KR101501154B1 - Stressing apparatus of gear type for structure reinforcement under concrete surface, and method for the same - Google Patents

Abstract

Provided are a gear type surface-mounted tensioner device and a method thereof. The method of the gear type surface-buried tensioner device is capable of preventing a tendon from being rotated due to eccentricity by inserting the gear type tensioner device in a surface-mounted fixating unit and applying a tensible force to the same line as the tendon by the gear type tensioner device. The gear type surface-mounted device comprises: a fixating member fixating the end of one side of a tendon inserted in a concave groove of a concrete structure; a horizontal gear coupled to the fixating member in the concave groove of the concrete structure and moved by being collinearly arranged with tendon; a surface-mounted body inserted and fixated in the fixating unit, and having a space formed in order for the horizontal gear to penetrate thereinto; a circular gear having an insertion groove formed thereon, interlocked with a gear formed on the horizontal gear while being fixated inside the surface-mounted body, and rotated to make the horizontal gear penetrated into the surface-mounted body; and a rotational member rotating the circular gear by being inserted in the insertion groove formed on the circular gear in order for the horizontal gear interlocked with the circular gear to penetrate into the surface-mounted body, wherein the horizontal gear applies a tensible force to the tendon on the same line as the tendon.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a gear type surface-

The present invention relates to a tension member tensioning apparatus, and more particularly, to a tension member tensioning apparatus in which, in a post tension surface buried tensioning method, a fixation hole is embedded in a surface of a concrete structure, and tension is applied on the same line as a tension member To a gear type surface buried tension device and a method thereof.

Recently, prestressed concrete bridges using PS (Pre Stressed) steel (stranded wire or steel bar) are being actively applied to highways, national roads and provincial roads. These prestressed concrete bridges are classified into a pre-tension method and a post-tension method depending on the introduction time of the prestress. Here, the prestress is a method of applying tensile stress to compensate for weak defects of concrete Quot; refers to a force that increases tensile stress by applying a compressive force to a portion in advance.

The pre-tension method is a method of providing a compressive force to a structure by introducing a prestress by the curing of the concrete in a state where the PS steel is tense, and the post-tension method It is a method to introduce the prestress into the hydraulic jack by inserting the PS concrete into the sheath tube after the sheath tube is buried according to the linear shape of the designed tendon of the bridge, It is a method to fill a hollow space in a pipe with grouting material to complete the bridge.

Among the two methods of introducing the prestress, the pre-tension method is a state in which the tensile PS steel (stranded wire or steel bar) and the concrete are in close contact with each other without any gap. In the post-tensioning method, the tensile PS steel And grouting is performed after introducing a tension force.

Specifically, a concrete structural member such as a concrete beam of a bridge is reinforced by introducing post tension. As a method of introducing the post tension to such a concrete structural member, a tension member is disposed outside the concrete structural member, then the tension member is tensioned by using the hydraulic pressure, and the tension member is fixed to the tension member. An external post tension method is widely used.

At this time, a method is generally used in which a separate bracket is provided on the outer side surface of the concrete structural member for external post tension, the tension is applied to the tension member by applying tension at the end of the tension member, and the tension member is fixed to the bracket .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view schematically showing a mold of a bridge in which a tension device according to the prior art is used. FIG. 1 shows a state in which an external post tension is introduced in a concrete beam member under a bridge and an apparatus for tensioning the tension member.

Brackets 4 and 4 'are fixed to the both ends of the concrete beams 2 of the bridge 1 and the tension members 7 are disposed as shown in FIG. One end of the tension member 7 is fixed to one bracket 4 'by a conventional fixing device and the other end of the tension member 7 is tensioned by a hydraulic jack 9 provided on the other bracket 4. In the case of a bracket-mounted type tensional tension device for tensing the tension member 7 by using the hydraulic jack 9, the following problems occur.

First, a so-called center hall jack is used as the hydraulic jack 9. Since a large tension is required to tighten the tension member 7, the size of the hydraulic jack 9 must be increased, The size of the vertical plate 4a of the bracket 4 should be secured by the distance L1 from the side surface of the bolt member 2 to the center of the hydraulic jack 9, Since the moment applied to the bracket 4 by the tensile force of the straining material 7 is proportional to the distance L1, the longer the length of L1, the more rigid bracket 4 is required, and the bracket 4 is fixed The anchor bolts 8 should be designed to withstand large moments.

Therefore, the entire volume and weight of the bracket 4 must be increased, so that the design and installation work of the bracket 4 is not easy, and since the bracket 4 must be welded and assembled in the field, Is delayed.

In the case of such a bracket-mounted type taut strap tensioning device, since the size of the hydraulic jack 9 is large, a sufficient space for installing the hydraulic jack 9 around the end portion of the strained tension 7 should be secured, A separate jack lift device or the like may be required to support the frame 9.

In addition, in order to remove the hydraulic jack 9 after the operation of the hydraulic jack 9 and the tensioning operation, in order to remove the hydraulic jack 9 from the vertical plate 4a of the bracket 4 to the rear end of the bolt member 2 It is often difficult to secure such a working clearance in actual construction. Therefore, it is easy to install the hydraulic jack 9 and to tense the steel wire 7 There is a problem that the construction period due to a necessary preparation work may be delayed.

On the other hand, unlike the above-described bracket-installed type tensional tension device, a surface buried tension method in which a tensile material is embedded in a concrete structure without being exposed to the surface of the concrete structure has been developed.

The surface buried tensioning method according to the related art forms concave grooves at a certain depth on the outer surface of a portion of a concrete structure that needs reinforcement. Then, after the tension member is installed in the concave groove, the tension member is tensioned by using a tension device installed at the end of the concrete structure. Then, the grooved material is completely buried in the grouting material by filling the grooved material with the grouting material. Thereafter, when the grouting material cures to a predetermined strength or more, the tension device is disassembled from the tensile material, and unnecessary portions of the tensile material are removed to complete reinforcement of the concrete structure.

In the surface embedding tension method according to the related art, it is possible to easily apply a tensile force to a tensile material even at a place where the space of a concrete structure is narrow. The surface embedding tension device according to the related art is described with reference to FIGS. 2 and 3 do.

FIG. 2 is a schematic view for explaining a surface embedding tension method according to the prior art, and FIG. 3 is a perspective view showing a tension device for reinforcing a structure by a surface embedding tension method according to a conventional technique.

As shown in FIG. 2, in the surface embedding tension method according to the prior art, a fixing apparatus is embedded in the bottom surface of the reinforced concrete, for example, a tension force is introduced into the FRP tension member and the grouting member is filled.

As shown in FIG. 3, the surface buried tensioning device for introducing a tensile force into the tensile material is configured such that when the tensile stress is applied to the concrete structure by applying a tensile force to the concrete structure, the space of the end of the concrete structure is narrow It is easy to install if it is difficult to install.

A surface buried tension device according to the prior art comprises a base 12 fixed to a surface 10 to be reinforced of a concrete structure; A clamping member 18 connected to an end of the tension member 14 at a lower portion of the base 12; A moving member 22 installed to be movable in a direction to tense the tension member 14 on the base 12 and connected to the clamping member through an opening 16 formed in the base 12, ; A pressing member (24) for pressing the moving member (22) to move in a direction in which the tension member (14) is tensed; And a position fixing member 30 for fixing the position of the movable member 22 when the movable member 22 is moved so that the reinforcing member 30 is installed on the reinforcing object surface 10 of the concrete structure in parallel with the tension member 14 The tension member 14 can be tensioned in the longitudinal direction.

However, since the tension device used in the surface embedding tension method according to the related art is installed directly on the concrete structure, a large number of anchor bolts 34 are required to support the tension force introduced, The damage may be increased at the reinforcing object surface 10 of the structure.

Further, in the case of the conventional surface embedding tension device, since the clamping member 18 connected to the end portion of the tension member 14 is not fixed immediately after the tensioning operation, until the grouting member is filled and cured after the tensioning operation The tensioning device must support the tensioning force and thus the tensioning device can not be disassembled.

Therefore, the tension device used in the surface buried tension method according to the related art has a problem that the turnover rate is low and it is difficult to effectively utilize the tension device.

On the other hand, Korean Patent No. 10-1005347 discloses an invention entitled " Surface Embedding Tension Device for Strengthening Structures and Tension Method "as a related art for solving the problems of the above-mentioned surface embedding tension method. 4.

Fig. 4 is a view showing a surface buried tension device for reinforcing a structure according to the prior art, wherein Fig. 4 (a) is a perspective view with a surface buried tension device mounted on a concrete structure and Fig. 4 (b) is a sectional view.

Referring to FIG. 4, in the case of a surface buried tension device for reinforcing a structure according to the prior art, the surface of a structure C requiring structural reinforcement is fixed to each of the concave grooves 112, (120). The fusing unit 120 includes a fusing plate 124 fixed to the concave groove 112 of the concrete structure C by an anchor bolt 122. The fusing plate 124 may be, And the fusing plate 124 is formed with a vertical wall having a hole through which the end portion 132 of the tension member 130 is inserted.

The fusing plate 124 also has a hole in the center thereof which coincides with the longitudinal direction of the recessed groove 112 in which the tension member 130 is installed, Can be inserted.

The fixing plate 124 is permanently fixed to the inside of the concave groove 112 through an anchor bolt 122 to the lower side thereof, and the vertical wall is fixed to the upper surface thereof with screws (not shown) So that the power unit 140 can be fixed by assembling the bolt 128 with the hole.

In this process, the fusing plate 124 is tightened to a predetermined torque value by using the anchor bolt 122, and the gap between the fusing plate 124 and the concave groove 112 is filled with epoxy.

The surface embedding tension device 100 for reinforcing a structure according to the related art is provided with a recessed groove 112 (see FIG. 4B) which is fixed adjacent to the fusing part 120 and is provided with a tensile material 130, And a power section 140 disposed along the longitudinal direction. The power unit 140 includes a front fixing part 144 fixed to the fixing part 120 through a bolt, a plurality of guide rods 146 horizontally extending in parallel to the rear of the front fixing part 144, And a fixed support 148 connected to the rear end of the guide rod 146.

The power unit 140 includes a front fixing unit 144, a guide rod 146 and a fixed support unit 148. The movable support unit 150 is slidably movable in the guide rod 146, As shown in Fig.

The fixed support portion 148 provided at the rear end of the plurality of guide rods 146a spaced apart from the movable support portion 150 is installed at the rear of the power portion 140 so as to face the front fixing portion 144 A tension unit 156 installed to move the movable support unit 150 relative to the fixed support unit 148 is mounted between the movable support unit 150 and the fixed support unit 148.

The tension unit 156 may be, for example, a hydraulic jack, and the movable support 150 may be moved forward and backward with respect to the fixed support 148 through the operation of the hydraulic jack. The front fixing part 144, the movable supporting part 150, the fixing supporting part 148 and the tensioning part 156 constituting the power part 140 are formed as a single unit structure, The front fixing part 144, the movable supporting part 150, the fixing supporting part 148, and the tensioning part 148 constituting the power part 140 are assembled by bolting the front fixing part 144 into the bolts, The entire concrete structure 156 can be detached from the concrete structure C.

4 (b), the movable support unit 150 is capable of moving the tension member 130 by moving the tension member 130 to the lower side of the movable support member 150, thereby imparting a tensile force to the tension member 130 And the latching jaw 152 is protruded. A nut 134 may be screwed onto the tension member 130 to contact the latching jaw 152.

The tension unit 156 may further include a load cell 160 disposed between the hydraulic jack and the fixed support 148 to detect a load of the hydraulic jack so that the tension unit 156 may apply the tension applied to the tension member 130 in real time Can be measured and an accurate tension force applied to the tension member 130 can be obtained.

According to the prior art surface embedding tension device for reinforcing a structure, since the tension device can be removed from the concrete structure after the fixing of the tension material in the surface embedding tension process of the concrete structure, there is no need to install the tension device during the curing period of the grouting material , Thereby improving the equipment turnover rate.

However, in the case of a surface-buried tension device according to the prior art, the tensions embedded in the surface of the concrete structure are tense, so that the tensions and the tension devices are not in a straight line so that rotation may occur, There is a problem in that measures such as fixing the concrete structure to the concrete structure are additionally required.

Korean Patent No. 10-1005347 filed on November 13, 2008, entitled "Surface Embedded Tension Device for Strengthening Structures and Tension Method" Korean Patent No. 10-666029 filed on June 12, 2006, entitled "Frapalphan strain device without anchor fixing and method of repairing / reinforcing structure using the same" Korean Patent No. 10-653629 filed on Jan. 18, 2006, entitled "Tension device capable of tensioning the tension material placed on the inner side of the concrete structure on the surface" Korean Unexamined Patent Publication No. 2002-39640 (published May 27, 2002), entitled "Screwed tensioner device for external post tensioning of a prestressed concrete structural member" Korean Unexamined Patent Publication No. 2002-33146 (Publication Date: May 4, 2002), entitled "Method and Method for Reinforcing External Tension Material of Reinforced Concrete Structure" Japanese Unexamined Patent Publication No. 2005-155212 (Publication Date: June 16, 2005), entitled " Long Fiber Reinforcement Tension System " Japanese Patent Registration No. 3459629 filed on November 8, 2000, entitled "Anchor fixing method and anchor fixing structure" Korean Patent Publication No. 2001-54152 (published on July 2, 2001), entitled "PSS wire fixing device and post-tensioning method using the same,

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a method of fixing a tension member by inserting a gear type tension device in a surface- The present invention provides a gear type surface buried tension device and a method thereof.

As a means for achieving the above-mentioned technical object, a gear type surface buried tension device according to the present invention is a surface buried tension device which is embedded in a fixation hole formed in a concrete structure and introduces a tensile force to the stressed material, A fixing member for fixing one end of the inserted tension member; A horizontal gear engaged with the fixing member in the concave groove of the concrete structure and arranged in line with the tension member and moving; An embedding body inserted and fixed in the fixation port and having a space through which the horizontal gear can enter; A circular gear having an insertion groove formed therein and engaging with a gear formed on the horizontal gear in a state fixed to the inside of the embedding body and allowing the horizontal gear to enter the inside of the embedding body by rotation; And a rotating member inserted in an insertion groove formed in the circular gear so as to rotate the circular gear so that the horizontal gear engaged with the circular gear can enter the inside of the embedding body, And introduces a tensile force into the tensile material on the same line as the tensile material.

Here, after the tensile force is introduced into the tensile material, the concave groove of the concrete structure and the grouting material may be filled in the fixture to permanently fix the tensile material.

Here, a nut portion to be fastened to the fixing member is formed on one side of the horizontal gear, and gears are formed on both sides of the other side of the horizontal gear.

Here, the circular gear meshes with the horizontal gear on both sides of the horizontal gear, and the insertion groove formed in the circular gear may have a rectangular shape corresponding to the shape of the rotary member.

Here, a fixing device for preventing loosening of the circular gear is formed in the embedding body.

Here, the fixing member may have a thread formed on one side thereof and may be inserted into a nut portion formed in the horizontal gear.

Here, the rotary member may be an electric rotary tool that is inserted in a direction perpendicular to the circular gear, and that is rotated by an electric power, or may be a hydraulic rotary tool that is rotated by a hydraulic cylinder.

According to another aspect of the present invention, there is provided a surface buried tensioning method for introducing a tension force into a tension member embedded in a fixing hole formed in a concrete structure, the method comprising: a) Disposing a tension member in the concave groove between the first and second fixing holes formed in the structural member and fixing one end of the tension member to the first fixing hole; b) connecting and fixing the other end of the tension member to the fixing member; c) tightening a screw thread formed in the fixing member in the recessed groove to a nut portion of the horizontal gear; d) embedding an embedding body in which the circular gear is embedded in the second fixing port, and engaging the horizontal gear with the circular gear; e) inserting a rotary member into the insertion groove formed in the circular gear; And f) moving a horizontal gear engaged between the circular gears by rotating the rotary member into the embedding body to introduce a tensional force to the tension member, wherein in the step f) And introduces a tensile force into the tensile material on the same line as the tensile material.

The method may further comprise the step of: g) filling grooves in the concave grooves of the concrete structure to permanently fix the tensions in a tensioned state.

According to the present invention, it is possible to prevent the rotation of the tension member due to the eccentricity by inserting the gear-type tension device in the surface-embedded fixture and introducing the tension force on the same line as the tension member by the gear type tension device, Tension can be safely introduced into the tensions of the concrete structure.

1 is a perspective view schematically showing a mold of a bridge in which a tension device according to a conventional technique is used.
2 is a schematic view for explaining a surface embedding tension method according to the prior art.
3 is a perspective view showing a tension device for reinforcing a structure by a surface buried tension method according to a conventional technique.
4 is a view showing a surface buried tension device for reinforcing a structure according to the prior art.
5 shows a gear type surface buried tensioning device according to an embodiment of the present invention.
6A and 6B are views for explaining the operation of the gear type surface buried tension apparatus according to the embodiment of the present invention, respectively.
Figure 7 is a flow chart of the operation of a gear type surface buried tension method in accordance with an embodiment of the present invention.
8A to 8F are views for explaining a gear type surface buried tension method according to an embodiment of the present invention, respectively.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

[Gear type surface embedding tension device (300)]

FIG. 5 is a view showing a gear type surface buried tension apparatus according to an embodiment of the present invention, and FIGS. 6A and 6B are views for specifically explaining the operation of the gear type surface buried tension apparatus according to the embodiment of the present invention admit.

Referring to FIGS. 5, 6A and 6B, a gear type surface buried tension device 300 according to an embodiment of the present invention is embedded in a fixation port 220 formed in a concrete structure 210, A horizontal gear 320, an embedding body 330, a circular gear 340, and a rotating member 350. The surface gear 351 is a surface-embedded tensioning device that introduces the surface tension of the fixing member 310,

The fixing member 310 fixes one end of the tension member 240 inserted in the concave groove 230 of the concrete structure 210. At this time, the fixing member 310 may be threaded at one side thereof and inserted into a nut portion formed in the horizontal gear 320.

The horizontal gear 320 is a fixing sleeve and is fastened to the fixing member 310 in the concave groove 230 of the concrete structure 210 and is in line with the tension member 240, And moved. 6A, a nut portion to be fastened to the fixing member 310 is formed on one side of the horizontal gear 320, and a gear 321 is formed on both sides of the other side of the horizontal gear 320, .

The landfill body 330 is inserted and fixed in the fixing port 220 and a space through which the horizontal gear 320 can enter is formed.

6B, the circular gear 340 includes a plurality of circular gears 340a, 340b, and 340c having insertion grooves formed therein. The circular gears 340a, 340b, and 340c are fixed to the inside of the embedding body 330, , And the horizontal gear 320 is inserted into the interior of the embedding body 330 by rotation. The circular gear 340 is engaged with the horizontal gear 320 on both sides of the horizontal gear 320 and the insertion groove formed in the circular gear 340 is formed in the shape of the rotary member 350 But it is not limited thereto. At this time, the circular gear 340 inside the embedding body 330 can be prevented from being loosened through a separate fixing device (not shown).

6A, the rotary member 350 includes the circular gear 340 so that the horizontal gear 320 engaged with the circular gear 340 can enter the inside of the embedding body 330. [ And the circular gear 340 is rotated. Here, the rotary member 350 may be an electric rotary tool that is inserted in a direction perpendicular to the circular gear 340 and rotated by an electric power, or may be a hydraulic rotary tool that is rotated by a hydraulic cylinder.

As a result, the horizontal gear 320 enters the interior of the embedding body 330 and introduces a tension force to the tension member 240 on the same line as the tension member 240. Subsequently, after the tensional force is introduced into the tensional material 240, the grouting material 250 is filled in the concave groove 230 of the concrete structure 210 and the grouting material 250 to permanently fix the tensional material 240 .

According to the gear type surface buried tension device 300 according to the embodiment of the present invention, since the gear type tension device can be inserted into the surface buried fixture and the tension force can be introduced on the same line as the tension type by this gear type tension device Rotation of the tension member due to eccentricity can be prevented.

[Gear-type surface buried tension method]

FIG. 7 is a flowchart illustrating an operation of a gear type surface buried tension method according to an embodiment of the present invention. FIGS. 8A to 8F are views for explaining a gear type surface buried tension method according to an embodiment of the present invention, respectively.

Referring to FIG. 7, a method of surface-to-surface tampon tensioning according to an embodiment of the present invention is a surface buried tensioning method that is embedded in a fixation port 220 formed in a concrete structure 210 to introduce a tensile force into the stressed material 240, 8A, a tensile member 240 is disposed on a concave groove 230 between a first fixing port (not shown) and a second fixing port 220 formed on the concrete structural member 210, One end of the tension member 240 is fixed to the first fixing port (S110). For example, the first fixing port 220 and the second fixing port 220 are embedded in the surface of the concrete structural member 210, and one end of the tension member 240 is fixedly fixed to the first fixing port.

Next, as shown in FIG. 8B, the other end of the tension member 240 and the fixing member 310 are connected and fixed (S120).

Next, as shown in FIG. 8C, a thread 311 formed on the fixing member 310 is fastened to the nut of the horizontal gear 320 in the concave groove 230 (S130). At this time, a nut portion to be fastened to the fixing member 310 is formed on one side of the horizontal gear 320, and gears are formed on both sides of the other side of the horizontal gear 320.

8D, the embedding body 330 with the circular gear 340 embedded therein is embedded in the second fixing port 220, and the horizontal gear 320 is inserted between the circular gears 340 (S140). Here, the circular gear 340 is fixed to the inside of the embedding body 330, and engages with the horizontal gear 320 on both sides of the horizontal gear 320.

The rotary gear 350 is then inserted into the insertion groove formed in the circular gear 340 to rotate the rotary member 350 so that the rotary gear 350 is engaged with the circular gear 340, (320) to the inside of the embedding body (330) to introduce a tensile force into the tension member (S160). Specifically, as shown in FIG. 8E, as the horizontal gear 320 enters the interior of the embedding body 330, a tension is applied to the tension member 240 on the same line as the tension member 240. Here, the rotary member 350 may be an electric rotary tool that is inserted in a direction perpendicular to the circular gear 340 and rotated by an electric power, or may be a hydraulic rotary tool that is rotated by a hydraulic cylinder.

Next, as shown in FIG. 8F, the grouting material 250 is filled in the concave groove 230 of the concrete structure 210 to permanently fix the tensile material 240 in a strained state (S170).

As a result, according to the embodiment of the present invention, it is possible to insert the gear-type tension device in the surface-embedded fixing port and to introduce the tension force in the same line as the tension material by the gear type tension device, Thus, it is possible to safely introduce the tensile force into the tensile material of the concrete structure.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

210: Concrete structure
220: anchorage
230: concave groove
240: Tension material
250: Grouting material
300: Surface embedded gear tension device
310: Fixing member
320: Horizontal gear
330: Reclaimed body
340: Circular gear
350: rotating member

Claims (13)

A surface embedding tension device embedded in a fixture (220) formed in a concrete structure (210) to introduce a tensile force into a tensile material (240)
A fixing member 310 for fixing one end of the tension member 240 inserted in the concave groove 230 of the concrete structure 210;
A horizontal gear 320 fastened to the fixing member 310 in the concave groove 230 of the concrete structure 210 and arranged to move in line with the tension member 240;
An embedding body (330) inserted and fixed in the fixation port (220) and having a space into which the horizontal gear (320) can enter;
The horizontal gear 320 is engaged with the gear formed in the horizontal gear 320 while being fixed to the inside of the embedding body 330 and the horizontal gear 320 is rotated to the inside of the embedding body 330 A circular gear 340 for entering; And
The horizontal gear 320 engaged with the circular gear 340 is inserted into the insertion groove formed in the circular gear 340 so as to enter the inside of the embedding body 330 to rotate the circular gear 340 The rotation member 350,
≪ / RTI >
Wherein the horizontal gear (320) enters the interior of the embedding body (330) and introduces a tensional force to the tension member (240) on the same line as the tension member (240). The method according to claim 1,
The trench 240 is permanently fixed by filling the grooved material 250 and the grouting material 250 in the concave groove 230 of the concrete structure 210 after the tension force is introduced into the trench 240. [ A gear type surface buried tension device. The method according to claim 1,
Wherein a nut portion to be fastened to the fixing member 310 is formed on one side of the horizontal gear 320 and a gear is formed on both sides of the other side of the horizontal gear 320. The method of claim 3,
Wherein the circular gear (340) meshes with the horizontal gear (320) on both sides of the horizontal gear (320). 5. The method of claim 4,
Wherein the insertion groove formed in the circular gear (340) has a rectangular shape corresponding to the shape of the rotary member (350). The method according to claim 1,
And a fixing device for preventing the release of the circular gear (340) is formed in the embedding body (330). The method according to claim 1,
Wherein the fixing member (310) is threaded on one side and inserted into a nut portion formed on the horizontal gear (320). The method according to claim 1,
Wherein the rotary member (350) is a hydraulic rotary tool which is inserted in a direction perpendicular to the circular gear (340) and which is an electric rotary tool rotating by an electric power or rotating by a hydraulic cylinder. A surface buried tensioning method for embedding a tension in a fixture (220) formed in a concrete structure (210) to apply a tensile force to a stressed material (240)
a) placing a tension member (240) in a concave groove (230) between first and second fixing holes formed in a concrete structural member (210) and fixing one end of the tension member (240) to the first fixing hole ;
b) connecting and fixing the other end of the tension member (240) to the fixing member (310);
c) tightening a thread formed on the fixing member (310) in the recessed groove (230) to a nut portion of the horizontal gear (320);
d) embedding an embedding body (330) with a circular gear (340) in the second fixing port (220) and engaging the horizontal gear (320) with the circular gear (340);
e) inserting the rotary member (350) into the insertion groove formed in the circular gear (340); And
f) introducing a tension force to the tension member (240) by moving the horizontal gear (320) engaged between the circular gears (340) by rotating the rotary member (350) into the embedding body
, ≪ / RTI &
Wherein in step f), the horizontal gear 320 enters the interior of the embedding body 330 and introduces a tension force to the tension member 240 on the same line as the tension member 240. In this case, Way. 10. The method of claim 9,
Wherein the rotary member 350 of the step f) is a hydraulic rotary tool which is inserted in a direction perpendicular to the circular gear 340 and which is rotated by an electric motor or rotated by a hydraulic cylinder. Landfill tension method. 10. The method of claim 9,
Wherein a nut portion to be fastened to the fixing member 310 is formed on one side of the horizontal gear 320 and a gear is formed on both sides of the other side of the horizontal gear 320. 12. The method of claim 11,
Wherein the circular gear 340 is fixed within the embedding body 330 and meshes with the horizontal gear 320 on both sides of the horizontal gear 320. 10. The method of claim 9,
g) filling the grooved material (250) in the concave groove (230) of the concrete structure (210) to permanently fix the tension material (240) in a tensioned state.

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