. Can be covered with rock wool 46.

  In addition, since the anti-scattering agent 42 is applied to the portion of the rear work space WSA from which the asbestos 31 has been removed, the lock wool 46 is attached to the rear work space WSA side of the closing plate 37. Therefore, the asbestos 31 also in the rear work space WSA. It is possible to attach the rock wool 46 while preventing the scattering.

  Further, the flat blocking plate 37 is disposed in a direction intersecting with the portion coated with the anti-scattering agent 42 and the edge thereof is in contact with the portion coated with the anti-scattering agent 42. The contact area with the peripheral surface can be reduced, and the rock wool 46 can be attached to a wider area. For this reason, after removing the asbestos 31 on the rear work space WSA side of the closing plate 37 that is in contact with the part where the anti-scattering agent 42 is coated in the previous work space WSB, the anti-scattering agent 42 is applied. The anti-scattering agent 42 can be applied to almost the entire region where the asbestos 31 has been adhered. Then, the rock wool 46 can be attached to a portion where the closing plate 37 is in contact, that is, a region excluding the thickness of the closing plate 37. Further, since the closing plate 37 is pulled out and removed in a direction intersecting with the portion where the closing plate 37 is in contact, even if the closing plate 37 is removed, only the gap 46a corresponding to the plate thickness of the closing plate 37 is formed. It is possible to remove the closing plate 37 without peeling off the wool 46.

  Further, since the rock wool 46 is also filled in the gap 46 a formed by pulling out the closing plate 37, the rock wool 46 can be provided in the entire region where the asbestos 31 has adhered.

  Further, since the sealing material 39 is filled between the relay members 36 and 36c and the inner peripheral surface, it is possible to reliably seal between the relay members 36 and 36c and the inner peripheral surface.

  In addition, a plurality of flat bars 62 extending in the front-rear direction are fixed to the wires 32 stretched from the ceiling to the floor of the hollow structure 10 so that the wires 32 and the flat bars 62 are latticed. It is possible to form a base of a wall surface having high rigidity. And since the airtight sheet | seat 40 is affixed on the wire 32 and flat bar 62 which make a grid | lattice form, it is possible to form the wall surface excellent in airtightness with high rigidity while being lightweight.

  Further, according to the partition wall 30 and the installation method of the partition wall 30 of the present embodiment, it is not necessary to avoid the steel beam 21a, the intermediate beam 24, etc. as between the adjacent lift spaces TR. It is possible to form.

  Since the elevating space is a space in which an object moves up and down, a beam, an intermediate beam, or the like is not provided between adjacent elevating spaces. For this reason, when a partition wall that is hermetically partitioned into a front work space and a rear work space is formed in the lifting / lowering space like the above partition wall, there is no need to avoid beams and intermediate beams, which is simpler. With the structure, it is possible to divide the space into a front work space and a rear work space.

=== Other Embodiments ===
As mentioned above, although embodiment of this invention was described, this invention is not limited to this embodiment, The deformation | transformation as shown below is possible in the range which does not deviate from the summary.

  In the above-described embodiment, the elevator shaft EVS is shown as an example of the internal space of the hollow structure 10. However, the present invention is not limited to this, and is not limited to this. A structure having an endless orbit for moving up and down a plurality of automobiles in a space) may be applied to this as a hollow structure. That is, in the internal space of the tower parking, a plurality of orbits are provided in parallel on the left and right in the horizontal direction, and each orbit can be independently orbited.

  Moreover, in the said embodiment, about the example which provides the partition wall 30 in the raising / lowering space of the center of the elevator shaft EVS of the triple type elevator EV, and divides into the front work space WSB and the rear work space WSA and performs a process. As described above, when there are four elevating spaces TR as in the triple elevator EV, a partition wall 30 is provided in one of the two elevating spaces excluding the elevating spaces at both ends to provide two spaces. Divide and process in the same manner as the triple elevator EV. In addition, when there are five or more elevating spaces TR, the partition wall 30 is provided in the elevating space TR located second from any one end side, and processing is performed in the work space WS on one end side. Thereafter, a partition wall 30 is newly provided in the lift space TR adjacent to the lift space TR provided with the partition wall 30, and processing is performed between the two partition walls 30. After that, the partition wall 30 is provided in the lift space TR in a position where one lift space TR is sandwiched between the lift space TR provided with the partition wall 30 and the asbestos 31 between the partition walls 30 is processed. Then, the partition wall 30 installed to seal the previous work space WSB can be used as the partition wall 30 of the rear work space WSA, so that the installation and removal work of the partition wall 30 can be omitted, and the work can be carried out efficiently. It is possible. At this time, the reason why the partition wall 30 is not provided in the adjacent lift space TR is that the work gondola 71 cannot be used between the partition walls 30.

  In the above-described embodiment, the airtight sheet 40 is described as a single sheet. However, the present invention is not limited to this, and the airtight sheet 40 is configured by a plurality of sheets of appropriate sizes, and these are connected by an adhesive tape or the like. In addition, the size of the partition wall 30 may be increased.

  In the said embodiment, although the scattering prevention sheet | seat stuck on the surface of asbestos 31 was made into the sheet | seat which has fire resistance, it does not necessarily need to have fire resistance.

  FIG. 16 is a perspective view showing another method for attaching the wall surface material.

  Moreover, in the said embodiment, the example which affixed the airtight sheet | seat 40 as a wall surface material on the flat bar 62 fixed to the wire 32 stretched along the up-down direction from both right and left was demonstrated. However, not limited to this, for example, as shown in FIG. 16, a wall surface is formed by sandwiching an airtight sheet 40 between two wires 32 (wire pairs 33) stretched adjacent to each other in the left-right direction. May be. In this case, since the airtight sheet is not attached, the construction for forming the wall surface is easy. Moreover, it is possible to easily increase the rigidity of the formed wall surface by narrowing the interval between the wire pairs 33 in the front-rear direction.

  In the above embodiment, the wall material is the airtight sheet 40, but the wall material is not limited to this, and for example, a plate material having high rigidity such as a Galvalume steel plate may be used. At this time, a plurality of wall materials such as a galvalume steel plate may be overlapped with each other to form a wall surface. Furthermore, if an airtight sheet is provided on both surfaces of the wall surface material, or if a sealing material is filled in the seam of the wall surface material, it is possible to perform a more reliable sealed compartment.

  In the above embodiment, an example has been described in which a wire is stretched from the ceiling surface to the floor surface of the hollow structure in the intermediate lifting space, and a partition wall is formed by attaching a wall surface material to the stretched wire. Instead of the wire, for example, a lightweight steel material may be erected from the ceiling surface to the floor surface of the hollow structure, and the wall material may be attached to the lightweight steel material.

  In the above-described embodiment, the case where the asbestos process is performed without the car 13 in the elevator shaft EVS is exemplified. However, the asbestos process is performed in the state where the car 13 is present in the lift space TR in which no partition wall is provided. May be performed. In this case, the car 13 is moved to the upper end or the lower end of the elevating space TR so as not to interfere with the asbestos processing operation. Needless to say, the car 13 is moved to the processed position.

  In the above-described embodiment, the work gondola 71 is brought into the elevator shaft EVS to perform asbestos processing work. However, the passenger car 13 provided in each elevator EV (elevating space TR) is used instead of the work gondola 71. May be. That is, an operator may get on the roof surface of the car 13 and perform the processing work.

  In the above embodiment, the example in which the relay member 36, the closing plate 37, and the abutting member 44 are fixed to the airtight sheet 40 with double-sided tape or the like has been described. The flat bar 62 may be fixed with screws or the like.

  The above embodiment is for facilitating the understanding of the present invention, and is not intended to limit the present invention. The present invention can be changed and improved without departing from the gist thereof, and it is needless to say that the present invention includes equivalents thereof.

10 hollow structure, 10a ceiling surface, 10b floor surface, 10c gap,
12 slabs, 19 hoisting machines, 21 column beam frames, 21a steel beams,
21b steel column, 24 intermediate beam, 24a right flange,
24b left flange, 25 door, 28 side walls, 28a landing doorway,
30 partition walls, 31 asbestos, 32 wires, 33 wire pairs,
34 wall member, 36 relay member, 36a contact plate part, 36b fixing plate part,
36c relay member, 37 closing plate, 38 scattering prevention sheet, 39 sealing material,
40 airtight sheet, 42 scattering prevention agent, 44 abutting member (covering member),
46 rock wool, 46a clearance, 47 47 square pipe material, 48 mounting hardware,
48a engaging portion, 49 steel plate panel, 49a upper steel plate panel, 49b lower steel plate panel,
61 Temporary steel beam, 61a Locking part, 61b Wire clip,
61c shackle, 61d turnbuckle, 61e load cell,
62 flat bar, 63 U bolt, 65 long bolt, 66 nut,
67 bolts, 71 gondola, 73 wires, 75 hoisting machine,
EV elevator, EVH elevator hall,
EVS elevator shaft, TR lifting space,
TRL Left and right lifting space, TRC central lifting space,
TRR right side lift space, WS work space,
WSA working space, WSB working space

Claims (11)

A deposit treatment method for treating deposits in a hollow structure having an internal space in which at least three lifting spaces for moving up and down the object are set in parallel in the horizontal direction,
In the intermediate elevating space excluding the elevating space located at both ends of the at least three elevating spaces, the hollow structure is preliminarily processed in the first working space, and the post working space is processed later. A partitioning step for forming a partition wall for hermetically partitioning;
The post-work space is in a state in which the object can be moved up and down, and the deposit processing step of performing the treatment in the previous work space,
A method for treating a deposit, characterized by comprising: It is the processing method of the deposit | attachment of Claim 1, Comprising:
The partitioning step is
A base arrangement step of providing a wall base material from the ceiling surface to the floor surface of the hollow structure in the intermediate lifting space;
A wall surface forming step for attaching a wall surface material by providing a gap between the wall base material provided and the inner peripheral surface of the hollow structure,
A closing step of closing the gap by attaching a relay member connecting the end of the wall material and the inner peripheral surface of the hollow structure;
A method for treating a deposit, characterized by comprising: It is a processing method of the deposit according to claim 2,
When the gap closed by the relay member is a gap between the end of the wall surface material and the deposit, the scattering prevention sheet is provided on the surface of the deposit to form the inner peripheral surface. And a deposit processing method. It is a processing method of the deposit according to claim 3,
The relay member is fixed to the wall surface material from the rear work space side,
In the deposit treatment step,
Remove the deposit on the side of the previous work space, and paint a scattering inhibitor on the removed site,
When the relay member in contact with the scattering prevention sheet is removed, a cover member that covers a portion where the previous work space communicates with the rear work space is fixed to the wall material from the previous work space side. ,
After attaching a new deposit different from the deposit on the side of the previous work space from the covering member of the part coated with the anti-scattering agent on the side of the previous work space,
A deposit processing method, comprising: removing the relay member from the rear work space side to remove the deposit in the rear work space. It is the processing method of the deposit | attachment of Claim 4, Comprising:
After coating the anti-scattering agent on the site where the deposit has been removed in the post-work space,
The method for treating deposits, comprising depositing the newly deposited deposits on the rear work space side of the covering member. It is a processing method of the deposit according to claim 5,
The covering member has a flat plate shape and is disposed along a crossing direction intersecting with the part coated with the anti-scattering agent, and the edge of the covering member is brought into contact with the part coated with the anti-scattering agent. ,
The depositing method according to claim 1, wherein the covering member is pulled out in the intersecting direction and removed after the newly deposited matter is attached to the rear working space side of the covering member. It is the processing method of the deposit | attachment of Claim 6, Comprising:
A method for treating deposits, comprising filling the newly deposited deposits into a portion where the covering member has been pulled out. A method for treating a deposit according to any one of claims 2 to 7,
A depositing method, wherein a sealing material is filled between the relay member and the scattering prevention sheet. A method for treating a deposit according to any one of claims 2 to 8, comprising:
In the partitioning step,
In the underlaying step, a wire is stretched from the ceiling surface to the floor surface of the hollow structure, and the stretched wire crosses the left-right direction with a space in the vertical direction. Fixing a plurality of plate-like members along
In the said wall surface formation process, an airtight sheet | seat is affixed on the said several plate-shaped member as said wall surface material from the said each of the left and right each side, The processing method of the deposit | attachment characterized by the above-mentioned. Method of installing a partition wall for partitioning the hollow structure in the hollow structure having an internal space in which at least three lifting spaces for moving up and down the object are set in parallel in the horizontal direction. Because
A base arrangement step of providing a wall base material from the ceiling surface to the floor surface of the hollow structure in an intermediate lift space excluding the lift space positioned at both ends of the at least three lift spaces;
A wall surface forming step for attaching a wall surface material by providing a gap between the wall base material provided and the inner peripheral surface of the hollow structure,
A closing step of closing the gap by attaching a relay member connecting the end of the wall material and the inner peripheral surface of the hollow structure;
A partition wall installation method characterized by comprising: A partition wall for partitioning the hollow structure when processing the adhering substance in the hollow structure having an internal space in which at least three lifting spaces for moving up and down the object are set in parallel in the horizontal direction. ,
A wall base material provided from the ceiling surface to the floor surface of the hollow structure in an intermediate lifting space excluding the lifting space located at both ends of the at least three lifting spaces;
A wall surface material attached to the wall base material provided with a space between the inner peripheral surface of the hollow structure, and
A relay member that connects the end of the wall material and the inner peripheral surface of the hollow structure to close the gap and is attached to the wall material;
A partition wall characterized by comprising: