JP5522694B2 - Exterior part construction method - Google Patents

Description

  The present invention relates to an exterior part construction method. Specifically, the present invention relates to an exterior part construction method for constructing an exterior part at a predetermined interval on the outside of an outer wall surface of a structure.

  2. Description of the Related Art Conventionally, an exterior panel is attached around a building, and an outer wall surface is constructed using the exterior panel. Specifically, the exterior panel is attached to a structure such as a floor or a beam on the outer periphery of a building via a fastener (see Patent Document 1).

JP 2010-59639 A

By the way, the exterior panel may be provided at a predetermined interval from the building. In this case, since the space | interval of the outer wall surface of a building and an exterior part becomes wide, the above-mentioned fastener cannot be used, for example, a bar-shaped support member is used to support an exterior panel on the building structure.
Such an exterior panel is attached from the lower layer to the upper layer while being supported by the support member from the building, but the uppermost exterior panel in the middle of assembly may not be supported reliably, so that the construction safety and construction It was difficult to ensure accuracy.

  An object of this invention is to provide the exterior part construction method which can construct | assemble an exterior part safely and accurately.

  The exterior part construction method according to claim 1 is an exterior part construction method for constructing an exterior part extending in a vertical direction at a predetermined interval from an outer wall surface of a structure, wherein the exterior part is a predetermined position on the outer wall surface. The structure is supported by the structure via a plurality of support members disposed in the assembly, and is assembled from the lower layer to the upper layer while supporting the exterior portion with the support member. The uppermost member of the exterior portion is temporarily supported on the structure by a temporary support member.

  According to this invention, when the exterior part is assembled from the lower layer to the upper layer, the uppermost member in the middle of the assembly is temporarily supported on the structure by the temporary support member. Therefore, since the uppermost member can be reliably supported from the structure even during assembly, the exterior portion can be constructed safely and accurately.

  The exterior part construction method according to claim 2 is characterized in that the temporary support member is used after being changed from a lower layer to an upper layer.

  According to this invention, since the temporary support member is used after being changed from the lower layer to the upper layer, the number of temporary support members manufactured can be reduced, so that the construction cost can be reduced.

  The exterior part construction method according to claim 3 is characterized in that the height level of the uppermost member is adjusted by adjusting the length of the temporary support member.

  According to this invention, the length of the temporary support member is adjusted, and the level of the uppermost member is adjusted. Therefore, the position and posture of the member constituting the exterior part can be easily adjusted to further improve the construction accuracy. it can.

  According to the present invention, when the exterior part is assembled from the lower layer to the upper layer, the uppermost member in the middle of the assembly is temporarily supported by the structure with the temporary support member. Therefore, since the uppermost member can be reliably supported from the structure even during assembly, the exterior portion can be constructed safely and accurately.

It is a cross-sectional view of the wing part of the building to which the exterior part construction method concerning one embodiment of the present invention was applied. It is II-II sectional drawing of the building which concerns on the said embodiment. It is a perspective view which shows the arrangement pattern of the needle and rod which concern on the said embodiment. It is an expansion perspective view of the 1st layer part of the arrangement pattern concerning the embodiment. It is a figure for demonstrating the procedure which builds the wing part which concerns on the said embodiment. It is a perspective view of the temporary rod which concerns on the said embodiment. It is an enlarged view of the adjustment mechanism of the temporary rod which concerns on the said embodiment.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a cross-sectional view of a wing part 20 of a building 1 to which an exterior construction method according to an embodiment of the present invention is applied, and FIG. 2 is a II-II cross-sectional view of the building 1.
The building 1 has a substantially shape in plan view, and both end portions on the front side of the building 1 are recessed portions 2 recessed inward. On the front side of the building 1, a wing portion 20 is provided as an exterior portion that protrudes laterally and extends in the vertical direction so as to cover the recess 2.

  Hereinafter, the left wing portion 20 will be described when the building 1 is viewed from the front side. The right wing part 20 has the same configuration as the left wing part 20.

  The building 1 includes a plurality of columns 10, a plurality of beams 11 installed between the column heads of the columns 10, a floor slab (not shown) supported by the beams 11, and a plurality of beams supported by the outer circumferential beams 11. Curtain wall 12.

  A bracket 13 is attached to the outer circumferential beam 11 at a predetermined location, and the curtain wall 12 is attached to the tip of the bracket 13 via a fastener 14.

  The curtain wall 12 has a rectangular plate shape and is arranged side by side in the horizontal direction and the vertical direction to form the outer wall surface 3 that partitions indoors and outdoors.

Hereinafter, the outer wall surface 3 on the front side of the recess 2 is referred to as an outer wall surface 3A, the outer wall surface 3 on the side surface side of the recess 2 is referred to as an outer wall surface 3B, and the outer wall surface 3 on the front side of the building 1 is referred to as an outer wall surface 3C.
The outer wall surface 3 </ b> A includes three curtain walls 12 arranged in the horizontal direction, and these curtain walls 12 are supported by fasteners 14 provided on the four brackets 13.

Two of the four brackets 13 are provided with connecting plates 15A and 15B at the center, and these connecting plates 15A and 15B project outside from the outer wall surface 3A through the gap between the curtain walls 12. Yes.
Here, of the connection plates 15A and 15B, the one located on the inner side (outer wall surface 3B side) is referred to as a connection plate 15A, and the one located outside is referred to as a connection plate 15B.

The wing portion 20 extends substantially parallel to the outer wall surface 3C from the corner of the outer wall surface 3B and the outer wall surface 3C.
The wing portion 20 is separated from the outer wall surface 3A by a predetermined distance via needles 30A, 30B, 30C and rods 40A, 40B, 40C, 40D as a plurality of support members provided at predetermined positions on the outer wall surface 3A. 1 is supported by the structure.

  The appearance of the wing portion 20 is the same as the appearance of the outer wall surface 3C of the building 1, and the front surface of the wing portion 20 is flush with the outer wall surface 3C of the building 1. For this reason, in the external appearance (facade) of the front of the building 1, the recessed part 2 is hidden.

  The wing portion 20 is provided at the floor level of each layer and extends in the horizontal direction, and a plurality of T-shaped mullion supports 22A that are provided in two rows in the vertical direction and connect the wind-resistant beams 21 to each other. 22B, and the wind-resistant beam 21 and the flat plate-like panel 23 attached to the mullion supports 22A and 22B.

The wind resistant beam 21 is connected to the bracket 13 at the corner of the outer wall surface 3 </ b> C and the outer wall surface 3 </ b> B via the joint piece 24.
Here, of the mullion supports 22A and 22B, the one located on the inner side (outer wall surface 3C side) is the mullion support 22A, and the one located on the outer side is the mullion support 22B.

FIG. 3 is a perspective view showing an arrangement pattern of the needles 30A to 30C and the rods 40A to 40D.
The arrangement of 30A to 30C and the rods 40A to 40D that support the wing portion 20 is configured such that six lots from the first layer to the sixth layer are one lot and this lot is repeated a plurality of times.

The needle 30A is provided in the sixth layer, extends substantially horizontally from the connection plate 15A, and is coupled to the position of the mullion support 22A of the wind-resistant beam 21 having the same height as the connection plate 15A.
The needle 30B is provided in all layers from the first layer to the sixth layer, extends substantially horizontally from the connection plate 15B, and is connected to the position of the mullion support 22B of the wind-resistant beam 21 having the same height as the connection plate 15B. ing.
The needle 30C is provided in the sixth layer, extends substantially horizontally from the connection plate 15B toward the outside, and is connected to the outer end portion of the wind-resistant beam 21 having the same height as the connection plate 15B.

The rod 40A is provided in the first layer, extends obliquely downward from the connection plate 15A, and is coupled to the position of the marion support 22A of the wind-resistant beam 21 below the connection plate 15A.
The rod 40B is provided in the first layer, extends obliquely downward from the connection plate 15B, and is coupled to the position of the marion support 22B of the wind-resistant beam 21 below the connection plate 15B.
The rod 40C is provided in the first layer, extends obliquely downward from the connection plate 15B toward the outside, and is coupled to the outer end portion of the wind-resistant beam 21 below the connection plate 15B.
The rod 40D is provided in the first layer, extends obliquely upward from the connection plate 15B, and is coupled to the position of the marion support 22B of the wind-resistant beam 21 on the upper layer of the connection plate 15B.

FIG. 4 is an enlarged perspective view of the first layer portion of the arrangement pattern. In FIG. 4, only the wind-resistant beam 21 in the wing portion 20 is displayed.
The rods 40A to 40D include a fork end 41 connected to the connection plates 15A and 15B protruding from the outer wall surface 3A, a fork end 42 connected to the wind-resistant beam 21, and a rod-like rod connecting the fork ends 41 and 42. A main body 43.

  The fork end 41 is rotatably connected to the connection plates 15A and 15B with a direction along the outer wall surface 3A being substantially horizontal and a rotation axis.

  A connection plate 211 projects from the upper or lower surface of the wind-resistant beam 21. The fork end 42 is rotatably connected to the connection plate 211 with a direction along the outer wall surface 3 </ b> A being substantially horizontal.

The above wing part 20 is constructed | assembled in the following procedures.
That is, as shown in FIG. 5, a suspension scaffold 50 having a height corresponding to three layers is assembled in the recess 2 and is suspended and supported from the structure of the building 1. While raising the suspension scaffold 50, the needles 30A to 30C and the rods 40A to 40D are attached, and the wing portions 20 are assembled one layer at a time.

  In this assembling process, a temporary rod 60 is prepared as a temporary support member, and the temporary windproof beam 21 in the middle of the assembly is temporarily supported from the connection plate 15B of the building 1 by using the temporary rod 60. The height level of the uppermost wind resistant beam 21 is adjusted by adjusting the length of 60. The arrangement of the temporary rod 60 is indicated by a broken line in FIG.

  Here, the temporary rod 60 is used by changing from the lower layer to the upper layer. Specifically, the temporary rod 60 below two layers is removed and used.

FIG. 6 is a perspective view of the temporary rod 60.
The temporary rod 60 includes a fork end 61 connected to the connection plate 15B protruding from the outer wall surface 3A, a rod-shaped rod body 62 connected to the fork end 61, a fork end 63 connected to the wind-resistant beam 21, A rod-shaped rod main body 64 connected to the fork end 63 and an adjusting mechanism 65 capable of adjusting the distance between the rod main bodies 62 and 64 are provided.

  The fork end 61 is rotatably connected to the connection plate 15B with a direction along the outer wall surface 3A being substantially horizontal and a rotation axis.

  A connection plate 211 is attached to the upper surface of the wind resistant beam 21. The fork end 63 is rotatably connected to the connection plate 211 with a direction along the outer wall surface 3A being substantially horizontal and a rotation axis.

FIG. 7 is an enlarged view of the adjustment mechanism 65 of the temporary rod 60.
The adjustment mechanism 65 includes a box-shaped main body 651 having a predetermined length, a sliding portion 652 that can slide in the length direction on the main body, and a hydraulic mechanism 653 that moves the sliding portion 652 back and forth.
The rod main body 62 is fixed to one end surface of the main body.
The rod main body 64 passes through the other end surface of the main body and is fixed to the sliding portion 652.

In the adjustment mechanism 65, the length of the temporary rod 60 is adjusted by the following procedure.
First, the manual hydraulic pump 66 is connected to and driven by the hydraulic mechanism 653 so that the sliding portion 652 advances and retracts, the distance between the rod bodies 62 and 64 is adjusted, and the length of the temporary rod 60 is adjusted.
Next, the rod body 64 is locked with the other end side of the main body 651 by fastening with the nut 654, and the length of the temporary rod 60 is fixed.
Thereafter, the hydraulic pump 66 is removed from the hydraulic mechanism 653.

According to this embodiment, there are the following effects.
(1) When the wing portion 20 is assembled from the lower layer toward the upper layer, the uppermost wind resistant beam 21 in the middle of the assembly is temporarily supported on the building 1 by the temporary rod 60. Therefore, since the uppermost wind-resistant beam 21 can be reliably supported from the structure of the building 1 even during assembly, the wing portion 20 can be constructed safely and accurately.

  (2) Since the temporary rod 60 is used by changing the order from the lower layer to the upper layer, the number of temporary rods 60 manufactured can be reduced, so that the construction cost can be reduced.

  (3) The length of the temporary rod 60 is adjusted to adjust the level of the uppermost wind-resistant beam 21. Therefore, the position and posture of the wind-resistant beam 21 constituting the wing portion 20 can be easily adjusted to improve the construction accuracy. It can be further improved.

  It should be noted that the present invention is not limited to the above-described embodiment, and modifications, improvements, etc. within a scope that can achieve the object of the present invention are included in the present invention.

1 ... Building (structure)
DESCRIPTION OF SYMBOLS 2 ... Recess 3 ... Outer wall surface 3A ... Outer wall surface on the front side of the recess 3B ... Outer wall surface on the side surface of the recess 3C ... Outer wall surface on the front side of the building 10 ... Column 11 ... Beam 12 ... Curtain wall 13 ... Bracket 14 ... Fastener 15A, 15B ... connection plate 20 ... wing part (exterior part)
21 ... Wind resistant beams 22A, 22B ... Marion support 23 ... Panel 24 ... Joint piece 30A, 30B, 30C ... Needle (support member)
40A, 40B, 40C, 40D ... Rod (supporting member)
41, 42 ... Fork end 43 ... Rod body 50 ... Suspension scaffold 60 ... Temporary rod (temporary support member)
DESCRIPTION OF SYMBOLS 61 ... Fork end 62 ... Rod main body 63 ... Fork end 64 ... Rod main body 65 ... Adjustment mechanism 66 ... Hydraulic pump 211 ... Connection plate 651 ... Main body 652 ... Sliding part 653 ... Hydraulic mechanism

Claims (3)

It is an exterior part construction method for constructing an exterior part extending in the vertical direction at a predetermined interval away from the outer wall surface of the structure,
The exterior part is a structure supported by the structure via a plurality of support members arranged at predetermined positions on the outer wall surface,
While assembling from the lower layer to the upper layer while supporting the exterior part with the support member,
In the assembling step, a method for constructing an exterior part is characterized in that the uppermost member of the exterior part during assembly is temporarily supported by the structure with a temporary support member.   The method for constructing an exterior part according to claim 1, wherein the temporary support member is used after being changed from a lower layer to an upper layer.   The exterior part construction method according to claim 1, wherein a height level of the uppermost member is adjusted by adjusting a length of the temporary support member.

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