JP3207151B2 - Steel panel joint structure - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used for arch-like structures requiring high rigidity, such as a freezing warehouse buried on a mountain slope, in which a steel plate is disposed on an inner surface and a steel frame is disposed on an outer surface. The present invention relates to a joint structure of a steel panel.

[0002]

2. Description of the Related Art Shielding methods are widely used for tunnel construction for railways and roads, and for tunnels for water supply and sewerage work underground in urban areas. In these shield tunnels, after the shield excavation work, a segment made of concrete, casting, or the like is laid as a structure behind the excavator body.

On the other hand, fresh foods such as vegetables, fish and meat are generally stored in warehouses near places where they are produced and harvested. Such perishable food is stored in a warehouse at a certain temperature, but it is difficult to construct a freezing warehouse in an area where the terrain is almost uphill, such as Japan, and keep it at a certain temperature. Therefore, the running cost of temperature control and energy supply was large, and construction was difficult.

Therefore, the present inventors have conceived of constructing a freezing warehouse on the slope of Gakuryo as a means for solving the above-mentioned problem. According to such a freezer warehouse, it is possible to construct in areas where it was conventionally difficult to construct, and because it can be buried in the mountain slope, the loss of energy previously emitted from the building during heat insulation can be reduced. Can be minimized.

[0005] In the above-mentioned shield method, it is difficult to construct a semi-cylindrical arch-shaped structure with a large cross section, and there is a problem that costs are high. Therefore, the above-mentioned freezing warehouse is made of steel. Assemble the unit panels to construct an arched roof with a one-way arch, and provide a masonry wall made of steel panels at both ends of the arched roof in the direction of the ridge. It is desirable to lay the soil and backfill the soil after curing the concrete.

However, the arch roof of such a freezer warehouse is subjected to a large load due to the soil of the mountain ridge, so that the steel unit panels are strongly bonded to each other in order to withstand the earth pressure of the mountain hill. Shall be taken.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a steel unit panel constituting an arch roof of an arch-like structure such as a freezing warehouse buried on a slope of Mt. It is an object of the present invention to provide a joint structure of steel panels that can be firmly joined to each other with a relatively simple configuration and that can provide an arch-like structure that can sufficiently withstand the earth pressure of Gakuryo.

[0008]

In order to achieve the above object, according to the present invention, an arch roof made of a steel plate located inside the roof and a steel frame material located outside the roof along the arch direction has a plurality of unit panels. In the arch-shaped structure configured in combination, in the arch direction joining of the unit panels, in the steel frame portion, the flanges of the steel frame material and the webs are bolted together via a splice plate, and in the steel plate portion, The ends of the steel plates are joined by welding, and the joint plates erected outside the roof of the steel plates are bolted together via splice plates. It is joined by welding with intervening.

[0009] In the above configuration, the foundation of the structure is constructed by excavating the soil such as the slopes of Gakuryo, and the unit panels of the arch roof are joined in the direction of the arch and the ridge of the building to form the foundation. Construct an arch roof, construct a masonry wall at both ends of the arch roof in the direction of the ridge, then cast concrete of a predetermined thickness on the outer surface of the arch roof and the masonry wall, fill the earth and sand after curing the concrete, and freeze Used as a warehouse.

[0010] When joining the unit panels in the arch direction, the steel members are bolted together via a splice plate, the steel plates are joined together by butt seal welding, and the joint plates are bolted together via a splice plate. In addition, the unit panels are joined in the direction of the ridge center by welding the ends of the steel plates to each other via a steel frame material, whereby the steel unit panels can be firmly joined by a relatively simple configuration. It is possible to construct an arch-like structure that can sufficiently withstand a large earth pressure or the like with a relatively simple joint structure.

When joining the unit panels in the arch direction, the steel plates are joined by seal welding so that the concrete to be poured does not leak, and the joint plates are bolted together via a splice plate. However, if the steel plates can be butted by full penetration welding to transmit the axial force, it is necessary to stand the joint plate on the outside of the steel plate roof and connect the joint plates with bolts via the splice plate. There is no.

However, the reason why the present invention avoids full penetration welding between steel sheets is as follows. Workability is poor because the welding operation is upward welding. A work base for performing welding work is required. Welding work is more difficult in upward welding than in downward welding. In addition, complete penetration is more difficult. Full penetration welding requires ultrasonic inspection. In view of the above problems and economy, the present invention has devised the above-described joint structure.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to an embodiment shown in the drawings. This is an example in which the present invention is applied to a freezing warehouse buried on the slope of Gakuryo. FIG. 1 shows a freezing warehouse as an arched structure according to the present invention. FIG. 2 shows the arch roof. FIG. 3 shows an arch roof unit panel. FIG. 4 shows a joint portion of the unit panel in the arch direction. FIG. 5 shows a bolt fastening portion of the joint plate. FIG. 6 shows a joint portion of the unit panel in the ridge direction. FIG. 7 shows a method of constructing a freezing warehouse in the order of steps.

As shown in FIG. 1, a freezing warehouse as an arch-like structure according to the present invention has an arch roof 1 having a semicircular cross section or the like and a predetermined length (one-way arch) in the direction of a ridge, and this arch. A roof wall 1 is provided for closing openings at both ends of the roof 1 in the ridge direction. Concrete 3 having a predetermined thickness is cast on the outer surface of the arch roof 1 and the outer surface of the mountain wall 2. Backfilled.

As shown in FIG. 2, the arch roof 1 has a semi-cylindrical steel plate 11 located on the inner surface side of the roof and also serving as a concrete form, and an outer surface of the steel plate 11 disposed in parallel with the arch direction A of the roof. A shell-type unit panel P composed of a semicircular steel frame member (H-section steel) 12 fixed to each other by welding and divided into a number of units and manufactured at the factory is joined in the arch direction A and the ridge direction B. It is built by doing.

As shown in FIG. 1, the end wall 2 comprises a semicircular steel plate 21 and a steel frame member (vertical bone) 22 which is disposed parallel to the vertical direction and fixed to the outer surface of the steel plate 21 by welding. It is constructed by joining a flat unit panel P, which is divided into a number of units and factory-manufactured, in the vertical (vertical) direction and the horizontal (horizontal horizontal) direction.

The unit panel P of the arch roof 1 is shown in FIG.
As shown in FIG.
And a plurality of arc-shaped steel members 12P arranged in parallel on the outer surface of the steel plate 11P at intervals. Steel 12
P is fixed to the steel plate 11P with fillet welds 13 to spliced the lower flange 12P ₂ to the outer surface of the steel sheet 11P.
Such unit panels P are joined as follows.

That is, the unit panels P are joined in the arch direction A in the steel frame portion, as shown in FIG. 4, at the upper flange 12P ₁ at the end of the steel frame material 12P.
The two are sandwiched between the upper and lower splice plates 30 and bolts 3
Fasten with 1. Web 12P ₃ each other, sandwiched between the left and right of the splice plate 32, is fastened with a bolt 33.

In the steel plate portion, the ends of the steel plate 11P in the arch direction A are abutted to each other to form a seal weld 34.
To prevent the concrete to be poured from leaking. Further, in addition to the seal welding 34, the ends of the steel plates 11P are fixed to each other using a joint plate 35 and a splice plate 37. Johnite Plate 35
Is a steel plate 12P adjacent to the joint end of each steel plate 11P.
The joint plate 35 is sandwiched between splice plates 37 and fastened with bolts 38. The joint plates 35 are fixed by a fillet weld 36 at an intermediate position between the steel plates 12P.

Here, the joint plate 35 is shown in FIG.
As shown in the figure, a pair may be provided. In this case,
As shown in FIG. 5, the bolts 38 of the adjacent joint plates 35 are disposed so as to be shifted from each other so that the bolts 38 do not interfere with each other.

As shown in FIGS. 6 (a) and 6 (b), the unit panels P are joined in the ridge direction B by joining the ends of the steel plates 11P in the ridge direction B by seal welding 40. The steel frame material 12P 'is arranged outside the steel plate 11P so as to straddle the joining line, and is fixed to each steel plate 11P by fillet welding 41 to reinforce the joint.

[0022] In this case, the sealing weld 40, because the overhead welding, the order to avoid this, as shown in FIG. 6 (c), 'the lower flange 12P _2' steel material 12P is steel 11P sandwiched between steel plates 11P so as to be positioned on the inner surface side is fixed to the lower flange 12P ₂ 'the end faces of the steel plate 11P in fillet welding 42. In this case, since the fillet weld 42 is a downward welding, the welding quality, the workability of welding, and the like are improved.

In the case of FIG. 6 (c), FIG. 3 (d)
As shown in the figure, the central portion of the steel plate 11P to which the steel frame material 12P is attached is directed downward so that the steel frame material 12P at the center of the unit panel and the steel frame material 12P 'at the end of the unit panel are arranged at the same level. It is processed so as to be displaced.

The steel frame 12P 'is an arc member having the same unit length as the steel frame 12P, and the steel frames 12P' are connected to each other by splice plates 30 and 32 similarly to the steel frame 12P.
Bolt.

In the freezing warehouse having the above-described structure, construction is performed according to the following procedure (see FIG. 7).

(1) The earth and sand 4 at a predetermined location on the mountain slope is cut open using heavy equipment such as a bulldozer or an excavator. The base part 5 is constructed at the freezer warehouse construction position on the open-cut ground.

(2) The shell-type unit panel P of the arch roof 1 manufactured in advance in the factory is carried in, and the semi-cylindrical arch roof 1 is constructed on the foundation 5. The unit panel A of the flat type of the end wall 2 is also carried in, and the end wall 2 is constructed on both ends of the arch roof 1 in the ridge direction.

(3) Concrete 3 having a predetermined thickness is cast on the outer surface of the steel plate 11 of the arch roof 1 and the outer surface of the steel plate 21 of the end wall 2. With respect to the dam wall 2, concrete is cast only on the mountainous side, but concrete may also be cast on the flat wall (where an entrance is formed).

(4) After the poured concrete 3 is cured until it is sufficiently dried, the earth and sand 4 generated by the excavation is backfilled, and the concrete wall 3 is buried while leaving the flat wall 2.

With the above-mentioned freezing warehouse, it is possible to construct even in an area where construction was conventionally difficult, and it is possible to combine the use of an area which is not normally used with effective installation conditions, and Open cuts can be made on the slopes of the mountain by civil engineering, and after the construction of the structure, construction can be carried out using general civil engineering techniques for backfilling the earth and sand. This can speed up construction and reduce costs. In addition, since the structure is buried on the mountain slope, energy loss that was conventionally emitted from the building during cold insulation can be minimized, and temperature management and energy supply running to maintain a constant temperature The cost can be significantly reduced.

The joint structure of the steel panels of the arch roof is such that, in the arch direction A, the steel members 12P fixed to the outer surface of the steel plate 11P to which the seal is welded are joined together by the splice plates 30 and 32 and the bolts 31 and 33. And the ends of the steel plates 11P are joined together by the joint plate 35,
It is fixed by the splice plate 37 and the bolt 38, and the force applied to the arch roof 1 can be transmitted effectively and smoothly. Further, also in the ridge center direction B, the ends of the steel plates 11P are fixed to each other by welding 41 (42) via the steel members 12P ', and are firmly fixed. From the above, it is possible to obtain an arch-like structure that can sufficiently withstand a large earth pressure or the like.

The freezing warehouse buried on the mountain slope has been described above. However, the present invention is not limited to this, and the present invention can be applied to arch-shaped structures that are installed on flat ground and need to withstand large forces. It goes without saying that you can do it. In addition, although a semicircular arch has been described, it is needless to say that the present invention is not limited to this.

[0033]

According to the present invention, there is provided an arch-shaped structure in which an arch roof made of a steel plate located on the inner side of the roof and a steel frame material located on the outer side of the roof along the arch direction is constituted by combining a plurality of steel panels. In the arch direction, the steel panels constituting the arch roof are connected by bolts between the flanges of the steel frame and the webs via the splice plate in the steel frame portion, and the ends of the steel plate in the steel plate portion. While joining by welding, joint plates erected on the outside of the roof of the steel plate are bolted via splice plates, and the joint of the steel panels in the ridge direction is
Since steel plates are joined by welding with steel members interposed, the steel panels that make up the arch roof of arched structures such as freezing warehouses buried on the slope of Gakuryo are relatively simple in configuration An arch-like structure that can be firmly joined and that can sufficiently withstand the earth pressure of Mt.

[Brief description of the drawings]

FIG. 1 is an example of an arch-shaped structure according to the present invention, in which (a) is a plan view, (b) is a longitudinal sectional view, and (c) is a front view.

FIG. 2 is an example of an arch roof according to the present invention, wherein (a) is a plan view and (b) is a side view.

FIG. 3 is an example of a unit panel of an arch roof according to the present invention, wherein (a) is a plan view, (b) is a top view, (c) is a bottom view,
(d) is an end view.

4A and 4B are arch direction joints of a unit panel of an arch roof according to the present invention, wherein FIG. 4A is a side view, FIG. 4B is a bottom view, and FIG.
Is an end view.

FIG. 5 is a plan view showing a joint plate portion of a unit panel of an arch roof according to the present invention.

FIGS. 6A and 6B are views showing a joint portion of a unit panel of an arch roof according to the present invention in a ridge center direction, wherein FIG. 6A is a bottom view, and FIGS. 6B and 6C are end views.

FIG. 7 is a side view showing the construction of the arched structure of the present invention in the order of steps.

[Explanation of symbols]

P ... Unit panel A ... Arch direction B ... Construction direction 1 ... Arch roof 2 ... Wife wall 3 ... Concrete 4 ... Sediment 5 ... Foundation 11 ... Steel plate 12 ... Steel frame material 12 ₁ ... Top flange 12 ₂ ... Bottom flange 12 ₃ ... Web 13 ... Fillet welding 21 ... Steel plate 22 ... Steel frame material (vertical bone) 30 ... Splice plate 31 ... Bolt 32 ... Splice plate 33 ... Bolt 34 ... Seal welding 35 ... Joint plate 36 ... Fillet welding 37 ... Splice plate 38 ... bolts 40 ... seal welding 41 ... fillet welding 42 ... fillet welding

Continuation of front page (58) Fields investigated (Int. Cl. ⁷ , DB name) E04H 1/00-9/00 E02D 29/00 E01F 7/00 E21D 11/00 E06B 5/00

Claims (1)

(57) [Claims] 1. An arch roof comprising a steel plate located on the roof inner side and a steel frame material located on the roof outer side and along the arch direction,
In an arch-shaped structure configured by combining a plurality of unit panels, in the arch direction joining of the unit panels, in the steel frame portion, the flanges of the steel frame and the webs are bolted together via a splice plate, In the steel plate part, the ends of the steel plate are joined by welding, and the joint plates erected outside the roof of the steel plate are bolted together via a splice plate. Of steel panels, which are joined by welding with steel members interposed therebetween.