JPH04143368A - Slab reinforcing method and structure thereof - Google Patents

Abstract

PURPOSE:To facilitate the execution of reinforcement work for slab concrete as well a to secure a firm reinforced structure by clamping a position, locking a reinforced steel plate, with a clamper such as an anchor bolt or nut, etc., via both first and second bonded steel plates. CONSTITUTION:A reinforced member is mad up of both first and second bonded steel plates 1, 3 and a reinforced steel plate 11. These two steel plates 1, 3 are formed into the same form, and two anchor bolt holes 7, 9 larger as far as about 0.5mm or so than the diameter of an anchor bolt 5 are installed there. Also in this reinforced steel plate 11, there is provided an anchor hole 13 piercing through this plate. In addition, a bonded part of slab concrete 15 is cut as far as the specified thickness and, after the reinforced steel plate 11 is bonded to this bonded part via the first bonded steel plate 1, the second bonded steel plate 3 is stuck on it, then it is clamped by the anchor bolt 5. With this constitution, the execution of slab reinforcement work can easily be done.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a slab reinforcement method for providing a reinforcement structure to slab concrete and a slab reinforcement structure.

(Prior Art) As a reinforcement structure for reinforcing slab concrete, there is a structure in which a steel plate is bonded and fixed to the surface of slab concrete. This will be explained with reference to FIG.

First, after constructing the concrete slab 101, its surface is cut by about 1 m. This cut is made on the entire surface of the concrete slab 101.

Next, anchor poles 103 are attached to multiple locations.

On the other hand, a rope plate 105 is prepared separately, and through holes 107 are bored in the rope plate 105 in accordance with the positions of the plurality of anchor bolts 103. In this work, the mutual dimensions of a plurality of anchor bolts 103 attached to the concrete slab 101 are measured, and the steel plate 10 is
Mark 5 and do it.

Next, the steel plate 105 is attached to the surface of the concrete slab 1010, and the nut 108 is attached to the anchor bolt 105.
It is fixed by screwing it into place.

Then, the injection port 10 is installed in advance on the steel plate 105.
Epoxy resin 111 as an adhesive is injected between the steel plate 105 and the concrete slab 103 via 9 .

After that, a desired reinforcing structure is completed by allowing a predetermined curing period (for example, 24 hours).

In addition, in such a reinforced structure, the rope plate 105 is fixed to the slab concrete 101 using anchor poles.
The fastening force due to 103 is 1/3, and the adhesive force due to epoxy resin 111 is 273.

(Problem to be solved by the invention) The conventional configuration described above has the following problems.

First, there was the problem that the work was difficult.

This is because in order to bond the steel plate 105 to the entire surface of the concrete slab 101, it is necessary to cut the entire surface of the concrete slab 101, and
Driving the anchor bolt 103, drilling the steel plate 105, etc. were also difficult.

Furthermore, during each of the above operations, a large amount of dust is generated, and it is necessary to install partitions to prevent this large amount of dust from flowing outside.

Since the steel plate 105 is bonded to the entire surface of the concrete slab 101, there is a risk that the copper plate 105 may peel off or fall from the concrete slab 101 due to cracks, water leakage, partial vibrations, etc. of the concrete slab 101.

Furthermore, since the steel plate 105 is bonded to the entire surface of the concrete slab 101, there is also the problem that it is not possible to inspect the concrete slab 101 for deterioration after construction.

The present invention was developed based on the above points, and its purpose is to facilitate construction, eliminate the generation of large amounts of dust, and enable inspection of deterioration of slab concrete after construction. The object of the present invention is to provide a slab reinforcement method and a slab reinforcement structure.

(Means for Solving the Problems) In order to achieve the above object, the slab reinforcement method according to the present invention includes a reinforcing steel plate, a first adhesive steel plate for bonding the reinforcing steel plate to the slab concrete, and a first bonding steel plate for bonding the reinforcing steel plate to the slab concrete side. A process of pre-drilling holes for anchor bolts of a predetermined diameter in the second bonded steel plate, and at the same time or before or after this, cutting the adhesive parts scattered at predetermined positions on the reinforced side end face of the concrete slab to a predetermined thickness. applying an adhesive to the first adhesive steel plate and the second adhesive steel plate; passing the first adhesive steel plate, the reinforcing steel plate, and the second adhesive steel plate through the anchor bolts and adhering them to the slab concrete, and attaching the nuts to the anchor The present invention is characterized by comprising a step of screwing onto a bolt to fasten and fix it.

Further, the slab reinforcement structure according to the present invention includes a first bonded steel plate bonded to adhesive portions scattered at predetermined positions on the reinforced side end face of the slab concrete, and a reinforcement bonded to the first bonded steel plate from the side opposite to the slab concrete. a steel plate, and a second adhesive rope plate that is bonded to the reinforcing steel plate from the anti-slab concrete side;
The present invention is characterized by comprising an anchor bolt/nut fastener for fastening and fixing the first bonding rope plate, the reinforcing steel plate, and the second bonding copper plate to the slab concrete.

(Function) In the method for reinforcing a slab according to the present invention, first, holes for anchor bolts of a predetermined diameter are made in the reinforcing steel plate, the first adhesive steel plate, and the second adhesive cable. This work can be done on-site or in a factory.

At the same time as or before or after the above-mentioned drilling work, cuts are made in the concrete slab at the site. The part to make this cut is
Instead of covering the entire surface as in the past, there are a plurality of bonded parts scattered at predetermined positions on the reinforced side end face of the concrete slab.

Next, an adhesive is applied to the first adhesive steel plate and the second adhesive steel plate. Then, the first bonded steel plate, the reinforcing steel plate, and the second bonded steel plate,
Pass it through the anchor bolt and adhere it to the slab concrete, and tighten it by screwing the nut onto the anchor bolt.
Fix it.

In addition, in the slab reinforcement structure according to the present invention, adhesive portions dotted at predetermined positions on the reinforced side end face of the slab concrete,
A reinforcing steel plate is bonded via the first bonded steel plate, and then a second bonded steel plate is bonded.
It is made by gluing together adhesive rope plates. Moreover, it is fastened and fixed using anchor bolt and nut fasteners.

(Embodiment) An embodiment of the present invention will be described below with reference to FIGS. 1 to 3. Fig. 1 is a plan view showing a slab reinforcement structure reinforced by the slab reinforcing method according to the present embodiment, Fig. 2 is a sectional view taken along the line ■-■ in Fig. 1, and Fig. 3 is a view taken along the -■ arrow in Fig. 2. It is a diagram.

First, an arbitrary number of first bonded steel plates 1 (for example, disc-shaped plates) 1 and the same number of second bonded steel plates 3 having the same shape are prepared. These first adhesive steel plate 1 and second adhesive steel plate 3,
Anchor bolt hole 7.9 through which the anchor bolt 5 passes
Open. At that time, the outer diameter of the anchor bolt 5 is 12.
If there are 5 cabinets, the holes should be about the size of (12,5+0.5) cabinets.

Further, a reinforcing steel plate 11 is prepared, and an anchor bolt hole 13 through which the anchor bolt 5 passes is bored at a predetermined position in the reinforcing steel plate 110. The diameter of this anchor bolt hole 13 is 25 to 25 m, assuming that the outer diameter of the anchor bolt 5 is 12.5 m.
The power should be approximately 35Wm. In other words, the hole has a margin with respect to the outer diameter of the anchor bolt 5.

All of the above work will be performed at the factory, and after processing at the factory, the product will be delivered to the site. Of course, it may be processed on site.

On the other hand, at the site, adhesive portions scattered at predetermined positions on the reinforced side end face of the concrete slab 15 are canted to a thickness of about 1 mm. The above-mentioned adhesive part refers to the first contact a mentioned above.
This is the part to which the m-board 1 is bonded.

Next, the anchor bolt 5 is attached to a predetermined position in the part where the force is applied. The anchor bolt 5 is fixed by applying epoxy resin and press-fitting it.

Next, an epoxy resin 17 as an adhesive is applied to the first bonded steel plate 1 and the second bonded steel plate 3 that have been transported from the factory to the site. At that time, since both surfaces of the first adhesive steel plate 1 serve as adhesive surfaces, epoxy resin 17 is applied to both surfaces, and the second
Regarding adhesive steel plate 3, only one side is the adhesive surface, so
Apply epoxy resin 17 only to one side.

Next, the first bonded steel plate 1, the second bonded steel plate 3, and the reinforcing steel plate 11 are pasted through the anchor bolts 5 and bonded together.

At that time, since the epoxy resin 17 is not in a completely hardened state, the reinforcing steel plate 11 can be moved freely within the margin of the anchor bolt hole 13. Therefore, the reinforcing steel plate 11 can be moved as appropriate. Adjust the position.

After completing the position adjustment, attach nut 19 to anchor bolt 5.
By screwing and fastening the first adhesive steel plate 1, the second adhesive steel plate 3, and the reinforcing steel plate 11 to the concrete slab 15,
Fixed to. And Camp 21 in Natsuto 19's part
complete the work.

Moreover, the slab concrete 15 and reinforcing steel plate 11 of this example
An inspection opening 23 is formed therein. Via this inspection opening 23, the concrete slab 15 is inspected for deterioration, etc.

According to this embodiment, the following effects can be achieved.

First, slab reinforcement work has become much easier.

This is not a conventional structure in which the reinforcing steel plate 11 is bonded to the entire surface of the slab concrete 15, but is partially bonded via the first bonding steel plate 1 and the second bonding steel plate 3. This is because the diameter of the anchor bolt hole 13 of the steel plate 11 is made large enough to have a margin with respect to the outer diameter of the anchor bolt 5.

In other words, with such a configuration, the area to be cut into the concrete slab 15 is significantly reduced. In addition, holes 7.9 are formed in the first adhesive steel plate 1 and the second adhesive steel plate 3.
This is because the work of drilling the holes 13 in the reinforcing steel plate 11 can all be done at the factory.

Even with such a configuration, the reinforcing effect as a reinforcing structure is 30% or more in terms of vibration frequency.

In addition, the amount of dust generated at the site has been significantly reduced as the area where the concrete slab 15 is cut has been significantly reduced, and in particular, partitions have been installed to prevent it from flowing outside. No longer needed.

When drilling holes for the anchor bolts 5, the drill is equipped with a dust suction device, so that dust will not be scattered.

Even if distortion occurs in the concrete slab 15, since it is not fully bonded, the distortion will not affect the entire surface, effectively preventing the first bonded steel plate 1 from peeling and falling, and by extension the reinforcing steel plate from peeling and falling. can do.

In other words, in the conventional case, epoxy resin is injected over the entire surface between the concrete slab and the reinforcing steel plate, and the bonding surface is an integral structure, so the distortion of the concrete slab 15 causes cracks in the bonded part. When it occurs,
This would affect the entire adhesive part, whereas in this example, the adhesive parts are scattered and cut at the edges.
Even if cracks occur in any bonded portion due to distortion of the concrete slab 15, this does not affect other bonded portions.

Furthermore, in the case of this embodiment, since the inspection opening 23 is provided, it is possible to inspect the deterioration of the concrete slab 15 after construction.

In addition, the structure has a gap formed between the slab concrete 15 and the reinforcing steel plate 11 in places other than the bonded part, but by injecting filler into the gap as appropriate, the rigidity after construction can be improved. You can try to recover.

(Effects of the Invention) As detailed above, according to the slab reinforcing method and slab reinforcing structure according to the present invention, the method of dotted bonding is used instead of the entire surface bonding method, so that slab reinforcing work can be facilitated, and The reinforced structure can be stably maintained over a long period of time.

[Brief explanation of the drawing]

1 to 3 are diagrams showing one embodiment of the present invention, in which FIG. 1 is a plan view of a slab reinforcement structure, and FIG. 2 is a
(2) Cross-sectional view, and FIG. 3 is a view taken along arrows m to (2) in FIG. 1... First bonded steel plate, 3... Second bonded steel plate, 5...
・Anchor bolt, 7,9.13... Anchor bolt completion 11... Reinforced steel plate, 15... Slab concrete, 17... Epoxy resin (adhesive), 19...
nut.

Claims (2)

[Claims] (1) A reinforcing steel plate, a first bonding plate to which this reinforcing steel plate is bonded to adhesive parts scattered at predetermined positions on the reinforced side end face of the slab concrete.
A process of pre-drilling holes for anchor bolts of a predetermined diameter in the second adhesive steel plate to be adhered to the anti-slab concrete side of the adhesive steel plate and reinforcing steel plate, and at the same time or before or after this process, the adhesive part of the slab concrete is made to a predetermined thickness. a step of applying adhesive to the first adhesive steel plate and a second adhesive steel plate, and a process of passing the first adhesive steel plate, reinforcing steel plate, and second adhesive steel plate through anchor bolts and adhering them to the slab concrete, and tightening the nuts. A method for reinforcing slabs comprising the steps of screwing onto anchor bolts to fasten and fix them. (2) A first bonded steel plate that is bonded to the adhesive portions scattered at predetermined positions on the reinforced side end face of the slab concrete, a reinforcing steel plate that is bonded to the first bonded steel plate from the side opposite to the slab concrete, and a second bonded steel plate bonded from the anti-slab concrete side, the first bonded steel plate, a reinforcing steel plate,
A slab reinforcement structure characterized by comprising an anchor bolt/nut fastener for fastening and fixing a second bonded steel plate to slab concrete.