JP2020041350A - Structure for pre-stressed concrete - Google Patents

Abstract

To provide a structure for a pre-stressed concrete integrated with a spacer capable of preventing deformation and damage of a steel permanent formwork.SOLUTION: A structure for a pre-stressed concrete comprises: a steel plate 4b; a rod-like steel material 10 used as a spacer for a pre-stressed concrete whose first end 10a is enlarged and to whose second end at an opposite side a temporary formwork is connected; and a cylinder-shaped member 11 which is fixed to the steel plate 4b, and has an inner diameter larger than the first end 10. The cylinder-shaped member 11 includes an end face with a hole 11a having a smaller diameter than the first end 10a and allowing the rod-like steel material 10 to be inserted therethrough. The cylinder-shaped member is also provided with the first end 10a therein. The structure for a pre-stressed concrete further comprise a buffer material 8b covering a part facing the pre-stressed concrete of the cylinder-shaped member 11 and the steel plate 4b.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a prestressed concrete structure for a prestressed concrete wall.

FIG. 5 shows a conventional example of a formwork and a spacer used for constructing a concrete wall. The conventional spacer for a formwork as shown in FIG. 5 is used for the purpose of keeping the space between the formworks facing each other and preventing the formwork space from widening at the time of placing concrete. There is prior art.

In the invention of the "mounting / removing device for concrete casting formwork" in Patent Document 1, a mounting hole is provided in the formwork in the thickness direction, and a bolt-like member is slidably and rotatably inserted into this mounting hole. There is disclosed an apparatus for attaching and detaching a concrete casting mold in which a nut-like member is screwed to one end of a bolt-like member protruding to the outer surface side of the mold.

Patent Document 2 discloses an invention of a “container for holding a concrete formwork”. In the invention, a stopper is provided at an intermediate portion of a fastening rod, and a slide stopped by a stopper is provided at an intermediate fastening portion between the stopper and the head. Assembling and holding the concrete formwork that fits the ring and fixes the tip of the adjustment band protruding from the sliding ring to the connecting female screw body to maintain the shortest effective depth when adjusting the screwing degree of the tightening rod. A material is disclosed.

Patent Literature 3 discloses an invention of “separator for formwork assembly”. The present invention includes a combination of two rods and a joint directly or indirectly coupled to a form plate fastening fitting at one end thereof, and the joint is formed with the other end provided with the protrusion of one rod. Disclosed is a mold assembly separator that fits relatively longitudinally and relatively rotatably about the axis of the rod.

Patent Literature 4 discloses an invention of a “form separator”. According to the present invention, the inner ends of a pair of separator construction rods arranged in series are slidably connected in the longitudinal direction of the rods via sliding connection fittings attached to the pair, and In each sliding connection fitting, a mold separator in which a locking member insertion through-hole is provided at a position where the separator coincides when the separator is extended to a predetermined length is disclosed.

Patent Document 5 discloses a "mold tie" which includes a pipe body fixedly penetrated to a veneer board and a cone integrally attached to a protruding portion of the veneer board on a concrete casting surface side in a penetrating state. In a state in which the shaft cannot be pulled out and is rotatably and slidably inserted for a fixed length, a screw hole for screwing a screw end of a separator to be inserted into the tube from the cone side is formed at the shaft end, and the other end of the shaft is There is disclosed a form binding device in which a rotating operation portion is protruded from an end of a tubular body, and a slide stopper is protruded here.

JP-A-62-268467 Japanese Utility Model Publication No. 51-11239 Japanese Utility Model Publication No. 54-15946 Japanese Utility Model Publication No. 51-045234 Japanese Utility Model Publication No. 64-43143

Generally, in casting concrete, a large number of separators are used in order to connect opposing molds with each other and maintain a constant interval between the opposing molds. Further, in the construction of the cylindrical prestressed concrete wall PC for prestressing the concrete C by tensioning the circumferential tendon, the diameter of the cylindrical prestressed concrete wall shrinks due to the prestress application. Therefore, when the prestress is applied, pressure toward the center of the cylinder acts on the inner peripheral form.
Therefore, when the inner peripheral side formwork of the opposite steel formwork used for the construction of the cylindrical prestressed concrete wall is a permanent formwork that is left as a part of the structure to be constructed, the steel permanent formwork is used. However, there was a risk of peeling or deformation from the prestressed concrete wall.
Further, in consideration of the pressure acting on the steel permanent form on the inner peripheral side due to the tension of the prestressed concrete wall, a measure to increase the plate thickness of the steel permanent form and increase the pressure resistance is also conceivable. In such a case, there is a problem that the cost of the material to be used is greatly increased.

Therefore, as a method of relieving the pressure acting on the steel permanent form on the inner peripheral side, a buffer material is attached in advance to the surface of the steel permanent form on the concrete casting side, so that the steel preform is applied when the prestress is applied. The present applicant has filed a technique for relieving the pressure acting on the steel permanent form with the cushioning material to prevent deformation and the like of the steel permanent form.
However, for the facing formwork used for concrete placement, the separators connecting the facing formwork were used to maintain the formwork spacing during concrete placement, so they were fixed to the casting concrete. There is no cushioning material in the steel permanent form of the separator mounting portion, and there is a problem that the pressure acting on the steel permanent form due to the application of prestress cannot be reduced.

  The prior arts described in Patent Literatures 1 to 5 absorb a displacement in the center direction of a cylinder due to the application of a prestress acting on a separator mounting portion of a steel permanent form, thereby deforming the steel permanent form. It does not relate to a structure for prestressed concrete intended to prevent damage or damage.

  The present invention has been made in view of the above-mentioned problems of the prior art, and has as its object the purpose of placing concrete between formwork and applying a prestressing force to construct a prestressed concrete wall. In doing so, the structure for prestressed concrete is integrated with a spacer capable of preventing deformation and damage of the permanent steel formwork while maintaining the predetermined space between the formwork against the concrete placing pressure. Is to provide the body.

The structure for prestressed concrete according to the invention of claim 1 is
A steel plate, a bar-shaped steel material having a first end expanded and serving as a spacer for prestressed concrete to which a temporary form is connected to a second end on the opposite side, and a bar larger than the first end fixed to the steel plate. A cylindrical member having an inner diameter, the cylindrical member having an end surface having a hole smaller in diameter than the first end but allowing the rod-shaped steel material to pass therethrough, wherein the first end is inside; A cushioning material is provided for covering a portion of the columnar member and the steel plate facing the prestressed concrete.

The structure for prestressed concrete according to the invention of claim 2 is:
The columnar member is fixed to the steel plate by welding.

The structure for prestressed concrete according to the invention of claim 3 is
A screw is cut inside the columnar member, and the stud fixed to the steel plate is engaged with the screw.

The structure for prestressed concrete according to the invention of claim 4 is:
A cushioning material is provided inside the columnar member at a position in contact with the first end of the bar-shaped steel material.

The structure for prestressed concrete of the present invention acts on the steel permanent form side when a prestressed concrete wall is constructed by applying a prestress force to concrete cast between the steel permanent form and the temporary form. It is possible to prevent the deformation and damage of the steel permanent form by absorbing the displacement toward the center of the cylinder.

It is sectional drawing during construction (right side) and after construction (left side) of the case of the newly installed ground type cylindrical tank 1 having the structure 9 for prestressed concrete according to the present invention. FIG. 2 is an enlarged view of a portion A in FIG. 1, and is a cross-sectional view illustrating an example of a detailed structure of a prestressed concrete structure 9. It is an exploded sectional view which shows the example of the detailed structure of the structure 9 for prestressed concrete of FIG.2 (b). It is sectional drawing which shows the example of the state at the time of (a) concrete casting and (b) concrete tension of the prestressed concrete structure 9 attached between the steel permanent form 4b and the temporary form 12. It is sectional drawing which shows the example of the detailed structure of the structure 9 for the conventional prestressed concrete.

  An embodiment of the prestressed concrete structure 9 according to the present invention will be described with reference to FIGS. Note that the present invention is not limited only to the following embodiments. It goes without saying that the following components may be omitted or added, and the shape of the components may be changed in the embodiment without departing from the gist of the present invention. In addition, the drawings show the outline, and only a part is drawn and the detailed structure is omitted.

FIG. 1 is an overall side view of an example of a newly-installed ground-type cylindrical tank 1 having a prestressed concrete structure 9 according to the present invention. Reference numeral 2 denotes a ground, 3 denotes an outer tank, and 4 denotes an inner tank.
The cylindrical tank 1 having a double shell structure has a metal inner tank 4 and a concrete outer tank 3 disposed so as to surround the inner tank 4. The left side of FIG. 1 is a cross-sectional view after the construction of the tank 1, and the right side is a cross-sectional view of the prestressed concrete side wall 3b of the tank 1 during the construction.
The outer tub 3 has a structure composed of the concrete bottom plate 3a and a prestressed concrete side wall 3b surrounding the side plate 4b of the inner tub 4.

An example of the order of constructing the prestressed concrete side wall 3b of the newly installed fixed roof type cylindrical tank 1 will be described.
Prior to the construction of the side wall 3b of the outer tub 3, the bottom plate 4a and the side plate 4b of the inner tub 4 are constructed, and the inner tub side plate 4b is used as a steel permanent form 4b for casting prestressed concrete.
Subsequently, a columnar member 11 for mounting the bar-shaped steel material 10 serving as a separator is installed on the outer peripheral surface of the inner tank side plate 4b. Here, the inner tank side plate 4b is the steel permanent form 4b.
Subsequently, the temporary formwork 12 is temporarily installed at a distance from the inner tank side plate 4b at a distance of the concrete casting width W.
Then, the temporary steel frame 12 and the inner tank side plate 4b of the permanent steel steel frame are connected with the rod-shaped steel material 10, and concrete C is cast between the two steel frames.
Subsequently, the prestressing force Ps is applied by tensioning the circumferential tension member 19 of the concrete C, and the side wall 3b made of prestressed concrete is constructed. Thereby, the outer tank side wall 3b is deformed in a direction to compress the inner tank side plate 4b.

FIG. 2 is an enlarged view of a portion A in FIG. 1 and is a cross-sectional view showing an example of a detailed structure of the prestressed concrete structure 9.
The prestressed concrete structure 9 is a spacer for prestressed concrete construction in which the steel permanent form 4b and the first end 10a are expanded and the temporary form 12 is connected to the second end 10c on the opposite side. It comprises a rod-shaped steel material 10 and a columnar member 11 fixed to the steel permanent form 4b and having an inner diameter larger than the first end 10a.
Each component of the prestressed concrete structure 9 will be described in detail.
The bar-shaped steel material 10 has a structure expanded by providing a flange portion 10b at the first end 10a.
The columnar member 11 has an end surface having a smaller diameter than the first end 10a but having an insertion hole 11a through which the bar-shaped steel material 10 can be horizontally moved in the axial direction, and the first end 10a of the bar-shaped steel material 10 is formed. Is located on the inside.
The columnar member 11 has a stopper portion 11b on the end face that abuts against the flange portion 10b and locks the flange portion 10b of the rod-shaped steel material 10 in a retaining state.
The columnar member 11 is directly or indirectly attached to a plurality of locations on the outer peripheral surface of the steel permanent form 4b.
(A) is an example in which the columnar member 11 is directly fixed to the outer peripheral surface of the steel permanent form 4b by welding S or the like. (B) is an example in which the cylindrical member 11 has a screw hole 11d on the inside, and the stud 25 fixed to the steel permanent form 4b by welding is engaged with the screw hole 11d of the cylindrical member 11. .
The flange 10b of the first end 10a of the rod-shaped steel member 10 is fitted into the fitting hole 11c of the columnar member 11 such that the flange 10b of the first end 10a of the rod-shaped steel member 10 contacts the stopper 11b of the columnar member 11. The bar-shaped steel material 10 is fitted so as to be slidable in the axial direction.
The columnar member 11 and the steel permanent form 4b include a cushioning material 8b that covers a portion facing the prestressed concrete PC.
Inside the cylindrical member 11, a stud 25 provided on the end surface of the flange 10b of the first end 10a of the rod-shaped steel material 10 and the inner surface of the steel permanent form 4b or the inner surface of the steel permanent form 4b. The gap 20 with the end portion 25b in the direction of the inside of the mold has a length L of several millimeters to several tens of millimeters. The length L of the gap 20 is set to a distance capable of absorbing the displacement in the center direction of the cylinder due to the application of the prestressing force Ps.
Further, a cushioning material 8c is provided in the gap 20.

FIG. 3 is an exploded sectional view showing an example of a detailed structure of the prestressed concrete structure 9 of FIG. 2B.
D ₁ is the outer diameter of the bar-shaped steel material 10.
D ₂ is the inner diameter of the insertion hole 11a for inserting the rod-like steel material 10 of the cylindrical member 11.
D ₃ is the outer diameter of the flange portion 10b which extends the first end 10a of the rod-shaped steel 10.
D ₄ is the inner diameter of the fitting hole 11c for fitting the flange portion 10b of the rod-shaped steel 10 of the cylindrical member 11.
Next, the relationship between the dimensions will be described.
Outer diameter _{D 1} of the rod-like steel material 10 smaller than the internal diameter D ₄ of the inner diameter _{D 2} and the fitting hole 11c of the insertion hole 11a of the cylindrical member 11, a rod-shaped steel 10 into the insertion hole 11a of the cylindrical member 11 The flange 10b is inserted into the columnar member 11 so as to be inside.
Outer diameter _{D 3} of the flange portion 10b of the rod-like steel material 10 larger than the inner diameter _{D 2} of the stopper portion 11b of the insertion hole 11a, when the flange portion 10b is in contact with the stopper portion 11b, the rod-shaped steel 10 yen Do not fall out of the columnar member 11.
The inner diameter _{D 4} of the fitting hole 11c of the cylindrical member 11, a value larger than the outer diameter _{D 3} of the flange portion 10b of the rod-shaped steel 10, the collar portion 10b of the fitting hole 11c of the cylindrical member 11 To allow the bar-shaped steel material 10 to move horizontally in the axial direction.

By using the prestressed concrete structure 9 of the present invention, the following effects can be obtained.
The prestressed concrete structure 9 can be easily processed, can be easily attached to a formwork, and can reduce construction costs and material costs.
It is possible to reliably prevent the space between the steel permanent form 4b and the temporary form 12 from being widened by the concrete pressure against the concrete pressure cast between the steel permanent form 4b and the temporary form 12. It is possible.
When the prestressed concrete wall PC is constructed by applying the prestressing force Ps to the concrete poured between the two formwork, the first end 10a of the bar-shaped steel material 10 moves horizontally inside the cylindrical member 11 so that the steel It is possible to absorb the displacement toward the center of the cylinder due to the prestressing force Ps acting on the permanent mold 4b side, thereby preventing deformation and damage of the steel permanent mold 4b.
When the steel inner tank side plate 4b of the double shell tank is used as the steel permanent formwork 4b at the time of concrete construction of the outer tank side wall 3b, the inner tank side plate 4b in which the cushioning material 8a cannot be installed is used. At the mounting portion of the bar-shaped steel material 10 on the outer peripheral surface, the displacement caused by the application of the concrete placing pressure Pc and the prestressing force Ps acting in the center direction of the cylinder is absorbed to prevent the inner tank side plate 4b from being deformed or damaged. Is possible.

Further, inside the columnar member 11, the form of the stud 25 provided on the end face of the flange portion 10b of the rod-shaped steel material 10 and the inner surface of the steel permanent form 4b or the inner surface of the steel permanent form 4b. By setting the gap 20 between the inner end 25b and the inner end 25b to have a length L of several millimeters to several tens of millimeters, the displacement in the center direction of the cylinder caused by the application of the prestressing force Ps causes the rod-shaped steel material 10 to move horizontally within the gap 20. It is absorbed by moving, and it is possible to prevent deformation and damage of the steel permanent form 4b.

Further, by providing the cushioning material 8c in the gap 20, the rod-shaped steel material 10 does not rattle in the columnar member 11 when the steel permanent form 4b and the temporary form 12 are connected and when the concrete is cast. It is possible to stably maintain the distance between the frames.
The buffer material 8c can be installed in the gap 20 and has a thickness capable of absorbing a displacement in the direction of the center of the cylinder acting on the steel permanent form 4b side by applying a prestress force Ps. And

  Furthermore, by forming a structure in which the portion of the cylindrical member 11 and the steel permanent form 4b facing the prestressed concrete wall PC is covered with the cushioning material 8b, the prestressing force Ps is exerted by the cushioning material 8b during concrete tension. The application can absorb the displacement in the direction of the center of the cylinder acting on the steel permanent form 4b side, thereby preventing the steel permanent form 4b from being deformed or damaged.

FIG. 4 is a cross-sectional view showing an example of the situation of (a) concrete placement and (b) concrete tension of the prestressed concrete structure 9 attached between the steel permanent form 4b and the temporary form 12. .
In the concrete casting of (a), the casting pressure Pc of the concrete poured between the steel permanent form 4b and the temporary form 12 acts in the direction of pushing and widening the distance W between the two forms. When the flange 10b of the first end 10a of the steel material 10 comes into contact with the stopper 11b of the columnar member 11, the predetermined space W between the two forms is maintained so as not to widen, and the concrete having the designed width W is removed. Casting becomes possible.
When the concrete circumferential direction tension member 19 between the steel permanent form 4b and the temporary form 12 is tensioned at the time of the concrete tension of (b), a pressure acts toward the center of the cylinder due to the application of the prestress force Ps, and the rod-shaped steel material The flange 10b of the first end 10a of 10 moves horizontally in a direction away from the stopper 11b of the columnar member 11, and is provided on the inner surface side of the steel permanent form 4b or the steel permanent form 4b. The cushioning material 8c provided in the gap 20 between the end portion 25b of the stud 25 and the inward direction of the mold absorbs displacement by being compressed, and the cushioning material 8a cannot be installed on the inner surface side of the steel permanent mold 4b. It is possible to prevent the mounting portion of the steel material 10 from being deformed or damaged by the pressure toward the center of the cylinder due to the application of the prestressing force Ps.

By using the prestressed concrete structure 9 of the present invention, the following effects can be obtained in (a) concrete placing and (b) concrete tension.
In the mounting portion of the steel permanent mold 4b where the cushioning material 8b of the steel permanent mold 4b cannot be provided, the flange portion 10b of the first end 10a of the steel bar 10 horizontally moves in the fitting hole 11c of the columnar member 11. The displacement caused by the prestressing force Ps is absorbed by an amount corresponding to the movement, and the pressure acting on the steel permanent form 4b side toward the center of the cylinder is reduced by applying the prestressing force Ps. Deformation and damage can be prevented.
By covering the portion of the cylindrical member 11 facing the prestressed concrete wall PC with the cushioning material 8b, the displacement due to the pressure toward the cylinder center due to the application of the prestressing force Ps acting on the cylindrical member 11 and the stud 25 is absorbed, It is possible to prevent deformation and damage of the steel permanent form 4b.
By installing the cushioning material 8c inside the columnar member 11 and in contact with the flange 10b of the first end 10a of the rod-shaped steel material 10, the rod-shaped steel material 10 is It is possible to stably maintain the distance between the two forms without rattling.

The steel permanent form 4b is used not only as a form at the time of casting the concrete, but also as the inner tank side plate 4b of the above-ground cylindrical tank 1 without dismantling even after the concrete is placed. It is a permanent formwork. The temporary formwork 12 is a formwork that is dismantled and removed after placing concrete.
Note that both 4b and 12 may be permanent molds.

The cushioning materials 8a to 8c are excellent in shock absorbing performance, energy absorbing performance, pressure dispersing performance, etc., and absorb displacement to the steel permanent form side due to application of concrete placing pressure Pc and prestressing force Ps. Use low resilience urethane foam or the like formed of a low resilience material that can be used.
Further, when applied to a tank or the like for storing flammable dangerous substances such as heavy oil and crude oil, a flame-retardant urethane foam or the like having flame retardancy, in which a flame retardant or the like is added to the low-repulsion material, is used. .

The prestressed concrete structure 9 can be applied to a structure such as a storage other than a tank in which tsunami countermeasures are desired, and is effective for a structure in which a side wall made of prestressed concrete needs to be constructed.

1 (cylindrical) tank
2 Ground
3 (concrete) outer tank 3a bottom plate (basic plate, reinforced concrete)
3b side wall (prestressed concrete)
4 (Metal) inner tank 4a bottom plate 4b side plate (steel permanent form)
5 Storage liquid 6 Fixed roof 6a Roof bone structure 6b Roofing plate 7 Top angle 8 Buffer material 8a Buffer material 8b (of outer peripheral surface of side plate 4b) Buffer material 8c (covering cylindrical member 11) Buffer material (in cylindrical member 11) Material 9 Prestressed concrete structure 10 Bar-shaped steel material 10a First end 10b Flange 10c Second end 10d Screw 11 Columnar member 11a Insertion hole 11b Stopper 11c Fitting hole 11d Screw hole 12 Temporary formwork 12a Hole 13 Cone 13a Screw hole 13b Screw rod 14 Form tie 15 Thick material 15a Thick material 15b Thick material 16 Washer 17 Nut 18 Formwork tightening rod 18a Screw part 19 Circumferential tension member 20 Gap 21 Bar member 21a First end 21b Screw part 21c 2nd end 21d screw part 22 stud 22a screw part 23 cover part 24 nut member 24a screw hole 25 screw member 25a screw part 5b mold in direction end portion

Casting pressure (tensile stress) of concrete on Pc side wall 3b
External pressure (compressive stress) when applying prestress to Ps side wall 3b
S Stud weld W Spacing between steel permanent form 4b and temporary form 12 C Concrete PC Prestressed concrete L Gap in columnar member 11

Claims (4)

  A steel plate, a bar-shaped steel material having a first end expanded and serving as a spacer for prestressed concrete to which a temporary form is connected to a second end on the opposite side, and a bar larger than the first end fixed to the steel plate. A cylindrical member having an inner diameter, having an end surface having a hole smaller in diameter than the first end but allowing the rod-shaped steel material to pass therethrough, wherein the first end is inside the cylindrical member; A prestressed concrete structure comprising: the columnar member; and a cushioning material covering a portion of the steel plate facing the prestressed concrete.   The prestressed concrete structure according to claim 1, wherein the columnar member is fixed to the steel plate by welding.   The prestressed concrete structure according to claim 1, wherein a screw is cut inside the columnar member, and the stud fixed to the steel plate is engaged with the screw.   The prestressed concrete structure according to any one of claims 1 to 3, wherein a cushioning material is provided inside the cylindrical member and at a position in contact with the first end of the bar-shaped steel material.

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