CN212716021U - TRC prestressing force implementation device - Google Patents

Abstract

The utility model discloses a TRC prestress implementation device, which comprises an anchoring mechanism, a tensioning mechanism, a layered positioning mechanism and a fiber net clamp; the anchoring mechanism comprises a first anchoring crosspiece, a first centering mechanism and a first self-locking box; the tensioning mechanism comprises a second anchoring crosspiece, a second centering mechanism, a second self-locking box and a tensioning driving assembly; the fiber net clamp is wedge-shaped and comprises a clamp cover plate and a clamp bottom plate which are detachably connected; the layered positioning mechanisms are uniformly distributed between the anchoring mechanism and the tensioning mechanism and are used for forming equal-distance distribution of each layer of fiber nets in the multiple layers of fiber nets. The utility model discloses can accomplish at the job site and exert the prestressing force of multilayer fibre web not with the help of large-scale complicated equipment, realize prestressing force TRC and consolidate the RC component, whole implementation device is simple, the process flow is succinct, the construction is convenient and easily promote, has better application prospect and economic value in the engineering reinforcement field.

Description

TRC prestressing force implementation device

Technical Field

The utility model relates to a structure reinforcement construction technical field, especially a TRC prestressing force implementation device.

Background

The FRP reinforcing and repairing structure technology is a novel structure reinforcing technology after concrete section is enlarged and steel is bonded. The FRP is wrapped and adhered on the surface of the member, so that the structure is reinforced. Compared with the traditional reinforced concrete with enlarged concrete section or bonded steel concrete, the FRP reinforcing technology has the characteristics of space saving, simple and convenient construction, no need of on-site fixed facilities, easy guarantee of construction quality, no increase of structure size and dead weight basically, good corrosion resistance, good durability and the like. Therefore, FRP reinforcement technology is gaining favor and attention. However, the FRP reinforcement usually requires the use of organic resin adhesive as the adhesive, and the resin adhesive has poor aging resistance, high temperature resistance and poor adaptability to humid environment, which limits the application range of the reinforcement method. Fabric Reinforced Concrete (TRC) is a novel composite reinforcing material developed on the basis of carbon fiber reinforcing technology, and is composed of a novel composite material formed by combining high-performance fine aggregate Concrete and a multiaxial alkali-resistant fiber net, such as carbon fibers and alkali-resistant glass fibers. TRC has the following characteristics: the TRC thin wall is light in weight and high in strength, and the adopted fiber bundle is small in diameter and corrosion resistant, and does not have the requirement on the thickness of a concrete protective layer, and only the bonding and anchoring requirements are met, so that the whole unit can be made into a thin layer of 10-20 mm. The TRC has good compatibility with a structure to be reinforced, so that cracks on the surface of the component can be filled in during repair, and the defects on the surface of the component are reduced; the adopted cement-based material has the characteristics of fire resistance, high temperature resistance, ageing resistance, suitability for being used on the surface of wet concrete and the like, so that the TRC material has good reinforcing effect and applicability.

However, the conventional technique of bonding a carbon fiber cloth (mesh) to a deformable member and reinforcing the deformed member with a TRC has a problem that stress hysteresis is caused by a phenomenon that a reinforcing layer and a member to be reinforced are deteriorated. Taking reinforced concrete slab as an example, because the stress lag exists between the reinforcing steel bars of the reinforced RC plate and the fiber composite material reinforcing layer, the strain development of the fiber composite material reinforcing layer is not large when the reinforcing plate is damaged, and the tensile strength of the fiber composite material is not fully exerted.

In response to this problem, some scholars have studied and disclosed some utility patents or utility models.

Chinese patent CN205476518U discloses a prestressed carbon fiber tensioning device, which comprises an anchoring frame, a tensioning mechanism and a force application device, wherein a carbon fiber sheet is fixedly arranged on the tensioning mechanism, the force application device applies prestress to the carbon fiber sheet through the tensioning mechanism, and a glue layer is coated on the surface of the carbon fiber sheet after tensioning is completed.

The defects that the carbon fiber cloth can not be tightly attached to the surface of a member to be reinforced after being subjected to prestress tensioning, although the carbon fiber cloth can be fixed by coating organic resin adhesive, the adaptability of the resin adhesive to the high temperature resistance, the ageing resistance and the wet concrete surface is poor, and the thickness and the uniformity of the resin adhesive layer can cause the uneven stress distribution at the interface of the carbon fiber cloth and the wet concrete surface to influence the reinforcing effect; in addition, the prestressing force applying device of the carbon fiber cloth must be always effective and cannot be detached after the reinforcement is completed, otherwise serious prestressing force loss of the carbon fiber cloth caused by the interface bonding problem is serious, and the reinforcement effect is influenced.

Patent CN105350790A discloses a method for reinforcing reinforced concrete slab by using a prefabricated prestressed TRC slab, which is to attach a prefabricated prestressed TRC thin slab on the surface of reinforced concrete, aiming at fully exerting the tensile property of TRC material, but the method has the following two disadvantages: (1) the prestress is applied to the prefabricated TRC plate, and the reinforcing layer can play a role in reinforcing only when a member to be reinforced generates large deformation, so that the deformation generated in the service process of the original member cannot be recovered, and the reinforcing effect is not obvious; (2) the thickness of the prefabricated TRC plate is small, and roughening treatment cannot be carried out, so that the bonding quality between the reinforcing layer and the original component cannot be guaranteed in the implementation process, the synergistic stress of the reinforcing layer and the original component cannot be guaranteed, and damage is easily caused on the bonding surface of the reinforcing layer and the original component.

Therefore, there is a need for a new and improved pre-stressing TRC device that is simple in construction, easy to operate, and effective in pre-stressing the web.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is not enough to above-mentioned prior art, and provide a TRC prestressing force implementation device, this TRC prestressing force implementation device can accomplish not exerting the prestressing force to the multilayer fibre web with the help of large-scale complicated equipment at the job site, realizes prestressing force TRC and consolidates the RC component, and whole implementation device is simple, the process flow is succinct, construction facility and easily popularization.

In order to solve the technical problem, the utility model discloses a technical scheme is:

a TRC prestress implementation device comprises an anchoring mechanism, a tensioning mechanism, a layered positioning mechanism and a fiber net clamp.

The anchoring mechanism and the tensioning mechanism are respectively installed at two ends of the RC component to be reinforced.

The anchoring mechanism comprises a first anchoring crosspiece, a first centering mechanism and a first self-locking box.

And the anchoring crosspiece is fixedly arranged on one end surface of the RC component to be reinforced. The self-locking box I comprises a self-locking box bottom plate I and a self-locking box cover plate I which are detachably connected. The outer side end of the first self-locking box bottom plate is connected with the first anchoring crosspiece through the first centering mechanism, and the first self-locking box bottom plate can slide along the length direction of the RC component to be reinforced.

The tensioning mechanism comprises a second anchoring crosspiece, a second centering mechanism, a second self-locking box and a tensioning driving assembly.

And the second anchoring crosspiece is fixedly arranged on the other end surface of the RC component to be reinforced. The self-locking box II comprises a self-locking box bottom plate II and a self-locking box cover plate II which are detachably connected. The outer side end of the self-locking box bottom plate II is hinged with the centering mechanism II, and the other end of the centering mechanism II extends out of the anchoring crosspiece II and is connected with the tensioning driving assembly. The self-locking box base plate II can slide along the length direction of the RC component to be reinforced under the driving of the tensioning driving assembly.

The web gripper includes an anchoring end gripper and a tensioning end gripper. The anchoring end clamp is placed in the first self-locking box, and the tensioning end clamp is placed in the second self-locking box. One end of the multilayer fiber net is clamped in the anchoring end clamp, and the other end of the multilayer fiber net is clamped in the tensioning end clamp.

Anchor end anchor clamps and stretch-draw end anchor clamps all are the wedge, all include the anchor clamps apron and the anchor clamps bottom plate of dismantling the connection.

The layered positioning mechanisms are uniformly distributed between the anchoring mechanism and the tensioning mechanism and are used for forming equal-distance distribution of each layer of fiber nets in the multiple layers of fiber nets.

The tensioning driving assembly comprises a force transmission screw rod, a movable crosspiece and a jack. One end of the force transmission screw rod is connected with the centering mechanism II, and the other end of the force transmission screw rod is provided with a movable crosspiece. The jack is arranged between the second anchoring crosspiece and the moving crosspiece.

The first centering mechanism and the second centering mechanism are Y-shaped linkage rods, and hinge balls are arranged at the tail ends of the main branches of the Y-shaped linkage rods and are respectively hinged with the first self-locking box bottom plate or the second self-locking box bottom plate. The tail ends of two branches of the Y-shaped linkage rod are threaded rods. And the Y-shaped linkage rod in the centering mechanism II is a Y-shaped linkage rod II.

And the two force transmission screw rods are respectively and integrally arranged with the two threaded rods of the Y-shaped linkage rod II.

And each threaded rod or each force transmission threaded rod on the two sides of the anchoring crosspiece II is provided with a fixing nut. The movable crosspiece is in threaded connection with the free ends of the two force transmission screw rods, and each force transmission screw rod on the outer side of the movable crosspiece is provided with a fixing nut.

Each layered positioning mechanism comprises two positioning columns and a plurality of layered rolling shafts. The two positioning columns are vertically arranged on two sides of the multilayer fiber web, the number of the layered rolling shafts is larger than the number of layered layers of the multilayer fiber web, and the layered rolling shafts are uniformly arranged between the two positioning columns along the height direction.

Two ends of each layered rolling shaft are respectively provided with a spring shaft with telescopic length, and the tail end of each spring shaft is inserted into the positioning column at the corresponding end.

The inner surfaces of the clamp cover plate and the clamp bottom plate are provided with convex and concave teeth which are meshed with each other, and wavy plastic pads are arranged between the contact surfaces of the clamp cover plate and the clamp bottom plate and the multilayer fiber net.

The utility model discloses following beneficial effect has:

1. the utility model discloses need not carry out the stretch-draw of multilayer fibre web with the help of large-scale power equipment.

2. The clamping surface of the fiber net clamp is designed into arc-shaped convex-concave teeth, and two layers of wavy plastic pads are arranged inside the clamp, so that the fiber net is prevented from being cut by the fiber net clamp while strong anchoring force is guaranteed for the fiber net.

3. The layering positioning mechanism is used for layering the multiple layers of fiber nets, so that the same spacing between the layers of fiber nets is ensured, and the quality of the TRC reinforcing layer is effectively ensured.

4. The centering mechanism is arranged to ensure automatic centering of the fiber web in the tensioning process and ensure accuracy and stability of the horizontal tension value.

5. And the arrangement of the horizontal graduated scale on the longitudinal sliding rail II is convenient for controlling the tensioning process of the fiber web.

6. The prepared prestressed TRC has the advantages of good crack resistance, fire resistance, high temperature resistance and the like, and the action of the prestressed TRC can effectively avoid the stress lag problem in the traditional TRC reinforcing process and can more fully utilize the TRC performance to reinforce the component.

To sum up, the utility model relates to a in a flexible way, can require the change device size according to the component characteristics and construction, easy and simple to handle, the construction is fast, and is efficient, and application scope is wide, treats to most that the reinforcement component all can be suitable for, and effectively restraines the fissured growth of component, plays the reinforcement effect, can promote the durability of component by a wide margin.

Drawings

Fig. 1 shows a schematic structural diagram of a TRC prestress application device of the present invention.

Fig. 2 shows a schematic view of the structure of the web clamp.

Fig. 3 shows a schematic view of the anchoring mechanism.

Fig. 4 shows a structural schematic diagram of the Y-shaped linkage rod.

Fig. 5 shows a schematic view of the structure of the hinge ball.

Fig. 6 shows a schematic structural view of the self-locking box.

Fig. 7 shows a schematic view of the structure of the tensioning mechanism.

Fig. 8 shows a schematic structural diagram of a horizontal scale on the second longitudinal sliding track.

Fig. 9 shows a schematic structural view of the layered positioning mechanism.

Fig. 10 shows a schematic view of the construction of a layered roller.

Among them are:

11. anchoring the crosspiece I; 12, a first Y-shaped linkage rod; 13. hinging a ball I; 14. a first self-locking box; 141. a first self-locking box bottom plate; 142. from

A first lock box cover plate; 15. a first longitudinal sliding rail;

21. anchoring the crosspiece II; 22, a Y-shaped linkage rod II; 23. hinging a ball II; 24. a second self-locking box; 241. a second self-locking box bottom plate; 242. from

A second lock box cover plate; 25. a second longitudinal sliding rail; 26. moving the crosspiece; 27. a force transmission screw rod; 28. a jack; 29. fixing a nut;

30. fiber web clamping: 31. a clamp cover plate; 32. a clamp base plate; 33. a plastic pad;

41. a positioning column; 42. a layering roller;

50. a plurality of layers of fibrous webs.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific preferred embodiments.

In the description of the present invention, it should be understood that the terms "left side", "right side", "upper part", "lower part" and the like indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, which is only for convenience of description and simplification of description, and do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, "first", "second" and the like do not indicate the degree of importance of the component parts, and thus, are not to be construed as limiting the present invention. The specific dimensions used in the present embodiment are only for illustrating the technical solution, and do not limit the protection scope of the present invention.

As shown in fig. 1, a TRC prestressing force applying apparatus includes an anchoring mechanism, a tensioning mechanism, a layered positioning mechanism, and a web jig 30.

The anchoring mechanism and the tensioning mechanism are respectively installed at two ends of the RC component to be reinforced.

As shown in fig. 3, the anchoring mechanism includes a first anchoring rail 11, a first centering mechanism and a first locking box 14.

And the anchoring crosspiece is fixedly arranged on one end surface of the RC component to be reinforced.

As shown in fig. 6, the first self-locking box comprises a first self-locking box bottom plate 141 and a first self-locking box cover plate 142 which are detachably connected, and the first self-locking box bottom plate and the first self-locking box cover plate are preferably connected through screws.

The self-locking box bottom plate I is preferably slidably mounted on a longitudinal sliding rail I15, and the longitudinal sliding rail I15 is preferably arranged along the length direction of the RC component to be reinforced.

The outer side end of the first self-locking box bottom plate is connected with the first anchoring crosspiece through the first centering mechanism.

As shown in figure 4, the first centering mechanism is a first Y-shaped linkage rod 12, and the tail end of a main branch of the first Y-shaped linkage rod is provided with a first hinge ball 13 shown in figure 5 and hinged with the outer side end of the first self-locking box bottom plate. The tail ends of the two branches of the first Y-shaped linkage rod are preferably threaded rods and are respectively in threaded connection with the first anchoring crosspiece.

Furthermore, the middle part of the self-locking box is preferably a wedge-shaped groove matched with the fiber net clamp, and the end part of the self-locking box is provided with a spherical groove used for placing a hinge ball I13 at the end part of the Y-shaped linkage rod I12.

As shown in fig. 7, the tensioning mechanism comprises a second anchoring rail 21, a second centering mechanism, a second self-locking box 24 and a tensioning driving assembly.

And the second anchoring crosspiece is fixedly arranged on the other end surface of the RC component to be reinforced.

The second self-locking box has the same structure as the first self-locking box, and specifically comprises a second self-locking box bottom plate 241 and a second self-locking box cover plate 242 which are detachably connected.

The second self-locking box bottom plate is preferably slidably mounted on the second longitudinal sliding rail 25, and the second longitudinal sliding rail 25 is preferably arranged along the length direction of the RC component to be reinforced, so that the second self-locking box bottom plate can slide along the length direction of the RC component to be reinforced under the driving of the tensioning driving assembly.

Further, as shown in fig. 7 and 8, a horizontal scale is arranged on the second longitudinal sliding rail 25. The horizontal graduated scale can be used for judging and controlling the application condition of prestress in the tensioning process. The second longitudinal sliding rail 25 is also preferably provided with embedded screw holes, and the second longitudinal sliding rail 25 can be fixed on the surface of the RC component to be reinforced by using screws.

The outer side end of the self-locking box bottom plate II is hinged with the centering mechanism II, and the other end of the centering mechanism II extends out of the anchoring crosspiece II and is connected with the tensioning driving assembly.

The centering mechanism II is preferably a Y-shaped linkage rod II 22, and the tail end of a main branch of the Y-shaped linkage rod II is provided with a hinge ball II 23 which is respectively hinged with the self-locking box bottom plate II. The tail ends of two branches of the Y-shaped linkage rod II are threaded rods.

The tensioning drive assembly comprises a force transfer screw 27, a moving rail 26 and a jack 28.

One end of the force transmission screw is connected with the centering mechanism II, and the force transmission screw is preferably as follows: and the two force transmission screw rods are preferably arranged, one end of each force transmission screw rod is preferably arranged integrally with the threaded rods at the tail ends of the two branches in the Y-shaped linkage rod II, and the other end of each force transmission screw rod preferably penetrates out of the anchoring crosspiece II to form a penetrating end.

The jack is arranged between the second anchoring crosspiece and the moving crosspiece.

And each force transmission screw rod on two sides of the anchoring crosspiece II is preferably provided with a fixing nut 29.

The movable crosspiece is in threaded connection with the free ends (i.e. the through ends) of the two force transmission screw rods, and a fixing nut 29 is arranged on each force transmission screw rod outside the movable crosspiece.

The web gripper includes an anchoring end gripper and a tensioning end gripper. The anchoring end clamp is placed in the first self-locking box, and the tensioning end clamp is placed in the second self-locking box. One end of the multilayer fiber net is clamped in the anchoring end clamp, and the other end of the multilayer fiber net is clamped in the tensioning end clamp.

As shown in fig. 2, the anchor end clamp and the tension end clamp are both wedge-shaped and each comprise a clamp cover plate 31 and a clamp base plate 32 which are detachably connected.

The inner surfaces of the clamp cover plate 31 and the clamp bottom plate 32 are both provided with arc convex-concave teeth, embedded screw holes are arranged at four corners, and the upper part and the lower part of the clamp are tightly occluded by screwing in bolts; two layers of wavy plastic pads 33 are preferably padded in the fiber net clamp, so that the fiber net is not cut due to overlarge shearing force while the fiber net is effectively clamped.

The web clamp 30 may be secured by a self-locking box and locked during tensioning of the multi-layered web 50.

The layered positioning mechanisms are uniformly distributed between the anchoring mechanism and the tensioning mechanism and are used for forming equal-distance distribution of each layer of fiber nets in the multiple layers of fiber nets.

As shown in fig. 9, each layered positioning mechanism includes two positioning posts 41 and a plurality of layered rollers 42. The two positioning columns are vertically arranged on two sides of the multilayer fiber web, the number of the layered rolling shafts is larger than the number of layered layers of the multilayer fiber web, and the layered rolling shafts are uniformly arranged between the two positioning columns along the height direction.

As shown in fig. 10, two ends of each layered rolling shaft are respectively provided with a spring shaft with a telescopic length, and the tail end of each spring shaft is inserted into a positioning column at the corresponding end.

A construction method for reinforcing an RC member by using a TRC prestress applying device comprises the following steps.

Step 1, installing a TRC prestress implementation device on an RC component to be reinforced.

In step 1, the method for installing the TRC prestress implementing device on the RC component to be reinforced comprises the following steps.

Step 11: and measuring and paying off the surface of the RC component to be reinforced, determining a reinforced area, and detecting the position of the steel bar in the RC component to be reinforced.

Step 12: and removing impurities on the surface of the RC component to be reinforced, repairing, leveling and polishing into a rough surface, and keeping a dry state.

Step 13, installing an anchoring mechanism: and (3) installing a first anchoring crosspiece and a first longitudinal sliding roller way at one end of the reinforcing area determined in the step (11). And screws used for mounting the first anchoring crosspiece and the first longitudinal sliding roller way need to be avoided from the position of the steel bar detected in the step 11. And then, slidably mounting the self-locking box bottom plate I on the longitudinal sliding roller way I. The first centering mechanism is a Y-shaped linkage rod I. Hinge balls at the tail ends of the main branches in the first Y-shaped linkage rod are connected to the first self-locking box bottom plate, and the tail ends of the two branches of the first Y-shaped linkage rod are connected to the first anchoring crosspiece.

Step 14, installing a tensioning mechanism: and (4) installing a second anchoring crosspiece and a second longitudinal sliding roller way at the other end of the reinforcing area determined in the step 11. And screws used for mounting the second anchoring crosspiece and the second longitudinal sliding roller way also need to be avoided from the positions of the steel bars detected in the step 11. And then, installing the self-locking box bottom plate II on the longitudinal sliding roller way II in a sliding manner. And the centering mechanism II is a Y-shaped linkage rod II. The tail ends of the two branches of the Y-shaped linkage rod II are two force transmission screw rods which respectively penetrate out of the anchoring crosspiece II. And a hinge ball at the tail end of the main branch in the Y-shaped linkage rod II is connected to the self-locking box bottom plate II in a ball joint mode.

Step 15, installing a tensioning driving assembly: the tensioning drive assembly includes a jack and a moving rail. The movable crosspiece is sleeved at the tail ends of the two force transmission screw rods. The jack is arranged between the second anchoring crosspiece and the moving crosspiece.

Step 16, installing a layered positioning mechanism: the two ends close to the anchoring mechanism and the tensioning mechanism are respectively provided with a layered positioning mechanism, and a plurality of layered positioning mechanisms are arranged along the length direction of the multilayer fiber net according to a set interval: the installation method of each layered positioning mechanism comprises the following steps: two positioning columns are fixed on two sides of the RC component by adopting a pin bolt, and then a plurality of layered rolling shafts are arranged between the two positioning columns at equal intervals along the height direction of the positioning columns. The mounting method of each layered roller comprises the following steps: the spring shafts at the two ends of the layered rolling shaft are pressed firstly, so that the length of the spring shafts is contracted, and then the spring shafts are inserted into the holes of the positioning columns.

Furthermore, a horizontal scale is arranged on the surface of the longitudinal sliding roller way.

Step 2, clamping a plurality of layers of fiber nets, which specifically comprises the following steps:

step 21, positioning and layering multiple layers of fiber nets: and respectively enabling the cut multilayer fiber nets to pass through each layer of layering rolling shaft, so that the layer moments among the multilayer fiber nets are equal.

Step 22, fixing two ends of the multilayer fiber net: and (3) after the layering in the step (21) is finished, fixing one end of the multilayer fiber net by using an anchoring end clamp, and fixing the other end of the multilayer fiber net by using a tensioning end clamp.

Step 23, clamping a plurality of layers of fiber nets: and placing the anchor end clamp in a self-locking box bottom plate in the self-locking box I, and placing the tensioning end clamp in a self-locking box bottom plate in the self-locking box II. And installing and fixing a first self-locking box cover plate and a second self-locking box cover plate, and completing the clamping of the multiple layers of fiber nets. The outer side end of the first self-locking box bottom plate is connected with the first anchoring crosspiece through the first centering mechanism, and the first self-locking box bottom plate can slide along the length direction of the RC component to be reinforced. The outer side end of the self-locking box bottom plate II is hinged with the centering mechanism II, and the other end of the centering mechanism II extends out of the anchoring crosspiece II and is connected with the tensioning driving assembly.

Step 3, stretching the multilayer fiber web in a prestress manner, which comprises the following steps:

step 31, prestress tension: and a jack positioned between the second anchoring crosspiece and the moving crosspiece is used for jacking and tensioning the multiple layers of fiber nets. And in the tensioning process, recording the jacking distance in real time. Further, when stretching, preferably through observing the scale change of horizontal scale, realize the real-time recording of jacking distance.

Step 32: fixing the prestress: and when the multi-layer fiber net is stretched to a preset jacking distance (such as a set horizontal scale), the positions of the second anchoring crosspiece and the moving crosspiece on the force transmission screw rod are limited by using the fixing nuts.

In step 32, the fixed prestress F is calculated as:

F＝σ·A·n

σ＝△·E_s/L

△＝△₁-△₂

in the above formula, σ is the stress of a single fiber bundle in the multilayer fiber web; delta is the longitudinal tensile deformation of the multilayer web; delta₁In the tensioning process, the second self-locking box slides along the longitudinal direction for the moving distance of the second rail; delta₂For the sliding distance of the multi-layer fiber net in the fiber net clamp in the tensioning process, and delta₂0 is approximately distributed; a is the total cross-sectional area of the fiber bundles in the multilayer fiber web; n is the number of fiber bundles in the multilayer fiber web; l is the fiber bundle length between the two web clamps; e_sFor bullets of fibre tows in fibre websAnd (3) a sexual modulus.

Step 4, pouring concrete: erecting a template, pouring (or coating) fine aggregate concrete mortar in the template along the longitudinal direction of the beam to embed and compact a plurality of layers of fiber nets between the anchoring mechanism and the tensioning mechanism, and then curing to form a prestressed TRC reinforcing layer.

When pouring, because the multilayer fiber net is in a prestressed tensioning state, a template with the thickness of a reinforcing layer is manufactured, and grouting can be performed from the side surface or the top surface. When grouting is performed from the top surface, due to the fact that meshes of the multi-layer fiber net are large, mortar can flow freely and is dense, after grouting is completed, the side edge is sealed, and maintenance is performed.

Because each layer of fiber net is in a stretching state with preset prestress, the fiber nets are all tight, and simultaneously, because of the existence of the layering roller in the layering positioning mechanism, the thickness of concrete (mortar) among the fiber nets is uniform.

And 5, disassembling the template, the jack, the movable crosspiece and the positioning column to finish the reinforcement of the RC component.

The above detailed description describes the preferred embodiments of the present invention, but the present invention is not limited to the details of the above embodiments, and the technical idea of the present invention can be within the scope of the present invention to perform various equivalent transformations, which all belong to the protection scope of the present invention.

Claims (7)

1. A TRC prestressing force implementation device is characterized in that: the device comprises an anchoring mechanism, a tensioning mechanism, a layered positioning mechanism and a fiber net clamp;

the anchoring mechanism and the tensioning mechanism are respectively arranged at two ends of the RC component to be reinforced;

the anchoring mechanism comprises a first anchoring crosspiece, a first centering mechanism and a first self-locking box;

the anchoring crosspiece I is fixedly arranged on one end surface of the RC component to be reinforced; the self-locking box I comprises a self-locking box bottom plate I and a self-locking box cover plate I which are detachably connected; the outer side end of the first self-locking box bottom plate is connected with the first anchoring crosspiece through the first centering mechanism and can slide along the length direction of the RC component to be reinforced;

the tensioning mechanism comprises a second anchoring crosspiece, a second centering mechanism, a second self-locking box and a tensioning driving assembly;

the second anchoring crosspiece is fixedly arranged on the surface of the other end of the RC component to be reinforced; the self-locking box II comprises a self-locking box bottom plate II and a self-locking box cover plate II which are detachably connected; the outer side end of the self-locking box bottom plate II is hinged with the centering mechanism II, and the other end of the centering mechanism II extends out of the anchoring crosspiece II and is connected with the tensioning driving assembly; the self-locking box bottom plate II can slide along the length direction of the RC component to be reinforced under the driving of the tensioning driving assembly;

the fiber net clamp comprises an anchoring end clamp and a tensioning end clamp; the anchoring end clamp is placed in the first self-locking box, and the tensioning end clamp is placed in the second self-locking box; one end of the multilayer fiber net is clamped in the anchoring end clamp, and the other end of the multilayer fiber net is clamped in the tensioning end clamp;

the anchoring end clamp and the tensioning end clamp are both wedge-shaped and respectively comprise a clamp cover plate and a clamp bottom plate which are detachably connected;

the layered positioning mechanisms are uniformly distributed between the anchoring mechanism and the tensioning mechanism and are used for forming equal-distance distribution of each layer of fiber nets in the multiple layers of fiber nets.

2. The TRC prestressing implementing device according to claim 1, wherein: the tensioning driving component comprises a force transmission screw rod, a movable crosspiece and a jack; one end of the force transmission screw rod is connected with the centering mechanism II, and the other end of the force transmission screw rod is provided with a movable crosspiece; the jack is arranged between the second anchoring crosspiece and the moving crosspiece.

3. The TRC prestressing implementing device according to claim 2, wherein: the centering mechanism I and the centering mechanism II are Y-shaped linkage rods, and hinge balls are arranged at the tail ends of the main branches of the Y-shaped linkage rods and are respectively hinged with the self-locking box bottom plate I or the self-locking box bottom plate II; the tail ends of two branches of the Y-shaped linkage rod are threaded rods; the Y-shaped linkage rod in the centering mechanism II is a Y-shaped linkage rod II;

and the two force transmission screw rods are respectively and integrally arranged with the two threaded rods of the Y-shaped linkage rod II.

4. The TRC pre-stress implementing apparatus according to claim 3, wherein: each threaded rod or each force transmission screw rod on the two sides of the anchoring crosspiece II is respectively provided with a fixing nut; the movable crosspiece is in threaded connection with the free ends of the two force transmission screw rods, and each force transmission screw rod on the outer side of the movable crosspiece is provided with a fixing nut.

5. The TRC prestressing implementing device according to claim 1, wherein: each layered positioning mechanism comprises two positioning columns and a plurality of layered rolling shafts; the two positioning columns are vertically arranged on two sides of the multilayer fiber web, the number of the layered rolling shafts is larger than the number of layered layers of the multilayer fiber web, and the layered rolling shafts are uniformly arranged between the two positioning columns along the height direction.

6. The TRC pre-stress implementing apparatus according to claim 5, wherein: two ends of each layered rolling shaft are respectively provided with a spring shaft with telescopic length, and the tail end of each spring shaft is inserted into the positioning column at the corresponding end.

7. The TRC prestressing implementing device according to claim 1, wherein: the inner surfaces of the clamp cover plate and the clamp bottom plate are provided with convex and concave teeth which are meshed with each other, and wavy plastic pads are arranged between the contact surfaces of the clamp cover plate and the clamp bottom plate and the multilayer fiber net.

Images