KR20220163776A - Post-tensioning method for PSC girder using cold drawn shape memory alloy wire/cable and concrete girder for the same - Google Patents

Abstract

The present invention relates to a post-tensioning method for a prestressed concrete (PSC) girder using a cold-drawn shape memory alloy wire/cable, which can realize post-tensioning of a prestressed concrete girder without using a fixing device of a tendon and a sheath in accordance with a site condition, and provide a prestressed concrete girder with an excellent restoring force. The method comprises processes of arranging a cold-drawn shape memory alloy member with deformation in which the length is increased by cold drawing in a form, exposing both ends of the cold-drawn shape memory alloy member to the outside of the form, pouring and curing concrete to form a concrete girder body, and then connecting both ends of the cold-drawn shape memory alloy member to a power source to supply a current to the cold-drawn shape memory alloy member.

Description

Post-tensioning method for PSC girder using cold drawn shape memory alloy wire/cable and concrete girder for the same}

The present invention relates to a post-tensioning method and an improvement of a concrete girder therefor, and in particular to a post-tensioning method of a prestressed concrete girder (hereinafter referred to as "PSC girder") and an improvement of a concrete girder therefor. it's about

In general, the manufacturing technique of PS girder includes a pre-tensioning technique and a post-tensioning technique. Pre-tensioning and post-tensioning techniques each have their own strengths and weaknesses.

Since the pre-tensioning technique requires pre-tensioning of the tendon prior to concrete pouring, a frame is required to fix and tension the tendon. In addition, due to the nature of the manufacturing technique, it is almost impossible to arrange the tension member in a straight line, which is inefficient compared to the arrangement of a curve.

PS girder used in most bridges is manufactured with post-tensioning technique because post-tensioning technique enables curve arrangement and is advantageous in manufacturing large girders. However, the post-tensioning technique requires placing a sheath on a formwork and installing a tension member therein, and requires a fixing device for tensioning after concrete is poured. In particular, grouting must be performed to fill the empty space of the sheath. Not only is the process difficult, but poor grouting may cause corrosion of the tension member, and severe corrosion may cause the tension member to break.

In addition, in the case of the post-tensioning technique, since the tension member must be tensioned using a jack, most of the tension member must be performed before mounting the girder on the pier. Tensioning after mounting the girder on the pier is dangerous and difficult because the tensioning work must be performed by installing equipment at a high place.

In addition, there are cases where it is necessary to re-tension the concrete body of the PSC girder installed on the bridge. Re-tensioning on narrow and high piers is time-consuming and risky.

In order to improve the above disadvantages, 『the primary casting member provided in a cross-sectional shape in which the centroid of the cross section is eccentrically arranged and the primary casting member and the secondary casting member disposed inside the primary casting member and secondarily cast Girder portion including; A tension part disposed in a straight line or a curve across the secondary casting member to introduce prestress to the girder part; And a fixing unit arranged to face each other in the primary casting member so that both ends of the tension unit are buried, wherein the tension unit is made of a shape memory alloy material, and the tension unit is formed by heat or electricity applied to the tension unit. A shape memory effect is developed so that prestress can be introduced into the girder part' is Registration No. 10-1946731 (Title of Invention: Pretension Girder and Construction Method of the Pretension Girder, Inventor: Jeong Jeong-yeong and 3 others) It is disclosed in the Registered Patent Publication.

However, the invention of Jeong Jeong-yeong and others has a disadvantage in that the adhesive force of the tension part is small, and for this reason, both ends must be bent and buried in the girder part. It is not easy to introduce prestress to the girder in a state where both ends of the tension part are buried, and in order to introduce prestress to the girder, various additional devices will need to be installed at both ends of the tension part.

An object of the present invention is to provide a PSC girder post-tensioning method that can overcome the disadvantages of the existing pre-tensioning technique and post-tensioning technique as described above.

Another object of the present invention is to provide a PS girder post-tensioning method that enables post-tensioning of the PS girder without a fixing device for fixing the tension member to the cross-section of the concrete girder as needed.

Another object of the present invention is to provide a PSC girder post-tensioning method with excellent adhesion between the tension member and concrete.

Another object of the present invention is to provide a PS girder post-tensioning method that allows the re-tensioning work to be easily performed.

Another object of the present invention is to provide a concrete girder that enables the implementation of the PS girder post-tensioning method of the present invention.

The PSC girder post-tensioning method according to the present invention uses a cold-drawn shape memory alloy wire strained to increase length by cold drawing or a cold-drawn shape memory alloy wire strained to increase length by cold drawing. A cold-drawn shape-memory alloy member preparation step of preparing a cold-drawn shape-memory alloy member including a cold-drawn shape-memory alloy cable made by using; A cold-drawn shape memory alloy member arranging step of disposing the cold-drawn shape memory alloy member in a formwork, but exposing both ends of the cold-drawn shape memory alloy member to the outside of the formwork; A girder body forming step of forming a concrete girder body by pouring and curing concrete in the formwork; And by connecting both ends of the cold-drawn shape memory alloy member to a power supply to supply a current to the cold-drawn shape memory alloy member higher than the transformation temperature at which transformation of the cold-drawn shape memory alloy member from martensite to austenite starts. A configuration comprising a shape restoration step of applying prestress to the concrete girder body by heating to cause the cold-drawn shape memory alloy member to shrink while restoring its shape.

The cold-drawn shape memory alloy member preparation step prepares the cold-drawn shape memory alloy member including the cold-drawn shape memory alloy wire crimped on the surface, and the cold-drawn shape memory alloy member disposing step is the surface It is preferable to include arranging to be exposed to the outside so as to come into contact with the concrete on which the cold-drawn shape memory alloy wire is formed with wrinkles.

The cold-drawn shape memory alloy member preparation step, the core wire made of the cold-drawn shape memory alloy; And preparing a cable including a plurality of peripheral wires made of the cold-drawn shape memory alloy wound in the same direction along the circumference of the core wire and coupled to the core wire, wherein the plurality of peripheral wires have crimped surfaces. ) It is preferable to include preparing one made of the cold-drawn shape memory alloy wires.

In some cases, the step of preparing the cold-drawn shape memory alloy member may include preparing the cold-drawn shape memory alloy wire in which wrinkles are not formed as the core wire.

The cold-drawn shape memory alloy member preparation step may include: a first cable made of the cold-drawn shape memory alloy cable; and a second cable made of a plurality of cold-drawn shape memory alloy cables disposed while being wound in the same direction along the circumference of the first cable, wherein the plurality of second cables have wrinkles formed on their surfaces. (Crimped) It is more preferable to include preparing that the cold-drawn shape memory alloy wires are disposed.

Preferably, the step of preparing the cold-drawn shape memory alloy member includes preparing a first cable made of the cold-drawn shape memory alloy wires without wrinkles.

The step of arranging the cold-drawn shape memory alloy member preferably includes arranging the plurality of cold-drawn shape memory alloy members at intervals along a curved path.

In some cases, the cold-drawn shape memory alloy member arrangement step arranges a plurality of the cold-drawn shape memory alloy members at intervals, and the shape restoration step includes a plurality of the cold-drawn shape memory alloy members until the concrete girder body is mounted on the pier. A first shape restoration step performed first on some of the cold-drawn shape memory alloy members among the shape memory alloy members; And a second shape restoration step performed on the remaining cold-drawn shape memory alloy members among the plurality of cold-drawn shape memory alloy members after an additional fixed load is applied to the concrete girder body. .

In some cases, further comprising a fixing device installation step of installing a fixing device fixed to both ends of the cold-drawn shape memory alloy member and pressing both ends of the concrete girder body inward, wherein the fixing device installation step, attaching nut covers having spirals formed on outer circumferential surfaces to both ends of the cold-drawn shape memory alloy member before the shape restoration step; Mounting an end press plate on an outer circumferential surface of the nut cover or an outer circumferential surface of the cold-drawn memory alloy member; And by coupling a nut to the helix of the outer circumferential surface of the nut cover to press the end press plate inward so that the end press plate extends both end faces of the concrete girder body to an area larger than the cross section area of the cold-drawn shape memory alloy member. It may include a pressing step to pressurize to.

In addition, in some cases, the cold-drawn shape memory alloy member arrangement step places the cold-drawn shape memory alloy member inside the sheath disposed in the formwork, and the cold-drawn shape memory alloy member is placed between the girder body forming step and the shape restoration step. Further comprising a cold-drawn shape memory alloy member tension step of tensioning the cold-drawn shape memory alloy member using the fixing device and the jack installed at both ends of the member, wherein the shape restoration step is the shape memory alloy member tension It may be configured to include performing after loss or reduction of the prestress force of the cold-drawn shape memory alloy member strained in the step.

The concrete girder according to the present invention includes a concrete girder body; And a cold-drawn shape memory alloy member disposed inside the concrete girder body and both ends of which are exposed to the outside of both cross-sectional portions of the concrete body, wherein the cold-drawn shape memory alloy member has a length by cold drawing. It is configured to include a cold-drawn shape memory alloy cable made by using a cold-drawn shape memory alloy wire in which an increasing deformation occurs or a cold-drawn shape-memory alloy wire in which a deformation in which a length is increased by cold drawing is generated, wherein the cold-drawn shape memory alloy cable is used. By connecting both ends of the shape memory alloy member to a power source, an electric current is supplied to the cold-drawn shape memory alloy member to heat the cold-drawn shape memory alloy member higher than the transformation temperature at which transformation from martensite to austenite starts. The cold-drawn shape memory alloy member is configured to apply prestress to the concrete girder body by causing the cold-drawn shape memory alloy member to contract while restoring the shape of the drawn shape memory alloy member.

The cold-drawn shape memory alloy member preferably includes the cold-drawn shape memory alloy wire having a crimped surface.

The cold-drawn shape memory alloy member, the core wire made of the cold-drawn shape memory alloy; and a plurality of peripheral wires made of the cold-drawn shape memory alloy wound in the same direction along the circumference of the core wire and coupled to the core wire, wherein the plurality of peripheral wires are crimped on a surface of the cold-drawn shape memory alloy. It is preferable to include those made of shape memory alloy wire.

The cold-drawn shape memory alloy member may include: a first cable made of the cold-drawn shape memory alloy cable; and a second cable made of a plurality of cold-drawn shape memory alloy cables disposed while being wound in the same direction along the circumference of the first cable, wherein the plurality of second cables are crimped on a surface thereof. It is more preferable to include one made of such that the cold-drawn shape memory alloy wires are exposed to the outside.

In some cases, a fixing device fixed to both ends of the cold-drawn shape memory alloy member and pressing both ends of the concrete girder body inwardly, wherein the fixing device comprises the amount of the cold-drawn shape memory alloy member Nut covers each fixed to an end and spirally formed on an outer circumferential surface; an end pressing plate mounted on the outer circumferential surface of the nut cover or the cold-drawn shape memory alloy member; And it is coupled to the spiral of the outer circumferential surface of the nut cover and presses the end pressing plate inward so that the end pressing plate presses both end surfaces of the concrete girder body inward with an area larger than the area of the cross section of the cold-drawn shape memory alloy member. It is possible to have a configuration including a nut that does.

In addition, sometimes, a sheath disposed in a curved path inside the concrete girder body to surround the cold-drawn shape memory alloy member; And fixed to the both ends of the cold-drawn shape memory alloy member and using a jack to maintain the cold-drawn shape memory alloy member in a tense state, the both ends of the cold-drawn shape memory alloy member of the concrete girder body It may be configured to further include fixing devices supported on both end surfaces.

According to the present invention, post-tensioning of the PS girder can be implemented without using a fixing device for the sheath and the tension member according to the site conditions.

According to the present invention, the process of introducing prestress to the concrete girder body is very easy, and it is also easy to sequentially introduce prestress to the concrete girder body at intervals.

According to the present invention, after the prestress is reduced or disappears in the PS girder, stress can be easily introduced again through re-tension work.

The PS girder according to the present invention is also excellent in resilience.

1 is a process chart showing the process of the PSC girder post-tensioning method according to the present invention;
2 is a side view showing a state in which a cold-drawn shape memory alloy member is disposed in a formwork;
3 is a side view of a concrete girder according to the present invention formed by pouring and curing concrete in the formwork of FIG. 2;
4 is a side view showing a state in which post-tensioning is performed on the concrete girder of FIG. 3;
5 is a perspective view showing an example of a cable as a cold-drawn shape memory alloy member that can be used in the PS girder post-tensioning method according to the present invention;
Figure 6 is a cross-sectional view of the cable shown in Figure 5;
7 is a side view showing an example of a cold-drawn shape memory alloy straight wire constituting the core wire of the cable of FIG. 5;
8 is a side view showing a cold-drawn shape memory alloy corrugated wire constituting the peripheral wire of the cable of FIG. 5;
Figure 9 is a side view showing the exaggerated wrinkles to explain the configuration of the cold-drawn shape memory alloy corrugated wire;
10 is a cross-sectional view showing another example of a cable that can be used as a cold-drawn shape memory alloy member according to the present invention;
11 is a partial cross-sectional view of a concrete girder according to the present invention using the cable of FIG. 10;
12 (a) to 12 (d) are graphs showing the results of experiments on the expression of recovery stress for the cold-drawn shape memory alloy straight wire shown in FIG. 7 and the cold-drawn shape memory alloy corrugated wires as shown in FIG. 8, respectively;
13 is a graph showing the adhesion performance of cold-drawn shape memory alloy straight wire;
14 is a graph showing the adhesion performance of cold-drawn shape memory alloy corrugated wire;
15 to 17 are cross-sectional views showing another embodiment of a cold-drawn shape memory alloy member that can be used in the PS girder post-tensioning method according to the present invention, respectively.
18 is a side view of a mortar beam made using a cold-drawn shape memory alloy corrugated wire;
Figure 19 is a front view of the mortar beam of Figure 18;
20 is a photograph showing a state of testing the prestress effect and restoring force of the mortar beam as shown in FIG. 18;
21 is a graph showing the rising phenomenon of the beam due to the prestress effect of the mortar beam of FIG. 18;
22 is a graph showing the results of repeated loading experiments on mortar beams with prestress introduced;
23 is a partial cross-sectional view of a concrete girder for explaining another example of a concrete girder according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4, in order to perform the PS girder post-tensioning method according to the present invention, first, a cold-drawn shape memory alloy member 100 is prepared (S1).

Preferably, the cold-drawn shape memory alloy member preparation step prepares a cold-drawn shape memory alloy member 100 including a cold-drawn shape memory alloy wire crimped on the surface. Accordingly, when the cold-drawn shape memory alloy wire having wrinkles formed on the surface is disposed in the formwork 10 without a sheath, the wrinkles are exposed to the outside in the formwork 10 so as to contact concrete to be poured.

The cold-drawn shape memory alloy member 100 includes a plurality of cold-drawn shape memory alloy wires in which deformation in which length is increased by cold drawing or a plurality of cold-drawn shape memory alloy in which deformation in which length is increased by cold drawing is generated. A cold-drawn shape memory alloy cable made of wire is used. Preferably, as the cold-drawn shape memory alloy member 100 according to the present invention, a cold-drawn shape memory alloy cable is used, and preferably, several cold-drawn shape memory alloy cables are used. The cold-drawn shape memory alloy wire and the cold-drawn shape memory alloy cable are described in more detail later.

The prepared cold-drawn shape memory alloy member 100 is placed in the formwork 10, preferably, as shown in FIG. Arranged so as to be exposed (S2).

Then, when concrete is poured and cured in the formwork 10, and the formwork 10 is removed to form the concrete girder body 210 as shown in FIG. 3, the concrete girder 200 according to the present invention is completed ( S3).

After completing the concrete girder 200 as shown in FIG. 3 by forming the concrete girder body 210, as shown in FIG. 4, both ends of the cold-drawn shape memory alloy member 100 are connected to the power source 20 to By supplying current to the drawn shape memory alloy member 100, the cold drawn shape memory alloy member 100 is heated higher than the transformation temperature at which transformation begins, preferably, to the final transformation temperature, and the cold drawn shape memory alloy member (100 ) causes prestress to be applied to the concrete girder body 210 by causing it to shrink while restoring its shape. Accordingly, the PS girder 200a is completed by post-tensioning the concrete girder 200 according to the present invention (S4).

A cold-drawn shape memory alloy member that can be used in the PS girder post-tensioning method according to the present invention consisting of the above process will be described with reference to the accompanying drawings.

5 to 9, a cable 100a as shown in FIGS. 5 and 6 is used as one of the cold-drawn shape memory alloy members 100 that can be used in the PS girder post-tensioning method according to the present invention. It can be. This cable 100a has a core wire 110 and a peripheral wire 130. The use of the cold-drawn shape memory alloy member 100 in the method of the present invention is that when the shape memory alloy wire is cold-drawn, deformation occurs in the longitudinal direction, and when heat is applied, the ability to generate recovery stress by the shape memory effect is to make available.

The core wire 110 is preferably composed of a cold-drawn shape memory alloy straight wire 112 shown in FIG. 7 in which a strain is generated by increasing the length by cold drawing. This shape memory alloy straight wire 112 can be manufactured continuously in a factory, so it can be produced very effectively regardless of length.

The cable (100a) that can be used as the cold-drawn shape memory alloy member 100 according to the present invention is a plurality of peripheral wires 130 made of cold-drawn shape memory alloy corrugated wire 132 is a cold-drawn shape memory alloy straight wire ( 112) is coupled to the core wire 110 in a state wound in the same direction along the circumference of the core wire 110. The cold-drawn shape-memory alloy corrugated wire 132 is to overcome the disadvantages of the cold-drawn shape-memory alloy straight wire 112 having low adhesion strength inside the concrete or cement composite material, preferably, the cold-drawn shape memory The alloy corrugated wire 132 is formed by forming corrugations 134 on the surface by giving a bend to a straight shape memory alloy wire deformed in the longitudinal direction by cold drawing. This shape memory alloy corrugated wire 132 can also be manufactured continuously in the factory as a subsequent process of the cold-drawn shape memory alloy straight wire 112, so it can be produced very effectively regardless of length.

Examples of the cold-drawn shape memory alloy crimped wire 132 are shown in FIGS. 8 and 9 . Referring to this, if the diameter (or thickness) of the cold-drawn shape memory alloy corrugated wire 132 constituting the peripheral wire 130 in FIGS. 5 and 6 is D (0.966 mm), the corrugation 134 The pitch P is about 3.4D (3.3mm), the height H is about 1.08D (1.039mm), and the depth WD of the valley between the corrugations 134 is about 0.038D (0.037mm).

However, the pitch of the corrugations 134 of the cold-drawn shape memory alloy corrugated wire 132 as above, the height of the cold-drawn shape memory alloy corrugated wire 132 and the depth of the valley between the corrugations 134 do not cause excessive bending. may vary within a limited range. If the bending becomes excessive, the limit is reached at which recovery stress does not occur.

That is, when the cold-drawn shape memory alloy corrugated wire 132 raises the temperature to the final transformation temperature, according to the property of recovering the original deformation by transformation, when the wire is fixed, the deformation given in the longitudinal direction is recovered by the property to be recovered. Stress is generated, but the deformation given by bending by the corrugations 134 increases the length of the wire while being stretched to its original shape, thereby reducing the occurrence of stress in a fixed state. Therefore, when the recovery stress due to the recovery of the longitudinal deformation is smaller than the stress reduction due to the unfolding of the bend, the stress does not occur. It must be manufactured so that the recovery stress is expressed simultaneously.

However, the limit of bending due to wrinkles can be determined by experimentation depending on the type of material used in shape memory alloy or field requirements, etc., and the type of material used in shape memory alloy, pitch of wrinkles, or It is difficult to determine uniformly because it varies depending on the characteristics of the wire and the requirements of the site. However, for those skilled in the art, the diameter of the peripheral wire 130, the pitch of the corrugation 134, the height of the peripheral wire 130, and the corrugation ( 134) can be performed by appropriately determining the depth of the valley between them.

As can be seen from the above description, the manufacturing process of the cable 100a shown in FIGS. 5 and 6 prepares the cold-drawn shape memory alloy straight wire 112 and the plurality of cold-drawn shape memory alloy corrugated wires 132 described above. And, a plurality of cold-drawn shape memory alloy corrugated wire 132 is wound in the same direction along the circumference of the central cold-drawn shape memory alloy straight wire 112 and coupled to the central cold-drawn shape memory alloy straight wire 112 is made by the process of

Sometimes, cold-drawn shape memory alloy straight wires 112 may be used as both the plurality of peripheral wires 130 and the core wire 110, but when a large adhesive force is required, as in this embodiment, a plurality of peripheral wires It is most preferable to manufacture a cable according to the present invention using a cold-drawn shape memory alloy corrugated wire 132 as the wire 130 and using a cold-drawn shape memory alloy straight wire 112 as the core wire 110 .

In addition, it can be seen that, in some cases, the cold-drawn shape memory alloy corrugated wire 132 can be used for both the core wire 110 and the peripheral wire 130 when the cable 100a is manufactured. In this case, the concrete adhesion is almost the same as that shown in FIGS. 5 and 6, and is superior to that made only of cold-drawn shape memory alloy straight wires 112. However, since wrinkles are formed in the core wire 110, the peripheral wires 130 cannot be radially symmetrically disposed, and manufacturing will be more difficult than in this embodiment.

Furthermore, the cold-drawn shape memory alloy corrugated wire 132 shown in FIGS. 8 and 9 may be used as the cold-drawn shape memory alloy member 100 as it is. In this case, it is preferable to form a concrete girder by placing several strands of cold-drawn shape memory alloy corrugated wires 132 at intervals in the formwork, and both ends thereof should be electrically connected to each other. This is the same even when using the cold-drawn shape memory alloy straight wire 112 as the cold-drawn shape memory alloy member 100 while using the fixing device.

Referring to Figures 10 and 11, in some cases, both the core wire 110 and the peripheral wire 130 may be composed of a cold-drawn shape memory alloy straight wire (112). That is, as shown in FIG. 10, the cable 100a that can be used as the cold-drawn shape memory alloy member 100 has a plurality of peripheral wires 130 made of cold-drawn shape memory alloy straight wires 112 in a cold-drawn shape. It may be configured to be coupled to the core wire 110 in a state wound in the same direction along the circumference of the core wire 110 made of memory alloy straight wire 112.

Although the cable (100a) of this embodiment has a lower adhesion to concrete than the previous embodiment, it does not require a separate tensioning device with a large capacity and a long length for tensioning the cable in the field, and It has the advantage of making it easy to prestress for concrete structures in Of course, in this case, as shown in FIG. 11, at both ends of the concrete girder body 210 protruding to the outside, a fixing device 150 for fixing the end of the cable 100a to both end surfaces of the concrete girder body 210 ) to go through the installation process.

The anchoring device 150 is fixed to both ends of the cold-drawn shape memory alloy member 100 and supported at both ends of the concrete girder body 210. This fixing device 150 is installed before the shape restoration step described above. In the installation process of the fixing device 150, nut covers 151 having spirals formed on the outer circumferential surface are attached to both ends of the cold-drawn shape memory alloy member 100, and the outer circumferential surface of the nut cover 151 or the cold-drawn shape memory alloy The end pressing plate 153 is mounted on the outer circumferential surface of the member 100, and the nut 155 is coupled to the spiral 152 on the outer circumferential surface of the nut cover 151 to press the end pressing plate 153 inward to end the pressing plate. It is recommended that (153) press the cross-sections on both sides of the concrete girder body 210 inward with an area larger than the area of the cross-section of the cold-drawn shape memory alloy member 100. Here, the inner end of the nut cover 151 is preferably installed so as to be buried in the concrete girder body 210.

Since the anchoring device 150 as shown in FIG. 11 has the advantage of being able to apply prestress over a wide area at both end surfaces of the concrete girder body 210, when using the cable 100a shown in FIGS. 5 and 6 Of course, it can also be installed.

Referring to Figures 12 (a) to 12 (d) will be described the results of the recovery stress expression of the cold-drawn shape memory alloy straight wire and the cold-drawn shape memory alloy corrugated wires. 12 (a) to 12 (d), "straight line" refers to the cold-drawn shape memory alloy straight wire 112 shown in FIG. 7, and "wrinkles-1" to "wrinkles-4" are shown in FIG. As shown in the cold-drawn shape memory alloy corrugated wire 132, as the number increases, the depth of the valley between the corrugations 134 increases, indicating that the curvature increases. In all four cases, the temperature range of the horizontal axis and / or There is a difference in the range of stress on the vertical axis.

The test method is to fix the cold-drawn shape memory alloy straight wire 112 and the cold-drawn shape memory alloy corrugated wire 132 of the specifications shown in Table 1 to a tensile tester, create a chamber around the test wire, and wire A thermometer for temperature measurement was attached, and the heat was applied to the cold-drawn shape memory alloy straight wire 112 and the cold-drawn shape memory alloy corrugated wire 132 using a heat gun, followed by cooling.

As the temperature of the cold-drawn shape memory alloy straight wire 112 or the cold-drawn shape memory alloy corrugated wire 132 of the test object rises, recovery stress occurs while exceeding the transformation start temperature As, which changes from martensite to austenite, and the final When the transformation temperature, Af, is reached, the recovery stress is at its maximum. When heat is continuously applied above the final transformation temperature, Af, the test wire expands and the stress decreases. Lengths that expand at temperatures above Af will contract again when the temperature drops.

Figure 12 (a) to 12 (d) of the recovery stress characteristics shown in the characteristics of a specific shape memory alloy wire, it is not general. Table 1 (measured value before experiment, unit: mm) and Table 2 (measured value after experiment, unit: mm) below show the thickness of each shape memory alloy wire before and after the experiment, the depth of the valley between wrinkles, and the height.

Referring to Figures 12 (a) to 12 (d) and Tables 1 and 2 below, when heated to the same temperature, the cold-drawn shape memory alloy straight wire 112 has the largest recovery stress and the largest bend. As it increases, the expressed recovery stress decreases. As described above, this is because the stress decreases while the bent portion caused by the wrinkles 134 expands. Therefore, when the bending becomes excessive, the limit is reached at which recovery stress does not occur.

division Straight wrinkle-1 wrinkles - 2 Wrinkle-3 wrinkles - 4 Diameter or thickness (D) 0.955 0.965 0.966 0.971 0.972 height (H) - 1.017 1.039 1.077 1.138 Bone Depth (WD) - 0.052 0.073 0.106 0.166 length - 50.36 50.22 50.54 50.39

division Straight wrinkle-1 wrinkles - 2 Wrinkle-3 wrinkles - 4 Diameter or thickness (D) 0.971 0.973 0.974 0.977 0.976 height (H) - 1.000 1.014 1.037 1.087 Bone Depth (WD) - 0.027 0.040 0.060 0.111 length - 49.38 49.55 49.93 49.88

The attachment performance of the cold-drawn shape memory alloy straight wire and the cold-drawn shape memory alloy corrugated wire will be described with reference to FIGS. 5 to 11 and FIGS. 13 and 14 together.

As shown in Figure 13, the cold-drawn shape memory alloy straight wire 112 begins to be pulled out at a stress of about 39-70 MPa, but referring to Figure 14, the cold-drawn shape memory alloy corrugated wire 132 is up to 600 MPa shows the bonding strength. The cold-drawn shape memory alloy corrugated wire 132 shows an increase in adhesion performance of about 10 times compared to the cold-drawn shape memory alloy straight wire 112. This is a very advantageous characteristic for allowing the shape memory alloy wire disposed inside the cement composite material or concrete to behave integrally with the cement composite material.

Therefore, when prestress is introduced into the concrete by bringing the cold-drawn shape memory alloy corrugated wire 132 into contact with the concrete, slip does not occur due to the strong attachment stress and the predetermined prestress can be effectively introduced into the concrete girder body 210 can

On the other hand, the cold-drawn shape memory alloy straight wire 112 generates a recovery stress to some extent in the experiment, but when placed inside the concrete and induces the recovery stress, the adhesion stress is small and the recovery stress is reduced while slip occurs. Because of these characteristics, it is preferable to use a fixing device for fixing the end of the cold-drawn shape memory alloy straight wire 112 disposed on the surface.

Meanwhile, referring to FIG. 15, a first cable 101 made of the cable shown in FIG. 10 is placed in the center, and a plurality of second cables 102 made of the cable shown in FIG. The cable 100b made by being coupled to the circumference of the first cable 101 while being wound in the same direction along the circumference can be used as the cold-drawn shape memory alloy member 100 of the present invention.

When the cable 100b is manufactured in a 7x7 shape according to this embodiment, as shown in FIG. 15, the first cable 101 in the center is used as shown in FIG. By using the ones shown in , it is possible to obtain the ease of manufacture and the effect of enhancing the bonding strength at the same time. The cable 100b according to this embodiment does not need to install a fixing device or an anchoring device at the end during prestressing. In the case of pressurizing a large area on both end surfaces of the concrete girder body 210, it is of course possible to install a fixing device or an anchoring device at the end.

16 and 17, both the first cable 101 and the second cable 102 may be configured with the cable shown in FIG. 6 or the cable shown in FIG. 10, depending on circumstances.

That is, as shown in FIG. 16, both the first cable 101 and the second cable 102 may be composed of the cable shown in FIG. In this case, since both the first cable 101 and the second cable 102 must use the cold-drawn shape memory alloy corrugated wire 132, manufacturing is somewhat more difficult than that of FIG. A fixing device or anchoring device may not be installed.

In some cases, as shown in FIG. 17, both the first cable 101 and the second cable 102 may be composed of the cable shown in FIG. In this case, since both the first cable 101 and the second cable 102 are made of straight wire, it is easy to manufacture the cable 100b and has the advantage of generating a relatively large recovery stress, while the adhesive strength is low. Since it is small, it is preferable to install a fixing device or anchoring device as described in FIG. 11 at the end.

Referring to the above, any one of the cables shown in FIGS. 6 and 10 is used as the central first cable 101, and a plurality of second cables made of any one of the cables shown in FIGS. 6 and 10 It can be seen that the cable 100b according to the present invention can be made by coupling 102 to the first cable 101 while winding it in the same direction along the circumference of the first cable 101.

On the other hand, the present inventors installed the cold-drawn shape memory alloy corrugated wire 132 as shown in FIG. 8 to the mortar beam 210a as shown in FIGS. 18 and 19 to perform a prestress effect and restoring force experiment. To this end, a 1.0 mm shape memory alloy wire was cold-drawn in a straight line to a diameter of 0.96 mm, and then bent as shown in FIG. 8 to form wrinkles. As the wrinkles were formed, the height of the shape memory alloy wire with a diameter of 0.96 mm increased to 1.05 mm. Eight cold-drawn shape memory alloy corrugated wires 132 made in this way were inserted to make a mortar beam 210a having a square cross section with a width and length of 30 mm as shown in FIGS. 18 and 19. The installation height of the shape memory alloy corrugated wire 132 was such that four were installed at a height of 4 mm and 4 at a height of 6 mm from the floor.

As shown in FIG. 20, in a state where the vicinity of both ends of the mortar beam 210a made as above is supported, the height change in the central portion of the mortar beam 210a can be measured using the height measuring device 30. In the state of FIG. 20, a current is applied to the cold-drawn shape memory alloy corrugated wires 132 to raise the temperature with electrical resistance to induce transformation of the shape memory alloy, thereby recovering stress to the cold-drawn shape memory alloy corrugated wires 132 By generating a prestress force was introduced into the mortar beam (210a). The cold-drawn shape memory alloy corrugated wires 132 are, preferably, transformed from ditwined martensite to austenite as they are gradually cooled after being heated to the final transformation temperature Af or higher and then returned to the martensite state. Go through the process.

21 shows the vertical displacement behavior of the left and right central portions of the beam when the temperature of the cold-drawn shape memory alloy corrugated wire 132 is raised by electric heating. In FIG. 21, CR indicates that the shape memory alloy corrugated wire 132 was used, and EH indicates that heating was performed by electric heating. This is also the case in FIG. 22 .

In the initial stage of heating before the recovery stress is expressed in the cold-drawn shape memory alloy corrugated wire 132, sagging occurred in the mortar beam 210a due to the temperature rise. However, after a certain period of time, recovery stress due to shape restoration is expressed in the shape memory alloy corrugated wire 132, and prestress is introduced into the mortar beam 210a, and a phenomenon in which the central portion of the mortar beam 210a rises was observed. That is, through this experiment, it was found that the cold-drawn shape memory alloy corrugated wire 132 has an excellent ability to introduce prestress to the mortar beam 210a.

22 is a graph showing that deformation is generated by a load after prestress is introduced and the deformation is recovered when the load is removed, showing the displacement behavior of the mortar beam 210a to which the prestress is introduced by repeated loading experiments. . As shown in FIG. 22, it is shown that most of the generated displacement is recovered when the load is removed after the load is applied. That is, it can be seen that the PS girder according to the present invention using the cold-drawn shape memory alloy corrugated wire 132 can exhibit very excellent displacement recovery performance, unlike general reinforced concrete beams. From this graph, it was found that the cold-drawn shape memory alloy corrugated wire 132 can introduce prestress to the mortar beam 210a and exhibits very good performance in restoring force.

According to the embodiments as described above, current is first supplied to some of the cold drawn shape memory alloy members 100 of the plurality of cold drawn shape memory alloy members 100 until the concrete girder body 210 is mounted on the pier. After the first shape restoration step is performed, and an additional fixed load is applied to the concrete girder body 210, the remaining cold-drawn shape memory alloy members 100 among the plurality of cold-drawn shape memory alloy members 100 It is possible to easily perform the second shape restoration step by supplying current.

23 is a partial cross-sectional view of a concrete girder for explaining another example of a concrete girder according to the present invention.

In some cases, the concrete girder 200 according to the present invention may further include a sheath 170 disposed inside the concrete girder body 210, and the cold-drawn shape memory alloy member 100 is inside the sheath 170 can be installed on Preferably, the plurality of cold-drawn shape memory alloy members 100 may be respectively installed inside the sheath 170 arranged in a curved path at intervals.

This embodiment is provided with a fixing device 150 for supporting both ends of the cold-drawn shape memory alloy member 100 to both end surfaces of the concrete girder body 210. According to this embodiment, between the girder body forming step and the shape restoration step, the cold-drawn shape memory alloy member 100 is formed by using the fixing device 150 installed at both ends of the cold-drawn shape-memory alloy member 100 and the jack. A cold-drawn shape memory alloy member tension step of tensioning may be further included, whereby the PS girder 200a according to the present invention is made.

The shape restoration step may be performed when re-tensioning is required after a loss or decrease in the prestress force of the cold-drawn shape memory alloy member 100, which is tensioned in the shape memory alloy member tension step, occurs.

That is, according to this embodiment, the recovery stress of the shape memory alloy can be used to re-tension the concrete girder body 210.

According to the present invention as described above, if necessary, the cold-drawn shape memory alloy member is disposed along the curve in the formwork without a sheath, and the recovery stress of the cold-drawn shape memory alloy member due to post-tensioning is applied to the concrete girder body to pre-stress. can do. When applying prestress to the concrete girder body 210 by post-tensioning, the concrete girder can be placed on the ground, and electricity supply is easy even when mounted on the piers of a bridge, so it is easy to introduce prestress even when mounted on the piers. can be done

Therefore, according to the present invention, after the concrete girder is installed on the pier, prestress is introduced to some of the cold-drawn shape memory alloy members, and after an additional fixed load is applied, the prestress is introduced to the remaining cold-drawn shape memory alloy members sequentially. Phosphorus introduction can also be carried out easily.

In the case of using a cold-drawn shape-memory alloy corrugated wire or a cable having a cold-drawn shape-memory alloy corrugated wire disposed on the surface, the adhesive strength to concrete is relatively large, and the corrugations that increase the adhesive strength are preferably distributed over the entire length. Therefore, there is no need to install a fixing device at the end as in the conventional post-tensioning technique.

The present invention has the possibility of being suitably used to make a PS girder used as a superstructure of a bridge. The present invention can be used to make concrete girders of other structures as well as superstructures of bridges.

10: formwork 20: power source
30: height measuring instrument 100: cold drawing formation memory alloy member
100a, 100b: cable 101: first cable
102: second cable 110: core wire
112: cold drawn shape memory alloy straight wire
130: peripheral wire
132: cold drawn shape memory alloy corrugated wire
170: sheath 200: concrete girder
200a: PS girder 210: concrete girder body

Claims (16)

A cold-drawn shape memory alloy cable made using a cold-drawn shape memory alloy wire strained to increase length by cold drawing or a cold-drawn shape memory alloy wire strained to increase length by cold drawing A cold-drawn shape memory alloy member preparation step of preparing a cold-drawn shape memory alloy member;
A cold-drawn shape memory alloy member arranging step of disposing the cold-drawn shape memory alloy member in a formwork, but exposing both ends of the cold-drawn shape memory alloy member to the outside of the formwork;
A girder body forming step of forming a concrete girder body by pouring and curing concrete in the formwork; and
Both ends of the cold-drawn shape memory alloy member are connected to a power source and a current is supplied to the cold-drawn shape memory alloy member to heat the cold-drawn shape memory alloy member higher than the transformation temperature at which transformation from martensite to austenite starts. PS girder post-tensioning method comprising a shape restoration step of applying prestress to the concrete girder body by causing the cold-drawn shape memory alloy member to contract while restoring the shape. In claim 1, wherein the cold-drawn shape memory alloy member preparation step is to prepare the cold-drawn shape memory alloy member including the cold-drawn shape memory alloy wire crimped on the surface,
The step of arranging the cold-drawn shape memory alloy member comprises arranging the cold-drawn shape memory alloy wire having wrinkles formed on its surface to be exposed to the outside so as to come into contact with the concrete to be poured. . In claim 2, the cold-drawn shape memory alloy member preparation step,
a core wire made of the cold-drawn shape memory alloy; and
Prepare a cable including a plurality of peripheral wires made of the cold-drawn shape memory alloy wound in the same direction along the circumference of the core wire and coupled to the core wire,
The PS girder post-tensioning method comprising preparing a plurality of the peripheral wires made of the cold-drawn shape memory alloy wires crimped on the surface. In claim 3, the cold-drawn shape memory alloy member preparation step,
PS girder post-tensioning method comprising preparing the cold-drawn shape memory alloy wire in which no wrinkles are formed as the core wire. In claim 1, the cold-drawn shape memory alloy member preparation step,
a first cable made of the cold-drawn shape memory alloy cable; and
Preparing a second cable made of a plurality of the cold-drawn shape memory alloy cables disposed while being wound in the same direction along the circumference of the first cable,
The PS girder post-tensioning method comprising preparing a plurality of second cables in which the cold-drawn shape memory alloy wires crimped on the surface are disposed. In claim 5, the cold-drawn shape memory alloy member preparation step,
The PS girder post-tensioning method comprising preparing the first cable made of the cold-drawn shape memory alloy wires without wrinkles. In any one of claims 1 to 6,
The PS girder post-tensioning method, characterized in that the step of arranging the cold-drawn shape memory alloy member comprises arranging a plurality of the cold-drawn shape memory alloy members along a curved path at intervals. In any one of claims 1 to 6,
The cold-drawn shape memory alloy member arrangement step is to arrange a plurality of the cold-drawn shape memory alloy members at intervals,
The shape restoration step,
A first shape restoration step of performing first on some of the cold drawn shape memory alloy members of the plurality of cold drawn shape memory alloy members until the concrete girder body is mounted on the pier; and
PSC characterized in that it comprises a second shape restoration step performed on the remaining cold-drawn shape memory alloy members among the plurality of cold-drawn shape memory alloy members after an additional fixed load is applied to the concrete girder body. Girder post-tensioning method. In any one of claims 1 to 6,
Further comprising a fixing device installation step of installing a fixing device fixed to both ends of the cold-drawn shape memory alloy member and pressing both ends of the concrete girder body inward,
The fixing device installation step,
attaching nut covers having spirals formed on outer circumferential surfaces to both ends of the cold-drawn shape memory alloy member before the shape restoration step;
Mounting an end press plate on an outer circumferential surface of the nut cover or an outer circumferential surface of the cold-drawn memory alloy member; and
A nut is coupled to the spiral of the outer circumferential surface of the nut cover to press the end pressing plate inward so that the end pressing plate moves both end surfaces of the concrete girder body inward with an area larger than the area of the cross section of the cold-drawn shape memory alloy member. A PS girder post-tensioning method comprising a pressing step to pressurize. In any one of claims 1 to 6,
The cold-drawn shape memory alloy member arranging step is to place the cold-drawn shape memory alloy member inside the sheath disposed in the mold,
A cold-drawn shape memory alloy member for tensioning the cold-drawn shape-memory alloy member using the fixing device and the jack installed at both ends of the cold-drawn shape-memory alloy member between the girder body forming step and the shape-restoring step Including more tension stages,
The shape restoration step is performed after loss or reduction of the prestress force of the cold-drawn shape memory alloy member tensioned in the shape memory alloy member tensioning step. PS girder post-tensioning method. concrete girder body; and
It is disposed inside the concrete girder body and both ends include cold-drawn shape memory alloy members exposed to the outside of both end surfaces of the concrete body,
The cold-drawn shape memory alloy member,
Including cold-drawn shape memory alloy cables made using cold-drawn shape memory alloy wire strained to increase length by cold drawing or cold-drawn shape memory alloy wire strained to increase length by cold drawing constituted,
Both ends of the cold-drawn shape memory alloy member are connected to a power source, and an electric current is supplied to the cold-drawn shape memory alloy member to heat the cold-drawn shape memory alloy member higher than the transformation temperature at which transformation from martensite to austenite starts. The concrete girder, characterized in that it is configured to apply prestress to the concrete girder body by causing the cold-drawn shape memory alloy member to contract while restoring the shape of the cold-drawn shape memory alloy member. The concrete girder according to claim 11, wherein the cold-drawn shape memory alloy member comprises the cold-drawn shape memory alloy wire crimped on the surface. In claim 11, the cold drawn shape memory alloy member,
a core wire made of the cold-drawn shape memory alloy; and
Including a plurality of peripheral wires made of the cold-drawn shape memory alloy coupled to the core wire wound in the same direction along the circumference of the core wire,
Concrete girders, characterized in that the plurality of peripheral wires are made of the cold-drawn shape memory alloy wire crimped on the surface. In claim 11, the cold drawn shape memory alloy member,
a first cable made of the cold-drawn shape memory alloy cable; and
A second cable made of a plurality of cold-drawn shape memory alloy cables disposed while being wound in the same direction along the circumference of the first cable;
A concrete girder, characterized in that the plurality of second cables are made of such that the cold-drawn shape memory alloy wires crimped on the surface are exposed to the outside. In any one of claims 11 to 14,
Further comprising a fixing device fixed to both ends of the cold-drawn shape memory alloy member and pressing both ends of the concrete girder body inward,
The fixing device is
Nut covers fixed to both ends of the cold-drawn shape memory alloy member and spirally formed on the outer circumferential surface;
an end pressing plate mounted on the outer circumferential surface of the nut cover or the cold-drawn shape memory alloy member; and
It is coupled to the spiral of the outer circumferential surface of the nut cover and presses the end pressing plate inward so that the end pressing plate presses both end surfaces of the concrete girder body inward with an area larger than the area of the cross section of the cold drawn shape memory alloy member Pressing inward A concrete girder comprising a nut. In any one of claims 11 to 14,
a sheath disposed in a curved path inside the concrete girder body and surrounding the cold-drawn shape memory alloy member; and
The both ends of the cold-drawn shape memory alloy member are fixed to both ends of the cold-drawn shape memory alloy member and both ends of the cold-drawn shape memory alloy member are fixed to both sides of the concrete girder body so as to maintain the cold-drawn shape memory alloy member in a tense state using a jack. Concrete girder, characterized in that it further comprises a fixing device for supporting the cross section.

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