KR20120117092A - Tension plate structure of end phase of the electric pole and method making the electric pole by it - Google Patents

Abstract

PURPOSE: A top-end tension plate structure with an integrated top-end plate and a method for manufacturing a concrete pole with the structure are provided to form the covering depth of a top-end side into designed thickness by inserting a shortage of concrete mortar of the top-end side. CONSTITUTION: A mortar insertion space(540) is formed inside a top-end tension plate(520). A length adjusting spiral unit(522) is longitudinally formed on an outer surface of the top-end tension plate. A top-end tension fixing nut(600) is inserted into the adjusting spiral unit. A tension device combining unit(530) is integrally formed on the top of the top-end tension plate at a right angle. A protrusion(532) and an insertion unit(534) are alternatively formed.

Description

Tension plate structure of end phase of the electric pole and method making the electric pole by it}

The present invention relates to a horseshoe tension plate structure integrally formed with a horseshoe plate and a method of manufacturing concrete pole using the same. The lack of concrete mortar on the horseshoe side caused by the compaction by centrifugal force is molded through a horseshoe tensioner plate body integrally formed with horseshoe plates. Not only is it easy to inject into it, but the fixation and support of the tensile muscles to which tension is applied is made easy by a support flange of a mold having a simple structure.

The production of electric pole is efficient and economical because there is no need for the subsequent process to reinforce the thickness of the finished concrete pole by inputting the lack of concrete mortar on the horse end to the design thickness.

As described above, the present invention is supported by a mold, which is a structure in which a shortage of concrete mortar can be added and a simple structure for fixing and supporting a tensile muscle given tensile force does not cause a lack of coating thickness of concrete poles. useful.

Jeonju is a concrete product with a tension bar inserted. Tensile force is applied to the tensile muscles.

Jeonju's shape is usually called the base buried in the basement and the opposite air side.

The inside of the pole is hollowed out. The diameter of the sphere is large, and the diameter of the sphere is small.

This is because the sphere is buried underground and is standing vertically, so the diameter of the sphere is large and the diameter of the sphere is small to be structurally stable.

Concrete pole is manufactured by centrifugal force.

The outline of concrete pole making is as follows.

In the Jeonju Mold, the tensile muscles are long and extended over the sphere and the horse sphere.

Tensile muscles are located between the sphere of the finished concrete pole and the concrete thickness of the sphere.

Since the diameter of the sphere is smaller than that of the sphere, it is more difficult for the reinforcement of the tensile muscle than the sphere.

The tensile force is applied to the tension muscles by the tension device, and concrete mortar is introduced into the mold in this state. At this time, the slump of concrete mortar is zero.

Centrifugal force is applied to the mold.

The concrete mortar adheres to the mold by centrifugal force, and a hollow part thereof is formed at the center thereof.

The concrete thickness of the sphere and the horse sphere in which the hollow part is formed is the same.

The central axis of centrifugal force is the central axis of the sphere and the horse sphere. The central axis of the centrifugal force is the central axis of the mold and its central axis is a horizontal line.

Since the central axis of the centrifugal force of the mold is a horizontal line, the bottom of the sphere is located below the bottom of the sphere. The concrete mortar of the mold is gravity-driven from the top side to the bottom side. This is because the pole is inclined downward from the end to the sphere.

The central axis of the centrifugal force is a horizontal line connecting the central axis of the sphere and the sphere, and since the concrete thickness of the sphere and the sphere is the same, the concrete mortar of the sphere side in the mold is directed to the sphere side by gravity due to the slope of the pole.

The slope of the pole is usually 1/75 with respect to the central axis.

It is for this reason that the slump of concrete mortar is set to 0 to minimize the amount of deflection. Even if the slump value = 0, the concrete mortar is not compacted.

As the concrete mortar is compacted by centrifugal force, the structure becomes dense. As compacted and dense, there is a shortage of concrete mortar.

Concrete mortar is gravity due to the sphere side, so the concrete mortar is gathered to the sphere side. As a result, the shortcomings appear on the side. There is a problem that the coating thickness is less than the end of the horseshoe side.

Concrete mortar is attached to the mold wall, but the concrete mortar is insufficient in the hollow part opposite the mold wall. This causes the coating thickness of the tensile muscles not to meet the specification, or even the tensile muscles are exposed.

Insufficient cover thickness should be followed by reinforcement with concrete mortar after completion of electric pole. In particular, where the tensile muscle is exposed, it is cumbersome to follow-up work to be completely covered.

In the concrete poles actually used, for example, the reduction in the thickness of the horseshoe is explained as follows.

Length of concrete pole (L) = 16m,

Diameter α of the sphere, 403 mm,

Word diameter β = 190 mm,

Concrete thickness of the sphere and sphere T = 55 mm,

Number of tensile muscles = 12-16,

Concrete mortar; Slump = 0, sand + aggregate (maximum size of coarse aggregate; 19 mm)

After fabricating the electric pole by applying centrifugal force under the above conditions, the concrete thickness T on the horseshoe side was reduced to 40 mm by 15 mm. The concrete thickness T = 55mm was taken into account at least the concrete coating thickness of the horse's tensile muscles, 40mm is not enough as the coating thickness of the tensile muscles.

Looking at the relationship between the lack of concrete mortar caused by the centrifugal force in relation to the prior art as follows.

First, the prior art-1 of FIGS. 1A and 1B relates to a manufacturing method of a pole and a manufacturing apparatus thereof of Patent No. 10-0376818.

A tension root 64 is disposed in the mold 20, and one end of the tension root 64 is provided by the tension nut 300 on the spherical tension root fixing plate 34 and the other end of the tension root fixing plate 44. It is fixed

In particular, the tension root 64 inserted into the horse plate 40 is inserted and fixed in the bolt hole 440 of the horse plate 40 as shown in FIG.

The tension of the tensile muscles 64 is a method of applying tension to the tension muscles 64 by moving the horseshoe plate 40 a certain distance while one end of the tension muscles 64 is fixed to the spherical tension muscle fixation plate 34. .

Means for moving the horse plate 40 is the connection ring 200 and the tension shaft 50 as shown in Figure 1b. The connection ring 200 is also connected to the horse plate 40 at the same time. That is, the connection ring 200 has a structure in which the tension root 64 penetrates the bolt hole 440 and is simultaneously connected with the horse plate 40 fixed by the tension nut 300. Although not shown, the tension axis 50 is an axis connected with the hydraulic pressure.

In other words, the connection ring 200 is positioned between the horse plate 40 and the tensile shaft 50 to transfer the tensile force of the tensile shaft 50 to the connection ring 200, and the tensile force transmitted again is the horse plate 40 By transferring to the horse plate 40 by moving a predetermined distance to give a tensile force to the tension root (64).

However, despite the lack of concrete mortar on the horseshoe by centrifugal force, there is no space to fill the lack of concrete mortars on the horseshoe.

This is because, as in FIG. 1B, the horse plate 40 is completely blocked except for the bolt hole 440.

As the structure of the prior art-1, the concrete mortar deficiency on the horseshoe side cannot be filled by centrifugal force.

Reference numerals related to the prior art-1 of FIGS. 1A and 1B, 14 denotes a horse, 20 denotes a mold, 23 denotes a sphere, 30 denotes a sphere plate, 32 denotes a sphere tension plate, 46 denotes a copper plate, 52 denotes a nut, and 220 denotes a hanger. The grooves 420 and 422 are hangers.

Next, the prior art-2 relates to a manufacturing apparatus and a manufacturing method of the pole of Patent No. 10-0766425. 2a and 2b.

The prior art-2 differs only from the improvement of the configuration of the horseshoe plate 40 to which the tension root 64 is fixed while using the prior art-1 as it is, as follows.

The horse plate 40 of the prior art-2 has a circular space 400 is formed in the center, the size of the circular space 400 is almost similar to the size of the inner space of the electric pole (100). Tensile muscle guide fixing hole 440 is formed on the outer wall of the circular space 400. The length of the guide fixing hole 440 is determined by the design position of the tensile muscle 64. Since the width of the guide fixing hole 440 should be such that the tension root 64 can be inserted freely, it is generally slightly larger than the diameter of the tension muscle 64.

The horseshoe plate 40 and the horseshoe plate 40 are fixed to the horseshoe plate 40 and the horseshoe plate 40 is fixed to the horseshoe plate 40 is fixed to the horseshoe plate upper cover 74 is installed. Fixing of the horseshoe fixing plate bottom cover 72 and the horseshoe fixing plate top cover 74 is fixed by the horseshoe fixing plate fixing cover fastening nut 350 by inserting the cover fixing rod 48.

However, even in the prior art-2, there is no space for filling the shortage of concrete mortar on the horseshoe side.

On the horse plate 40 in contact with the concrete and the horse plate 40 to which the tension roots 64 are fixed, respectively, a bottom cover 72 and a horse stop plate top cover 74 are installed, and a cover fixing rod 48 is provided. (See Fig. 2b.) There is no space at all in the bottom cover 72 and the top cover 74 of the horse holding plate and there is no structure to fill the shortage of concrete mortar. .

As the structure of the prior art-2, the concrete mortar deficiency on the horseshoe side cannot be filled by centrifugal force.

Reference numerals in FIGS. 2A and 2B are the same as in the prior art-1 and will be omitted. 2A is a support flange of the spherical mold, and B is a support flange of the spherical mold.

⒜ The present invention predicts the deficiency of the concrete mortar on the horseshoe side caused by the compaction by centrifugal force in the manufacturing process of concrete pole in advance, and first, by applying a preliminary centrifugal force to the molds to reach the horseshoeing state and then stopping the molds. The purpose is to fill a lack of concrete mortar on the horseshoe, and then apply regular centrifugal force to the mold so that the finished thickness of the horseshoe is the design thickness.

부족 The lack of concrete mortar on the horse's side puts the coating thickness on the horse's side into the design thickness, thus eliminating the need for subsequent steps to reinforce the coating thickness after the pole is completed, while making the pole's production more efficient and economical. Purpose,

목적 Another object is to make it easy to fix and support the tensioned muscles by allowing the fixing and supporting of tensioned tensioned muscles to be supported by the mold. have.

The basic concept of applying a tensile force to the tensile muscles using a sphere and a horse sphere, and manufacturing a concrete pole by centrifugal force is the same as the present invention or the prior art-1, -2.

However, the fixed sphere of the present invention changes the structure of the horse sphere on the tension side while using the prior art as it is.

More specifically, the horseshoe tension plate structure in which the horseshoe plate of the present invention is integrally formed is a structure that allows the shortage of concrete mortar to be injected into the horseshoe because the deficiency of concrete mortar occurs in the horseshoe. It is a support structure that makes it simple and easy to fix and support a tensioned muscle.

Thus, since the present invention improves only the structure of the horseshoe side (tension side), it is the same as the structure of the prior art-1, 2 except for the horseshoe side structure. Accordingly, the drawings and reference numerals of the mold, the spherical side, the tension root, etc. of the prior art-2 will be used as it is for convenience of description.

In the present invention, the tension root 64 is disposed in the mold 20 in which the spherical side support flange A and the spherical side support flange B are formed, and one end of the tension root 64 is formed by the spherical plate 30. It is fixed to the support side of the spherical side (A), and the other end of the tension root (64) is tensioned by the tension axis (50) in a state fixed to the horseshoe side, filled with a concrete mortar in the mold to add a centrifugal force to the concrete In the production apparatus for manufacturing poles

The horseshoe plate 510 forming the mortar inserting space portion 514 and the horseshoe plate 520 forming the mortar inserting space portion 540 are integrally formed, but the horseshoe plate 510 is the horseshoe plate 520. While having a tension bolt insertion groove 512 into which the tension bolt 700A is inserted at the lower end of the head), it is formed at right angles to the horse tension plate 520 toward the mortar insertion large space portion 540, and the horse tension plate 520. The mortar insertion large space portion 540 therein, and the length adjusting spiral portion 522 is formed long in the outside, the adjustment spiral portion 522 is a tool insertion groove 610 and the spiral portion 620 is The formed horse tension fixing nut 600 is inserted, and the tension device fastening portion 530 is integrally perpendicular to the horse tension plate 520 outside the mortar insertion large space portion 540 at the upper end of the horse tension plate 520. While forming the integral plate is characterized in that the projection 532 and the insertion portion 534 is formed alternately Malgu a tension plate structure.

Tensile plate 510 is formed by integrally forming the mortar inserting space portion 514 and the horseshoe plate 520 forming the mortar inserting space portion 540. Tensile force is applied to the muscle 64 and at the same time, the tension muscle 64 is elongated, and the elongated length is inserted into the adjusting spiral 522 of the horseshoe plate 520. Tensile force is introduced into the tension root 64 only when the stretched length is fixed as it is.

In order to keep the tension muscles 64 stretched as it is, the horseshoe tension fixing nut 600 and the horseshoe side support flange (B) inserted into the adjusting spiral 522. Since the horseshoe-side support flange B is fixed to the mold 20, it is the horseshoe plate 520 and the horseshoe fixing nut 600 which are moved.

In order to introduce a tensile force to the tension root 64, the distance to the horseshoe plate 520 has to be moved to a stationary state. When the horseshoe fixing nut 600 is rotated so as to be in contact with the horseshoe-side support flange B, the horseshoe-fixing nut 600 is fixed and supported by the horseshoe-side support flange B, and the horseshoe tension plate 520 is not moved. It is fixed to the position as it is.

In addition, the structure of the horse plate 510 and the horse tension plate 520 is integrated into the mortar insertion space portion 514 consisting of the horse plate 510 and the mortar insertion space portion 540 in the horse tension plate 520. Since the structures are in communication with each other, it is easy to input the mortar deficiency amount of the horseshoe into the mold.

As such, the structure in which the horse plate 510 and the horse tension plate 520 are integrally formed has a simple structure, and it is easy to apply a tensile force to the tensile muscle 64, and at the same time, it is easy to input a mortar deficiency amount on the horse side. Structure.

In addition, although the tension bolt 700A may be used, the inclination of the pole is usually 1/75, so it is advantageous to use the tension hinge bolt 700.

The tension bolt 700A may use what is described in Korean Patent No. 10-0970674. (See Fig. 6)

If the reference numeral of FIG. 6 is used as it is, the configuration of the tension bolt 700A is as follows.

The tensioning bolt 700A is composed of an insertion and fastening portion 740A having a head portion 720A, an insertion portion 730A, and a spiral portion 750A, and the spiral portion 920 of the tension root 900 is tensioned. It is a structure inserted into the spiral part 750A of the bolt 700A. The length S of the spiral portion 750A of the tension bolt 700A is equal to the length of the spiral portion 920 of the tensile muscle 900.

Tension hinge bolt 700 is shown in FIG.

The tension hinge bolt 700 is the same as the tension bolt 700A, except that the head portion 710 has a hinge portion 720 and the insertion portion 730 having an inclined surface is different. The spiral portion is formed inside the insertion portion 730. The spiral portion of the insertion portion 730 and the spiral portion 64a of the tensile muscle 64 are coupled to each other.

The hinge portion 720 of the tension hinge bolt 700 corresponds to the hinge groove 516 formed in the tension bolt insertion groove 512 of the horse plate 510. (See Fig. 3).

The hinge portion 720 of the tension hinge bolt 700 and the hinge groove 516 corresponding thereto will be described in detail as follows.

Since the pole and the horse are different in diameter, the inclination of the pole is inclined to 1/75 with respect to the axis of rotation. Tensile muscles (64) in the reinforcement is also inclined state in order to match the direction of the inclined tensile muscles (64) of the hinge portion 720 of the tension hinge bolt 700 and the corresponding plate 510 A hinge groove 516 is formed in the tension bolt insertion groove 512. When the direction of the tension bolt insertion groove 512 of the horse plate 510 coincides with the inclination direction of the tension muscle 64, there is no loss of tensile force added to the tension muscle 64.

In other words, when the direction of the tension hinge bolt 700 inserted into the tension bolt insertion groove 512 of the horse plate 510 coincides with the inclination direction of the tension muscle 64, the tensile force added to the tension muscle 64 is frictional force. The loss does not occur.

Therefore, it is preferable to form the tension bolt insertion groove 512 of the horseboard 510 to match the inclination of the tension root (64). It is structurally advantageous because the tensile force loss of the tensile muscle 64 due to the frictional force is minimized.

However, even if the tension bolt insertion groove 512 of the horse plate 510 matches the inclination of the tension root 64, there will always be an error.

Measures for overcoming this error are the hinge portion 720 and the hinge groove 516. By adjusting the hinge portion 720 and the hinge groove 516, the tension hinge bolt 700 is matched with the inclination of the tensile muscle 64. The diameter of the tension bolt insertion groove 512 of the horse plate 510 is 1 ~ 2mm larger than the diameter of the tension hinge bolt 700. Because of this margin, fine adjustment by the hinge portion 720 and the hinge groove 516 is accommodated.

On the other hand, the locking portion 820 having the exhaust hole 830 and the rubber cap 800 formed with the insertion portion 810 is inserted into the mortar insertion space portion 514 formed of the horseboard 510.

The mortar inserting space portion 514 is a space for injecting the mortar shortage on the horseshoe side.

When the mold is rotated by the centrifugal force, by blocking the mortar insertion space portion 514 with a rubber cap 800 to prevent the concrete mortar from jumping out of the mold.

The exhaust hole 830 of the rubber cap 800 is for discharging gas such as water vapor generated by heat of hydration in the mold out of the mold.

At the time of curing the pole, the rubber cap 800 inserted in the mortar insertion space portion 514 is removed.

The mortar insertion space portion 514 of the horseshoe is an inflow path into which the steam enters the inside of the hollow during steam curing, so that the steam contact is even, so that the curing quality of the concrete pole is excellent and the curing time is shortened.

When the circular hole is formed on the spherical side corresponding to the mortar insertion small space portion 514 on the horseshoe side, the mortar insertion small space portion 514 and the circular hole pass through the hollow portion. In the case of steam curing, the steam is contacted evenly through the hollow hole, so that the curing quality of concrete pole is not only excellent, and the curing time of 8 hours can be shortened by 1 hour or more, thereby greatly reducing energy.

The tensioning of the tension roots 64 is accomplished by a tensioning device (not shown). The tension device may be fixed to the tension device fastening unit 530 and the tension device may be tensioned. At this time, the tension device is also provided with an insertion portion and a protrusion corresponding to the protrusion 532 and the insertion portion 534 of the tension device fastening portion 530.

The present invention predicts the deficiency of the concrete mortar on the horseshoe side caused by the compaction by the centrifugal force in the manufacturing process of the concrete pole in advance, and first, by applying a preliminary centrifugal force to the molds to reach the horseshoe shortage state and then stop the molds. Since the side is filled with insufficient concrete mortar, there is an effect that the cover thickness of the horseshoe side becomes the design thickness.

Since the lack of concrete mortar on the horse's side is added to the design thickness on the horse's side, there is no need for subsequent work to reinforce the thickness after the pole is completed, making the pole pole efficient and economical.

It is a structure that can be added to the mortar of the shortage, and it is a structure in which the fixing and support of the tensile muscles to which tension is given is supported by a mold, so the structure is simple and the fixing and support of the tensile muscles to which tension is applied is easy. .

Since the inclination of the pole is 1/75, and the inclination of the tension muscle is the same, the tension-bearing force of the tension muscle can be minimized by forming the tension-muscle insertion groove of the horse plate to match the inclination of the tension muscle. have.

Since the inlet path of the mortar insert small space part of the horse's mouth during steam curing, the steam contact is even, so that the curing quality of the concrete pole is excellent and the curing time is shortened.

Since the horseshoe plate and the horseshoe plate are integrally formed, the structure is simple, and it is a useful invention having the effect of facilitating the provision of the tensile force to the tensile muscles and at the same time the input of the mortar deficiency on the horseshoe side easily.

1A is a cutaway sectional view and a partially enlarged view showing the configuration of a conventional pole fabrication apparatus;
1B is an exploded perspective view showing the configuration of the connecting means applied to FIG.
Figure 2a cutaway sectional view and a partial enlarged view showing the configuration of a conventional pole fabrication apparatus (screw portion)
2B is an exploded perspective view showing the configuration of the connecting means applied to FIG. 2A;
3 is an exploded perspective view of a horseshoe tension plate structure formed integrally with the horseshoe plate of the present invention
Figure 4 is a perspective view of the combination of the horseshoe tension plate structure formed integrally with the horseshoe plate of the present invention
Longitudinal cross-sectional view of FIG. 4
6 is a perspective view of the tension bolt 700A

Referring to the concrete pole manufacturing method using the horseshoe tension plate structure formed integrally the horseshoe plate of the present invention in detail with the accompanying drawings as follows.

The tension root 64 is disposed in the mold 20 in which the spherical side support flange A and the spherical side support flange B are formed, and one end of the tension root 64 is supported by the spherical plate 30. It is fixed to the flange (A), and the other end of the tension root 64 is tensioned by the tension axis 50 in a state fixed to the horseshoe side, filling the concrete mortar in the mold to add a centrifugal force to the mold to produce a concrete pole In the production method

인장 Place and fix the tension root 64 in the mold 20 in which the spherical side support flange A and the spherical side support flange B are formed, and one end of the tension root 64 is driven by the spherical plate 30. It is fixed to the support flange (A), the other end of the tension root 64 is fixed by the tension hinge bolt 700 inserted into the tension bolt insertion groove 512 of the horse plate 510 having a hinge groove 516. Becoming;

걸 Hook the tensioning shaft of the tensioning device to the tensioning device fastening portion 530, tension the horse tensioning plate 520 by the tensioning axis to impart a predetermined tensile force to the tension root 64, and then the tensioning tension fixing nut 600 Inserting and rotating a tool into the tool insertion groove 610 of the c) so that the horseshoe tension fixing nut 600 is brought into close contact with the horseshoe-side support flange B so that the tension force of the tension root 64 is maintained and fixed;

(2) A rubber cap (800) formed with a catching portion (820) having an exhaust hole (830) and an inserting portion (810) is inserted into the mortar inserting space portion (514) of the horseshoe plate (520), and the tension root (64). Putting concrete mortar into the mold 20 in the tensioned state and then covering the upper and lower molds to give the mold a precentrifugal force at 500 to 1000 rpm for 5 to 10 minutes to stop the mold 20;

고무 The rubber cap 800 inserted into the mortar insertion space portion 514 of the horseshoe plate 520 is removed through the mortar insertion space portion 540 and then the concrete mortar of the shortage is molded through the mortar insertion space portion 514. Dosing in 20);

⒠ The rubber cap 800 is inserted into the mortar insertion space portion 514 through the mortar insertion space portion 514, and a concrete centrifugal force is applied to the mold 20 to produce a concrete pole, and the rubber cap 800 is removed. Then curing and demolding; It is a method of manufacturing concrete pole using a horseshoe tension plate structure formed integrally with a horseshoe plate characterized in that it comprises a.

In addition, the hinge portion 720 may be inserted into the tension bolt insertion groove 512 in the step (5) having the insertion portion 730 and the head portion 710, the hinge hinge bolt 700 formed with a hinge portion 720 is inserted. A hinge plate 516 is formed at a position corresponding to the hinge groove 516, but the hinge groove 516 has a shape close to a circle and is formed at right angles to the tension bolt insertion groove 512. Concrete pole fabrication method using the structure.

In the structure in which the horse plate 510 and the horse tension plate 520 are integrated, the mortar insertion space portion 514 formed of the horse plate 510 and the mortar insertion space portion 540 in the horse tension plate 520 are each other. Since the structure is in communication with each other, it is easy to input the mortar deficiency amount of the horseshoe into the mold.

As such, the structure in which the horse plate 510 and the horse tension plate 520 are integrally formed has a simple structure, and it is easy to apply tensile force to the tensile muscle 64, and at the same time, it is easy to add a mortar deficiency on the horse's side. to be.

20; Mold
64; Tensile muscle, 64a; Spiral
510; Horse plate, 512; Tension bolt insertion groove, 514; Mortar insertion part space part, 516; Hinge groove, 520; Horse,
522; Length adjusting spiral, 530; Tension device fastening, 532; Protrusion, 534; Insert,
540; Mortar Insert,
600; Horse Stuffed Nuts,
610; Tool insert groove, 620; Spiral
700; Tension Hinge Bolt
710; Head 720; Hinge portion, 730; The insertion portion
800; Rubber cap
810; Insert, 820; Latching portion, 830; Vent
A; Sphere Side Support Flange
B; Support Side Flange

Claims (7)

The tension root 64 is disposed in the mold 20 in which the spherical side support flange A and the spherical side support flange B are formed, and one end of the tension root 64 is supported by the spherical plate 30. It is fixed to the flange (A), and the other end of the tension root 64 is tensioned by the tension axis 50 in a state fixed to the horseshoe side, filling the concrete mortar in the mold to add a centrifugal force to the mold to produce a concrete pole In the production apparatus

The horseshoe plate 510 forming the mortar inserting space portion 514 and the horseshoe plate 520 forming the mortar inserting space portion 540 are integrally formed, but the horseshoe plate 510 is the horseshoe plate 520. While having a tension bolt insertion groove 512 into which the tension bolt 700A is inserted at the lower end of the head), it is formed at right angles to the horse tension plate 520 toward the mortar insertion large space portion 540, and the horse tension plate 520. The mortar insertion large space portion 540 therein, and the length adjusting spiral portion 522 is formed long in the outside, the adjustment spiral portion 522 is a tool insertion groove 610 and the spiral portion 620 is The formed horse tension fixing nut 600 is inserted, and the tension device fastening portion 530 is integrally perpendicular to the horse tension plate 520 outside the mortar insertion large space portion 540 at the upper end of the horse tension plate 520. While forming the integral plate is characterized in that the projection 532 and the insertion portion 534 is formed alternately Malgu tension plate structure
The method of claim 1, wherein
At the position corresponding to the hinge portion 720 so that the tensioning bolt 700 having the hinge portion 720 and the insertion portion 730 and the head portion 710 in the tension bolt insertion groove 512 can be inserted. A hinge plate 516 is formed, but the hinge groove 516 is a horseshoe tension plate structure integrally formed with a horse plate, characterized in that formed in a shape substantially close to the circular and perpendicular to the tension bolt insertion groove 512
The method according to claim 1 or 2
The horseshoe tension plate structure integrally formed with a horseshoe plate, characterized in that the direction of the tension bolt insertion groove 512 of the horseshoe plate 510 and the inclined direction of the tension root 64
The method according to claim 1 or 2
The phrase plate is characterized by inserting the rubber cap 800 formed with the engaging portion 820 having the exhaust hole 830 and the insertion portion 810 into the mortar insertion space portion 514 formed by the horse plate 510. Integrally formed sphere tension plate structure
The tension root 64 is disposed in the mold 20 in which the spherical side support flange A and the spherical side support flange B are formed, and one end of the tension root 64 is supported by the spherical plate 30. It is fixed to the flange (A), and the other end of the tension root 64 is tensioned by the tension axis 50 in a state fixed to the horseshoe side, filling the concrete mortar in the mold to add a centrifugal force to the mold to produce a concrete pole In the production method

인장 Place and fix the tension root 64 in the mold 20 in which the spherical side support flange A and the spherical side support flange B are formed, and one end of the tension root 64 is driven by the spherical plate 30. It is fixed to the support flange (A), the other end of the tension root 64 is fixed by the tension hinge bolt 700 inserted into the tension bolt insertion groove 512 of the horse plate 510 having a hinge groove 516. Becoming;

걸 Hook the tensioning shaft of the tensioning device to the tensioning device fastening portion 530, tension the horse tensioning plate 520 by the tensioning axis to impart a predetermined tensile force to the tension root 64, and then the tensioning tension fixing nut 600 Inserting and rotating a tool into the tool insertion groove 610 of the c) so that the horseshoe tension fixing nut 600 is brought into close contact with the horseshoe-side support flange B so that the tension force of the tension root 64 is maintained and fixed;

(2) A rubber cap (800) formed with a catching portion (820) having an exhaust hole (830) and an inserting portion (810) is inserted into the mortar inserting space portion (514) of the horseshoe plate (520), and the tension root (64). Putting concrete mortar into the mold 20 in the tensioned state and then covering the upper and lower molds to give the mold a precentrifugal force for 5 to 10 minutes at 500 to 1000 rpm and stopping the mold 20;

고무 The rubber cap 800 inserted into the mortar insertion space portion 514 of the horseshoe plate 520 is removed through the mortar insertion space portion 540 and then the concrete mortar of the shortage is molded through the mortar insertion space portion 514. Dosing in 20);

⒠ The rubber cap 800 is inserted into the mortar insertion space portion 514 through the mortar insertion space portion 514, and a concrete centrifugal force is applied to the mold 20 to produce a concrete pole, and the rubber cap 800 is removed. Then curing and demolding; Concrete pole production method using a horseshoe tension plate structure formed integrally with a horseshoe plate characterized in that it comprises a
The method of claim 5, wherein
Concrete poles using the horseshoe tension plate structure formed integrally with the horseshoe plate, characterized in that the direction of the tension bolt insertion groove 512 of the horseshoe plate 510 in the ⒜ step to coincide with the inclination direction of the tension root 64 How to make
The method according to claim 5 or 6
The hinge portion 720 may be inserted into the tension bolt insertion groove 512, the tension portion bolt 700 having an insertion portion 730 and the head portion 710, the hinge portion 720 is formed in the tension bolt insertion groove (512). The hinge groove 516 is formed at a position corresponding to the hinge groove 516 is a horseshoe tension plate structure integrally formed with a horse plate, characterized in that the shape close to the circular shape and formed at right angles to the tension bolt insertion groove 512 Concrete pole manufacturing method using

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