Patent Document

BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The present invention relates to a method of manufacturing pre-stressed concrete members, which are reinforced with carbon fiber, useful as pillars, columns, spars, beams or the like of building, civil engineering or offshore structures and so on. 
   2. Description of the Related Art 
   Pillar, columns, spars, beams or the like in a building, constructing or engineering field are fabricated from concrete members reinforced with steel rods or fiber-reinforced plastics (FRP). Although the steel rod is a representative reinforcing member, it is heavy and requires a broad workspace for processing and handling the reinforced concrete member. The steel rod shall be stored in a properly controlled atmosphere due to its poor corrosion-resistance. Especially, a post-tension concrete member, which has the structure that steel anchors are embedded in a concrete body at both ends, is significantly damaged in a corrosive atmosphere near a seaside. 
   Application of thermosetting carbon fibers or fiber cables to pre-stressed concrete members has been researched and developed, aiming at lightening and improved corrosion-resistance of the concrete members. In fact, prepregs, which are prepared by bundling many carbon filaments of 10 μm or less in diameter and impregnating the fiber bundle with a thermosetting primer, are sometimes used as carbon fiber cables. Composite members, which are prepared by forming and curing a woven fiber bundle, are also used for reinforcement of concrete members. 
   Thermosetting carbon fibers and carbon fiber cables are very expensive due to complicated manufacturing process, so that concrete members reinforced with such fibers or cables can not be used to various fields in point of economical view. Carbon fiber cables are often embedded in a loosed state, resulting in poor fatigue strength of the concrete members. Moreover, steel anchors, which are likely to be damaged in a corrosive atmosphere, are still used for pre-stressed concrete members reinforced with carbon fiber cables. In short, corrosion of the concrete members in a salty atmosphere is not fundamentally dissolved only by use of thermosetting carbon fibers or carbon fiber cables for reinforcement. 
   SUMMARY OF THE INVENTION 
   The present invention aims at provision of concrete members, which are reinforced with stretched straight carbon fiber cables, excellent in fatigue strength, corrosion-resistance and mechanical properties. An object of the present invention: is to offer concrete members, which can be installed without steel anchors. 
   The inventive concrete member is manufactured by either of post-tension and pre-tension processes. 
   According to a post-tension process, continuous carbon filaments are held parallel to each other and bonded together at proper parts with an adhesive to prepare a straight carbon fiber cable. After burial anchors are attached to both ends of the carbon fiber cable, the carbon fiber cable is inserted in a sheath and set in a molding box. Green concrete is poured in the molding box and steam-aged to a predetermined profile. The sheath is filled with grout under the condition that the carbon fiber cable is stretched by pulling tentative anchors. After the grout is hardened, the carbon fiber cable is released from tension. 
   According to a pre-tension process, continuous carbon filaments are held parallel to each other and bonded together at proper positions with an adhesive to prepare a straight carbon fiber cable. The carbon fiber cable is processed to a main reinforcing member by attaching burial anchors. Tentative anchors are attached to both ends of the main reinforcing member. The tentative anchors are clamped to an anchor-fixing discs. At least a carbon fiber hoop is wound around a plurality of the straight carbon fiber cables and bonded thereto with an adhesive. The main reinforcing member, which has the carbon fiber hoops fixed to the carbon fiber cables, is set in a molding box. Green concrete is poured in the molding box under the condition that the main reinforcing member is stretched by pulling the tentative anchors. The green concrete is steam-aged to a predetermined profile in the molding box. Thereafter, the main reinforcing member is released from tension. 
   In any of the post-tension and pre-tension processes, burial anchors are bonded to the carbon fiber cable at its both ends or parts near the ends. The burial anchor is prepared by forming a carbon fiber bundle to a U-shaped profile. The burial anchor may be a part of the carbon fiber cable shaped to a predetermined profile. The U-shaped anchor preferably has a flat bottom perpendicular to a longitudinal direction of the concrete member. The burial anchor is completely buried in a concrete body without such projection as noted in a conventional steel anchor. 
   A burial anchor, which is bonded to a carbon fiber cable, is a U-shaped carbon fiber cable. It is bonded to a folded end of a carbon fiber bundle extending from an end of the straight carbon fiber cable. 
   A burial anchor, which is a part of a straight carbon fiber cable, is prepared as follows: A plurality of straight carbon fiber bundles are arranged in a toroidal state each parallel to the other. A banding carbon fiber bundle is wound onto straight parts of the carbon fiber bundles. A cold-setting low-viscosity resin bond is infiltrated to the banded parts and cured, so as to form the burial anchor at both ends of the carbon fiber cable. 
   A main reinforcing member is formed to a proper length with ease by bonding two or more straight carbon fiber cables. In this case, carbon filaments of each carbon fiber cable are overlaid on and bonded to carbon filaments of the other carbon fiber cable. After each carbon fiber bundle is untied, its filaments are intertwined with filaments of the other carbon fiber bundle and the carbon fiber bundles are firmly bonded together. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1A  is a schematic view illustrating a straight carbon fiber cable, in which carbon fiber bundles are bonded together at predetermined positions along a longitudinal direction. 
       FIG. 1B  is a sectional view illustrating a straight carbon fiber cable impregnated with a cold-setting low-viscosity resin bond. 
       FIG. 2  is a side view illustrating a bonded joint between two straight carbon fiber cables. 
       FIG. 3  is a sectional view illustrating a post-tension process, whereby an anchor is bonded to an end of a straight carbon fiber cable. 
       FIG. 4A  is a perspective view illustrating a part of a straight carbon fiber cable, to which a U-shaped carbon fiber anchor is bonded. 
       FIG. 4B  is a side view illustrating the same part of the straight carbon fiber cable. 
       FIG. 5  is a plan view illustrating a U-shaped carbon fiber anchor, which will be bonded to an end of a straight carbon fiber cable. 
       FIGS. 6A ,  6 B, and  6 C together comprise a flow chart illustrating formation of a burial anchor at an end of a straight carbon fiber cable. 
       FIG. 7A  is a sectional view illustrating a steel pipe of a tentative anchor, which will be fixed to an end of a carbon fiber cable. 
       FIG. 7B  is a sectional view illustrating the same steel pipe, which has a carbon fiber cable folded and secured therein. 
       FIG. 8  is a sectional view illustrating attachment of anchors to a carbon fiber multi-cable, which is prepared by uniting two or more straight carbon fiber cables together. 
       FIG. 9  is a view illustrating a pre-tension process, whereby a pre-stressed concrete member is manufactured, using hooped straight carbon fiber cables. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   A composite member, which is prepared by impregnating a carbon fiber bundle with a thermosetting primer, forming the prepreg to a predetermined profile and then curing the thermosetting primer, has been used as a carbon fiber cable for a pre-stressed concrete member. The inventive carbon fiber cable is different from the conventional composite member, since it is fabricated without steps of pre-impregnation and thermosetting. Due to omission of pre-impregnating and thermosetting steps, the carbon fiber cable is offered at a low cost. 
   According to the present invention, carbon filaments are bundled in a state each parallel to the other, and the carbon fiber bundle is formed to a straight carbon fiber cable by application of a certain tension. A cold-setting low-viscosity resin bond is infiltrated into the straight carbon fiber cable and then cured at a temperature of 60° C. or lower during steam-aging concrete. The cold-setting low-viscosity resin bond preferably has a cure temperature of 20±10° C. and viscosity of 700–1000 mPa·sec. 
   A burial anchor is also prepared from the same straight carbon fiber cable, as follows: The straight carbon fiber cable is bent to a U-shape, and upper parts of the U-shaped carbon fiber cable are coupled with a tendon. A middle part between the coupled parts is straightened, while a bottom of the U-shaped carbon fiber cable is reformed to a flatter and wider profile than the other part. A resin bond is infiltrated into the carbon fiber cable and cured therein. The U-shaped carbon exhibits an elevated anchoring effect due to the flattened bottom, when the anchor is buried in grout hardened in a sheath or a concrete body. The anchor made of the straight carbon fiber cable is also excellent in corrosion-resistance and handled with ease. 
   A hoop, which is used in a pre-tension process, is also prepared from a straight carbon fiber cable. Two or more straight carbon fiber cables as a main reinforcing member are arranged parallel to each other. A carbon fiber hoop is wound around the straight carbon fiber cables. A cold-setting low-viscosity resin bond is infiltrated into the main reinforcing member and the hoop at the crossing points. The hoop is formed at a part of the main reinforcing member by curing the resin bond. 
   Since straight carbon fiber cables are used as main reinforcing member, burial anchors and hoops, pre-stressed concrete members, which are lightened (e.g. a fourth of a conventional concrete member reinforced with a steel rod by specific gravity) and well resistant to corrosion in a salty atmosphere, are manufactured. Due to excellent corrosion-resistance, the concrete members are easily handled or stored and also installed with good durability. 
   The other features of the present invention will be clearly understood from the following explanation consulting with drawings attached herewith. 
   [Preparation of a Straight Carbon Fiber Cable] 
   Continuous carbon filaments  11  are arranged and stretched in a state parallel to each other, so as to form a straight carbon fiber cable  10 . The carbon filaments  11  are fixed together by a cold-setting resin bond  12  at proper positions along a longitudinal direction, as shown in  FIG. 1A . In the case where the carbon fiber cable  10  is used for reinforcement of a pre-stressed concrete member, it is reformed to a tight state and impregnated with a cold-setting low-viscosity resin bond. Each carbon filament  11  is firmly bonded with the other by curing the resin bond, as shown in  FIG. 1B . Since the straight carbon fiber cable  10  is prepared by stretching continuous carbon filaments  11  and bonding the filaments  11  together, it is not loosened but improved in fatigue strength as compared with a conventional stranded cable. 
   Infiltration and curing of the cold-setting resin bond in the straight carbon fiber cable  10  may be performed in a cable-fabricating yard or a pre-stressed concrete member-manufacturing yard. In any case, use of the straight carbon fiber cable  10  remarkably eliminates difficulty on production and handling of a reinforced concrete member, and saves a working space necessary for fabrication and preparation of reinforcing members. Consequently, pre-stressed concrete members are manufactured and installed at a low cost. Moreover, it is possible to automatically on-line control arrangement of reinforcing members and production of pre-stressed concrete members. 
   Two or more straight carbon fiber cables  10  may be tied each other to a predetermined length suitable for a purpose, as shown in  FIG. 2 . When the straight carbon fiber cables  10   a ,  10   b  are tied together, carbon fibers  10   f  are preferably wound onto the tied joint for reinforcement. 
   In the case where two or more straight carbon fiber cables  10   a ,  10   b  are tied together to, a predetermined length necessary for a practical use, one straight carbon fiber cable  10   a  is overlaid on the other straight carbon fiber cable  10   b , a cold-setting resin bond  12  is infiltrated into the overlaid part of the straight carbon fiber cables  10   a ,  10   b , and the straight carbon fiber cables  10   a ,  10   b  are banded together with carbon fibers  10   f . Thereafter, the cold-setting resin bond  12  is cured so as to bond the carbon fibers  10   f  to the carbon fiber cables  10   a ,  10   b . A fiber bundle of each carbon fiber cables  10   a ,  10   b  may be untied and intertwined at the joint before infiltration of the cold-setting resin bond  12 , in order to strengthen the tied joint. 
   [Fixation of a Burial Anchor] 
   After a straight carbon fiber cable  10  is banded with a ring  31  at its end, carbon fiber bundles  13   a ,  13   b  are pulled out beyond the ring  31 . Reinforcing members  32  are bonded to the carbon fiber bundles  13   a ,  13   b  with a resin bond, and one or more U-shaped carbon fiber anchors  33 ,  33  are inserted as burial anchors between the carbon fiber bundles  13   a ,  13   b . ( FIGS. 3 ,  4 A and  4 B) 
   The U-shaped carbon fiber anchor  33  may be untied to separate filaments at jointing ends  33   e  in a predetermined length A, as shown in  FIG. 5 . The separate filaments are intertwined with filaments of the straight carbon fiber bundles  13   a ,  13   b , and a resin; bond is infiltrated into the intertwined part, whereby the U-shaped carbon fiber anchors  33  are firmly bonded to the straight carbon fiber bundles  13   a ,  13   b  by curing the infiltrated resin bond. 
   The U-shaped carbon fiber anchor  33  preferably has a flattened bottom in order to enlarge its bearing area with respect to grout  22 . The U-shaped carbon fiber anchor  33 , which is preformed to a certain profile by infiltrating a thermosetting resin bond to a part except the jointing ends  33   e  and curing the infiltrated resin bond therein, is bonded to a straight carbon fiber cable  10  in a cable-fabricating yard or a pre-stressed concrete-manufacturing yard. 
   A U-shaped carbon fiber anchor  35 , which is formed from an end part of a straight carbon fiber cable  10 , may be used instead of the separate U-shaped carbon fiber anchor  33 . The integrated U-shaped carbon fiber anchor is fabricated as follows: 
   Carbon fiber bundles  17  are arranged in a toroidal state each parallel to the other, and expanded at both ends with spacers  34   r ,  34   l , as shown in  FIG. 6(   a ). After the carbon fiber bundles  17  are stretched, a banding carbon fiber bundle  18  is helically wound on and bonded to straight parts of the carbon fiber bundles  17 . As a result, U-shaped carbon fiber anchors  35   r ,  35   l  are formed at both ends of the carbon fiber cable  10 , as shown in  FIG. 6(   b ). Carbon fiber cables  36   1r ,  36   1l ,  36   2r ,  36   2l  are properly attached to the U-shaped carbon fiber anchors  35   r ,  35   l  by winding carbon fiber reinforcing members  37   1r ,  37   1l ,  37   2r ,  37   2l  thereon, as shown in  FIG. 6(   c ). The fiber cables  36   1r ,  36   1l ,  36   2r ,  36   2l  are used for stretching the main reinforcing member  10 . 
   The reinforcing members  32 ,  37  are made of continuous carbon filaments. The stretching carbon fiber cables  36   1r ,  36   1l ,  36   2r ,  36   2l  are bonded to the integrated t-shaped carbon fiber anchors  35   r ,  35   l , by intertwining filaments of the carbon fiber cables  36   1r ,  36   1l ,  36   2r ,  36   2l  with filaments of the carbon fiber anchors  35   r ,  35   l , impregnating the intertwined part with a resin bond, and curing the resin bond therein. 
   A cold-setting low-viscosity resin bond is applied to a surface of the joint, where the U-shaped carbon fiber anchor  33  is bonded to the straight carbon fiber cable  10 , or where the stretching carbon fiber cables  36   1r ,  36   1l ,  36   2r ,  36   2l  are bonded to the U-shaped carbon fiber anchors  35   r ,  35   l  formed at end parts of the straight carbon fiber cable  10 . The reinforcing members  32 ,  37   1r ,  37   1l ,  37   2r ,  37   2l  are helically wound on the resin bond-applied surface, and then the resin bond is cured so as to firmly integrate the reinforcing members  32 ,  37   1r ,  37   1l ,  37   2r ,  37   2l  with the straight carbon fiber cable  10  and the U-shaped carbon fiber anchors  33 ,  35   r ,  35   l . Each carbon fiber bundle is preferably untied to separate filaments and intertwined together in this case, too. 
   The bonded joint is strengthened due to presence of the cured resin bond and a tightening force of the reinforcing members  32 ,  37   1r ,  37   1l ,  37   2r ,  37   2l . In fact, the U-shaped carbon fiber anchor  33  is firmly bonded to the straight carbon fiber cable  10 , or the stretching carbon fiber cables  36   1r ,  36   1l ,  36   2r ,  36   2l  is firmly bonded to the U-shaped carbon fiber anchors  35   r ,  35   l  formed at end parts of the straight carbon fiber cable  10  by enlarging a contact plane between the carbon fiber filaments, infiltrating a sufficient amount of the resin bond and raising a tightening force of the reinforcing member  32 ,  37   1r ,  37   1l ,  37   2r ,  37   2l . In prior to bonding, each carbon fiber bundle is preferably untied to separate filaments at the joint between the straight carbon fiber cable  10  and the U-shaped carbon fiber anchor  33  or between the integrated U-shaped carbon fiber anchors  35   r ,  35   l  and the stretching carbon fiber cable  36   1r ,  36   1l ,  36   2r ,  36   2l . When the separate carbon fiber filaments are intertwined each other, impregnated with the resin bond and tied with the reinforcing members  32 ,  37   1r ,  37   1l ,  37   2r ,  37   2l , the bonded joint is further strengthened due to the cured resin bond in the carbon fiber bundles. 
   The fabricated straight carbon fiber cable  10  is useful as a stretching cable in a post-tension or pre-tension process for manufacturing a pre-stressed concrete member  20 . 
   [Post-Tension Process] 
   In a post-tension process, the U-shaped carbon fiber anchor  33  is bonded to the straight carbon fiber cable  10 , tentative anchors  40   a ,  40   b  for application of an initial tension are attached to top ends of carbon fiber bundles  13   a ,  13   b  extending from the straight carbon fiber cable  10 , and then the carbon fiber bundles  13   a ,  13   b  are inserted in a sheath  21 , which preferably has a tapered inner surface  21   t  enlarged toward an opened end, as shown in  FIG. 3 . 
   A reinforcing carbon fiber cable  14  may be helically wound on the straight carbon fiber cable  10  and bonded thereto with a resin bond, in prior to insertion of the carbon fiber bundles  13   a ,  13   b  in the sheath  21 . Adhesion of grout  22  to the straight carbon fiber cable  10  is improved by the reinforcing carbon fiber cable  14 . However, an unbending post-tension process without using the reinforcing carbon fiber cable  14  is also applicable. 
   Each tentative anchor  40   a ,  40   b  has a steel pipe  41 , whose inner diameter becomes larger from one end to the other end, as shown in  FIG. 7A  Each carbon fiber bundle  13   a ,  13   b  is folded at its top end, the folded part is inserted in the steel pipe  41  from an opened end of a larger diameter. The folded part is overlaid on the straight carbon fiber cable  10  and integrally bonded thereto with a resin bond. Thereafter, the steel pipe  41  is filled with a expansive resin or concrete  42  so as to prevent the folded part of the carbon fiber bundle  13   a ,  13   b  from dropping off the steel pipe  41 , as shown in  FIG. 7B . The folded part of the carbon fiber bundle  13   a ,  13   b  may be flattened. Adhesion of the resin or expansive concrete  42  to the folded part of the carbon fiber bundle  13   a ,  13   b  can be improved by a bonding node  44 , which is formed by winding a reinforcing carbon fiber bundle  43  on the flat folded part, infiltrating and curing the resin bond in the carbon fiber bundles  13   a ,  13   b  and  43 . 
   A straight carbon fiber multi-cable  10   n  maybe used as a straight carbon fiber cable  10  inserted in a sheath  21 , in order to enhance pre-stress strength. The multi-cable  10   n  is also preferably tied with a cold-setting low-viscosity resin bond at proper positions along its longitudinal direction. 
   In the case where the straight carbon fiber multi-cable  10   n  is used, each carbon fiber bundle  13   1 ,  13   2  . . .  13   n  extending from the multi-cable  10   n  is folded and inserted in the sheath  21 , as shown in  FIG. 8 . The carbon fiber bundles  13   1 ,  13   2  . . .  13   n  are bridged with a plurality of U-shaped carbon fiber anchors  33   1 ,  33   2  . . .  33   n , and tentative anchors  40   1 ,  40   2  . . .  40   n  are attached to the carbon fiber bundles  13   1 ,  13   2  . . .  13   n . The sheath  21 , in which the folded parts of the carbon fiber bundles  13   1 ,  13   2  . . .  13   n  are inserted, is located at one side of a molding box. The multi-cable  10   n  is straightened by stretching each cable of the multi-cable  10   n.    
   After the straight carbon fiber cable  10 , to which the U-shaped carbon fiber anchor  33  is fixed, or wherein the stretching carbon fiber cables  36   1r ,  36   1l ,  36   2r ,  36   2l  are bonded to the U-shaped carbon fiber anchors  35   r ,  35   l  formed at end parts of the straight carbon fiber cable  10  ( FIGS. 6B and 6C ), is inserted in the sheath  21 , the straight carbon fiber cable  10  is set in a molding box. Green concrete is poured in the molding box under the condition that the straight carbon fiber cable  10  is stretched by pulling the tentative anchors  40   a ,  40   b.    
   After the poured concrete  23  is hardened to a predetermined profile in the molding box, a hydraulic jack is detached from the molding box without relaxation of the straight carbon fiber cable  10 . Grout  22  is then poured and hardened in the sheath  21 . Thereafter, a tacking tool is unloosed, each carbon fiber bundle  13   a ,  13   b  is cut off at a position between the tentative anchor  40   a ,  40   b  and a concrete body  23 . The pre-stressed concrete member  20  is taken out of the molding box and offered for a practical use. 
   A compression force (i.e. pre-stress), which originates in shrinkage of the straight carbon fiber cable  10  released from a tension, is applied to the pre-stressed concrete member  20  fabricated in this way, since an anchoring effect is realized by the buried carbon fiber anchor  33  and the grout  22  in the sheath  21 . 
   [Pre-tension Process] 
   A pre-tension process uses a pre-tension apparatus  50  having anchor-fixing discs  51 , to which tentative anchors  40   1 ,  40   2  . . .  40   n  can be attached with predetermined positional relationship, at both sides, as shown in  FIG. 9 . A hydraulic jack  53  is located between each anchor-fixing disc  51  and a bearing wall  52 . 
   Reinforcing members  32 , U-shaped carbon fiber anchors  33  and so on are bonded to a straight carbon fiber cable  10  by the same way as the post-tension process, except use of main reinforcing members  15   1 ,  15   2  . . .  15   n  made of the straight carbon fiber cable  10  and a hoop  16  made of the straight carbon fiber bundle. 
   A carbon fiber cable, in which a cold-setting low-viscosity resin bond is preparatively infiltrated and cured, may be used as the straight carbon fiber cable  10  for the main reinforcing members  15   1 ,  15   2  . . .  15   n  and the hoop  16 . Each tentative anchor  40   1 ,  40   2  . . .  40   n  is bonded to a corresponding carbon fiber bundle  13   1 ,  13   2  . . .  13   n , and attached to a predetermined hole of the anchor-fixing disc  51 . A sectional profile of the main reinforcing members  15   1 ,  15   2  . . .  15   n  (in other words, a pre-stressed concrete member  20 ) is determined by selection of holes of the anchor-fixing disc  51 , to which the tentative anchor  40   1 ,  40   2  . . .  40   n  are inserted. Each main reinforcing member  15   1 ,  15   2  . . .  15   n  is held parallel to the other, when its both ends are inserted in the holes of the anchor-fixing discs  51 . 
   The hoop  16  is wound around the main reinforcing members  15   1 ,  15   2  . . .  15   n , which are held with such positional relationship to define a predetermined sectional profile. The hoop  16  is bonded to the main reinforcing members  15   1 ,  15   2  . . .  15   n  at crossing points with a resin bond. 
   The main reinforcing members  15   1 ,  15   2  . . .  15   n  integrated with the hoop  16  are expanded between the anchor-fixing discs  51 ,  51 , and the tentative anchors  40   1 ,  40   2  . . .  40   n  are clamped to the anchor-fixing discs  51 ,  51 . After the main reinforcing members  15   1 ,  15   2  . . .  15   n  are set in a molding box  54 , the left-handed anchor-fixing disc  51  is shifted leftwards in  FIG. 9  by actuation of the hydraulic jack  53  so as to stretch the main reinforcing members  15   1 ,  15   2  . . .  15   n . Under the condition that the main reinforcing members  15   1 ,  15   2  . . .  15   n  are stretched with a certain tension, green concrete is poured in the molding box  54  and steam-aged therein. After the concrete is sufficiently hardened, the hydraulic jack  53  is released from a pressure. The main reinforcing members  15   1 ,  15   2  . . .  15   n  are cut off at positions between the concrete body  23  and the tentative anchors  40   1 ,  40   2  . . .  40   n , and the concrete member  20  is separated from the molding box  54 . 
   The pre-stressed concrete member  20  fabricated in this way is strengthened due to a compression force (i.e. pre-stress) originated in shrinkage of the main reinforcing members  15   1 ,  15   2  . . .  15   n  released from the tension. The bonded joints, where the hoop  16  is bonded to the main reinforcing members  15   1 ,  15   2  . . .  15   n  at a right angle, act as a series of nodes along a longitudinal direction of the main reinforcing members  15   1 ,  15   2  . . .  15   n , so as to firmly integrate the main reinforcing members  15   1 ,  15   2  . . .  15   n  with the concrete body  23  and to realize a dispersion effect of cracks. Consequently, the pre-stressed concrete member  20  is durable over a long term due to mechanical strength of the main reinforcing members  15   1 ,  15   2  . . .  15   n . 
   INDUSTRIAL APPLICABILITY 
   According to the present invention, a straight carbon fiber cable is impregnated with a cold-setting low-viscosity resin bond, stretched and molded as such in a concrete body. Arrangement of reinforcing members is fairly simplified in comparison with a conventional process using a composite member pre-cured with a thermosetting resin, and burial anchors are bonded to the straight carbon fiber cable at proper positions with ease. Since the straight carbon fiber cable is straightened by application of a tension and molded in concrete, the pre-stressed concrete member is improved in tensile strength, fatigue properties and crack-resistance. Moreover, carbon fiber cables are bonded as burial anchors to the reinforcing members instead of conventional metal fitting, so that the pre-stressed concrete member exhibits excellent corrosion-resistance even in a salty atmosphere. The pre-stressed concrete member is also handled with safe, since any part is not projected from its surface.

Technology Category: 6