JP3222488U - Handrail support fixing structure - Google Patents

Abstract

Provided is a handrail post fixing structure that can easily secure the handrail fixing strength to a structure. A handrail body is fixed to a rising portion of a veranda through a handrail post and a fixing plate. The handrail post is inserted into the through hole 122 and welded to the fixed plate 120 over the welding range W. The welding range W extends over the entire circumference of the four side surfaces of the handrail support in plan view, and extends from the upper opening 122a of the through hole 122 to the lower opening 122b in the vertical direction. [Selection] Figure 5

Description

  The present invention relates to a fixing structure of a handrail post.

  Handrails, an example of which is shown in Patent Document 1, may be installed on a structure.

JP 2010-242457 A

  There is a demand for a fixing structure that can withstand high wind pressure in a handrail support for installing a handrail as in Patent Document 1 on a structure. For example, handrails installed on the verandas of super high-rise apartment buildings that have been frequently built in densely populated areas are exposed to high wind pressure on high floors.

  The objective of this invention is providing the fixing structure of the handrail support | pillar which is easy to ensure the fixed intensity | strength with respect to a structure.

  The fixing structure of the handrail post according to the present invention is a fixing structure for fixing the handrail support to the structure, and includes a fixing member fixed to the structure, and the handrail support is welded to the fixing member. ing.

  According to the fixing structure of the handrail support of the present invention, the strength of the fixing portion between the handrail support and the fixing member is ensured by welding. Therefore, the strength of the entire fixing structure can be easily secured.

  In the present invention, it is preferable that a through hole is formed in the fixing member, and the handrail support column is inserted into the through hole and welded to the fixing member. According to this, the handrail post is welded to the fixing member after being inserted into the through hole. For this reason, it is easy to ensure the strength of the handrail support and the fixing portion of the fixing member.

  Further, in the present invention, the handrail support column is inserted into the through hole from one opening portion to the other opening portion of the through hole, and a welding range between the handrail support column and the fixing member is the one side. Preferably, the second opening extends from the second opening to the second opening. According to this, since the welding range is wide, it is easy to ensure the strength of the fixing portion of the handrail support and the fixing member.

  In the present invention, the handrail post is preferably made of duplex stainless steel. According to this, the strength of the handrail post is secured. The duplex stainless steel corresponds to SUS821L1, SUS323L, SUS329J1, SUS329J3L, SUS329J4L, SUS327L1, and the like in JIS standards.

  In the present invention, the handrail post may be used by being fixed to a veranda on a higher floor of an apartment. The external force that the handrail receives due to the wind pressure on the upper floors (floors of 60m or more above the ground or 20th floor or more) increases. The present invention is easy to ensure the strength according to the installation environment by the handrail support column using the duplex stainless steel.

It is a perspective view of a handrail unit concerning a 1st embodiment which is one embodiment of the present invention. It is the II-II sectional view taken on the line of FIG. 1 handrail unit. It is the III-III sectional view taken on the line of FIG. 1 handrail unit. It is a top view of the stationary plate used for the handrail unit of FIG. It is sectional drawing of the fixing | fixed part of the handrail support column and fixing plate which were used for the handrail unit of FIG. It is sectional drawing which concerns on the modification of the fixing | fixed part of FIG. It is a disassembled perspective view of the handrail fixing part which concerns on 2nd Embodiment which is another embodiment of this invention. It is the VIII-VIII sectional view taken on the line of FIG.

First Embodiment
Hereinafter, a handrail unit 1 according to a first embodiment which is an embodiment of the present invention will be described with reference to FIGS. The handrail unit 1 is fixed to a concrete rising portion 90 of a veranda shown in FIG. As shown in FIGS. 1 to 3, the handrail unit 1 includes a handrail main body 10 and a handrail fixing portion 100 for fixing the handrail main body 10 to the rising portion 90. The handrail main body 10 has a rectangular frame having a bush 11 and a lower chord 12 along the horizontal direction, and a column 13 along the vertical direction, and a glass plate 14 fitted in the frame. The handrail fixing portion 100 has a handrail support 110 along the vertical direction, and a fixing plate 120 (a fixing member in the present invention) to which the handrail support 110 is fixed. The handrail support 110 is a square pipe made of duplex stainless steel having a rectangular cross section. Duplex stainless steel (for example, SUS821L1) is a material having high strength and corrosion resistance as compared to stainless steel such as SUS304. A support 13 is fixed to the handrail support 110 by a bolt 15 (see FIGS. 2 and 3) and a nut (not shown). The fixing plate 120 is a flat plate-like member along a horizontal surface, and is fixed to the rising portion 90 by four adhesive system anchors 131. Thus, the handrail main body 10 is fixed to the rising portion 90. The bolt used for the adhesive anchor 131 may be made of metal other than duplex stainless steel as shown in the examination example described later, but is preferably made of duplex stainless steel.

  Next, the handrail support 110 and the fixing portion of the fixing plate 120 will be described in more detail. As shown in FIG. 4, the fixing plate 120 has four circular through holes 121 into which the adhesive anchor 131 is inserted and one rectangular through hole 122. The through hole 122 is formed slightly larger than the handrail support 110. Further, the corners of the upper opening 122a of the through hole 122 are rounded as shown in FIG. As shown in FIG. 5, the handrail column 110 is inserted into the through hole 122 from the upper opening 122a to the lower opening 122b. The lower end of the handrail post 110 is located at the lower opening 122b.

  The handrail support 110 and the fixing plate 120 are welded to each other in the through hole 122. The welding range W between the handrail post 110 and the fixed plate 120 extends over the entire four sides of the through hole 122 as shown in FIG. In other words, welding range W extends over the entire circumference of four side surfaces of handrail support 110. As shown in FIG. 5, the welding range W extends from the upper opening 122a to the lower opening 122b in the vertical direction. Such welding is performed as follows after the handrail support 110 and the fixing plate 120 are produced. First, the handrail support 110 is inserted from the upper opening 122a into the through hole 122 until one end of the handrail support 110 reaches the lower opening 122b. Thereafter, welding is performed while the welding rod is in contact with the groove formed between the rounded upper opening 122a and the side surface of the handrail post 110. At this time, if the welding conditions are appropriately adjusted, the metal melted in the groove enters the gap between the side surface of the handrail post 110 and the inner surface of the through hole 122 from the upper opening 122a and flows down in the gap. And reaches the lower opening 122b. As welding conditions, it is preferable that the clearance between the side surface of the handrail post 110 and the inner surface of the through-hole 122 is appropriate and the welding heat input is appropriately adjusted. By carrying out such welding over the entire circumference of the four side surfaces of the handrail support 110, the handrail support 110 and the fixed plate 120 are welded over the entire welding range W.

  Note that the handrail support column 110 and the fixed plate 120 may be welded as shown in a welding range W ′ of FIG. 6. The welding range W ′ extends over the entire circumference composed of the four side surfaces of the handrail post 110, but only the vicinity of the upper opening 122a and the lower opening 122b is the range in the vertical direction. In this case, it is preferable that the lower opening 122b is also formed in the same rounded shape as the upper opening 122a. According to this, a groove is formed between the upper opening 122a and the lower opening 122b with the side surface of the handrail column 110. Therefore, by bringing the welding rod into contact with the groove, the welding range W ′ can be expanded inside the through hole 122 to some extent. Thus, the strength of the handrail support 110 and the fixing portion of the fixing plate 120 can be easily secured. However, according to such a method, welding needs to be performed on each of the upper opening 122 a and the lower opening 122 b. For this reason, compared with the above-mentioned method in which welding is performed only on the upper opening 122a side, the welding procedure is increased. Therefore, it is preferable to use the above method from the viewpoint of productivity.

As an example of examination according to the above-described embodiment, the configuration of the handrail support 110 for ensuring the necessary strength was examined as follows. The examination was based on the “Guidelines on Aluminum Handrail Strength for Apartment Houses (Wind Load)” (published by the Japan Aluminum Handrail Industry Association in June 2014; hereinafter referred to as “Guidelines”). In addition, the installation place of the handrail unit 1 is a veranda of a high floor of a super high-rise apartment (for example, height 100 m or 150 m) built in Sapporo city 500 m or more away from the coast, and the reproduction period is assumed to be 100 years. The super high-rise apartment generally refers to an apartment having a height of 60 m or more, or approximately 20 stories or more. When the average speed pressure acting on the handrail unit 1 is Q [N / m ² ] and the peak wind force coefficient is Cr, the design wind pressure W required for the handrail unit 1 is as shown in the following Equation 1. Q is expressed by the following formula 2.

［数式２］

Ｅｒ：平均風速の鉛直分布を示す係数
Ｖ₀：基準風速［ｍ／ｓ］
ｙ：再現期間係数 [Equation 1]

[Equation 2]

Er: Coefficient showing vertical distribution of average wind speed V ₀ : Reference wind speed [m / s]
y: Reproduction period coefficient

When the height of the building is 100 m or 150 m, Er = 1.26 (100 m) or 1.36 (150 m) according to the guidelines. In addition, in calculation of this Er, it was based on Category III (ground surface roughness category I, II, general area other than IV) of Table 1 of a guideline. When the installation place is Sapporo City, V ₀ = 32. Furthermore, since the reproduction period is 100 years, y = 1.07. Cr was set to 1.5 (positive pressure) and -1.5 (negative pressure) corresponding to the center part in FIG. 3 of the guideline. In this case, W is calculated as follows. [] Indicates the height of the building.

[100m]
W = 1,676 N / m ² (positive pressure), -1,676 N / m ² (negative pressure)
[150m]
W = 1, 982 N / m ² (positive pressure), -1, 982 N / m ² (negative pressure)

For example, in the glass plate 14 or the like of the handrail unit 1, assuming that the area of the wind receiving surface is 1.57 m ² per handrail post 110, the wind pressures P 1 and P 2 acting on each handrail post 110 are as follows: It becomes as follows. P1 indicates the wind pressure when the height of the building is 100 m, and P2 indicates the wind pressure when the height of the building is 150 m.

P1 = 2, 632 N (positive pressure), -2, 632 N (negative pressure)
P2 = 3, 112 N (positive pressure), -3, 112 N (negative pressure)

  Next, the handrail support 110 made of SUS821L1 was configured with a thickness (wall thickness) of 2 mm, an outer diameter of 45 mm × 45 mm, and a height of 1,000 mm. When this handrail support 110 was subjected to a destructive test against an external force assuming wind pressure, the external force corresponding to 2% proof stress was about 5,600N. Thus, it was confirmed that the handrail support 110 made of the duplex stainless steel having the above configuration can sufficiently cope with the wind pressures P1 and P2.

  Further, as another examination example according to the above-described embodiment, the adhesive anchor 131 that can cope with the case where the wind pressure of P1 or P2 acts on the handrail column 110 was examined as follows. In the examination, it is assumed that the handrail column 110 has a thickness of 2 mm, an outer diameter of 50 mm × 50 mm, and a height of 1,000 mm, and a height of 500 mm on one side of the handrail column 110 (half of the entire column) It was assumed that the wind pressure of P1 or P2 acts in the center with respect to the width direction of the height position of. Further, the fixed plate 120 has a size of 150 mm in length and 150 mm in width in the plan view shown in FIG. Of 25 mm in length and 50 mm in length and 50 mm in width of the through hole 122 are assumed. In this case, the tensile load acting on the adhesive anchor 131 is F1 = 15.8 kN or F2 = 18.7 kN. F1 represents a load for the wind pressure P1, and F2 represents a load for the wind pressure P2. Such a tensile load can be dealt with by using a bolt length of about 150 mm of HIT-HY200 series and HIT-Z M12 manufactured by HILTI, for example. HIT-Z M12 is made of SUS316.

  If a bolt made of a duplex stainless steel such as SUS821L1 having a higher strength than SUS316 is used as the bolt of the adhesive anchor 131, a bolt having a smaller bolt diameter can be used in a range that can handle the tensile load. . Therefore, the design of the handrail unit 1 can be improved. Similarly, the bolt 15 and the nut for fixing the column 13 of the handrail main body 10 and the handrail column 110 are also made of duplex stainless steel, so that the bolt is thinner and smaller than the case of using a bolt made of SUS304 or SUS316. A nut can be used. Therefore, the design of the handrail unit 1 can be improved.

  According to this embodiment described above, the fixing plate 120 to which the handrail support 110 is fixed by welding is fixed to the rising portion 90 of the veranda by the adhesive anchor 131. Therefore, the fixing portions of the handrail support 110 and the fixing plate 120 are secured by welding. Thereby, the strength of the entire handrail fixing portion 100 can be easily secured. Further, when the handrail unit 1 is installed, for example, after fixing the fixing plate 120 to the rising portion 90, the handrail main body 10 is fixed to the handrail column 110, whereby the handrail unit 1 can be easily fixed to the rising portion 90.

  Moreover, in the present embodiment, the handrail support 110 is made of duplex stainless steel. For this reason, the strength of the handrail unit 1 is ensured even in an installation environment where a high wind pressure is assumed, such as a high-rise floor of a super high-rise apartment.

  In this embodiment, the welding range W extends from the upper opening 122a of the through hole 122 to the lower opening 122b. Therefore, since the handrail support 110 is welded to the fixed plate 120 over a wide range, the strength of the fixing portion between the handrail support 110 and the fixed plate 120 is easily secured.

Second Embodiment
Next, a handrail fixing portion 200 according to a second embodiment, which is another embodiment of the present invention, will be described with reference to FIGS. 7 and 8. The handrail fixing portion 200 can be employed in place of the handrail fixing portion 100 in the first embodiment.

  The handrail fixing unit 200 includes the same handrail support column 110 as that of the first embodiment and an anchor 210 (fixing member in the present invention) to which the handrail support column 110 is fixed. The anchor 210 has a column reinforcing portion 201, a plate portion 211 and four L-shaped portions 212. The L-shaped portion 212 is fixed to the plate portion 211. Each L-shaped portion 212 extends vertically downward from the lower surface of the plate portion 211 and is bent in a bowl shape toward one side in the horizontal direction at the lower end portion. The lower end is welded to a reinforcing bar (not shown) embedded in the rising portion 90.

  The column reinforcement 201 is a cylindrical member made of duplex stainless steel or other stainless steel, and is fixed while being inserted into the lower end of the handrail column 110. The column reinforcing portion 201 is fixed to the handrail column 110 by welding or a fixing tool such as a bolt. In the present embodiment, the handrail column 110 and the column reinforcement portion 201 as a whole correspond to the handrail column in the present invention. The lower end of the column reinforcing part 201 is welded to the upper surface of the plate part 211 of the anchor 210 as shown in FIG. The welded portion 213 of the support column reinforcement portion 201 and the plate portion 211 extends over the entire circumference of the side surface of the support column reinforcement portion 201. Similarly to the first embodiment, a through hole is formed in the plate portion 211, and the column reinforcing portion 201 may be inserted into the through hole and welded to the plate portion 211 in the through hole. The lower ends of the handrail support 110 and the support reinforcing part 201 are embedded in the upper part of the rising part 90 using a filler such as grout mortar.

  According to the present embodiment described above, the handrail reinforcement portion 201 is welded to the anchor 210 as in the first embodiment. Therefore, the fixing portion of the handrail reinforcement portion 201 and the anchor 210 is secured by welding. Thereby, the strength of the entire handrail fixing portion 200 can be easily secured.

<Modification>
The above is a description of a preferred embodiment of the present invention, but the present invention is not limited to the above-described embodiment, and various modifications are possible within the scope described in the means for solving the problem. It is possible.

  For example, in the above-described embodiment, the handrail support 110 is made of duplex stainless steel, but may be made of other metals as long as it can secure the necessary strength. In addition, the handrail support 110 is a rectangular pipe having a rectangular cross section, but may have other shapes such as a hexagonal pipe or a round pipe. A solid rod-like member may be used as a handrail post.

  Moreover, in the above-mentioned embodiment, the case where the handrail unit 1 is installed in the veranda of the high-rise floor of a super high-rise apartment is mainly assumed. However, the present invention may be applied when installed in other buildings and civil engineering structures. For example, a building other than an apartment, a tower, a bridge or the like may be set as the installation place. In addition, a dam or an observation deck may be set as the installation place.

  Further, in the above-described embodiment, the handrail support 110 and the fixing plate 120 are welded over the welding range W in FIG. 5 and the welding range W ′ in FIG. 6. However, the handrail strut 110 and the fixing plate 120 may be welded in a manner different from these as long as the required strength is satisfied. For example, the welding area may not extend over the entire circumference of the four side surfaces of the handrail support 110. Further, the handrail support 110 may be welded to the fixed plate 120 after being inserted partway through the through hole 122. Also in these cases, it is preferable that welding be performed in the widest possible range. For example, the welding range may extend from the upper opening 122a of the through hole 122 to the middle between the upper opening 122a and the lower opening 122b in the vertical direction.

1 handrail unit 10 handrail main body 90 rising portion 110 handrail post 120 fixing plate 121, 122 through hole 122a upper opening 122b lower opening 131 adhesive system anchor

Claims (5)

A fixing structure for fixing the handrail post to the structure,
And a fixing member fixed to the structure;
The handrail support fixing structure according to claim 1, wherein the handrail support is welded to the fixing member. A through hole is formed in the fixing member,
The handrail post fixing structure according to claim 1, wherein the handrail post is inserted into the through hole and welded to the fixing member. The handrail column is inserted into the through hole from one opening to the other opening in the through hole,
The welding structure of the handrail column according to claim 2, wherein a welding area of the handrail column and the fixing member extends from the one opening to the other opening.   The handrail support structure according to any one of claims 1 to 3, wherein the handrail support is made of duplex stainless steel.   The said handrail support | pillar is being fixed to the veranda of the high-rise floor of an apartment, The fixing structure of the handrail support | pillar of Claim 3 characterized by the above-mentioned.

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