KR101093797B1 - Clamper for fiber reinforced polymer bar - Google Patents

Abstract

The present invention relates to a clamper for clamping rod-shaped fiber mixed polymer reinforcement (1). The present invention, as one side is inserted into one end portion of the fiber mixed polymer reinforcement (1) in the state aligned with the fiber mixed polymer reinforcement (1), while being integral with the fiber mixed polymer reinforcement (1) A screw shaft 50 for substantially clamping the interpolymer reinforcement 1; It comprises; a rotating shaft 60 to be integrally connected to the other side of the screw shaft 50 to form a different angle from the screw shaft 50 to rotate the screw shaft 50 while rotating by an external force. In the present invention, since the screw shaft 50 is screwed to one end of the fiber mixed polymer reinforcement (1), the fiber mixed polymer reinforcement (1) can be firmly gripped through the screw shaft (50).

Fiber, Incorporated, Polymer, Reinforcing Bars, Clampers

Description

Clamp for fiber mixed polymer reinforcement {CLAMPER FOR FIBER REINFORCED POLYMER BAR}

The present invention relates to a clamper for clamping fibrous interpolymer reinforcement, and more particularly, to a clamper for fibrous interpolymer reinforcement, which is used for clamping the fibrous interpolymer reinforcement to measure the performance of a straight rod-shaped fiber interpolymer reinforcement. .

In particular, the present invention relates to a fiber interpolymer reinforced reinforcement clamper which can be reliably clamped while preventing breakage of the fiber intermixed polymer reinforcement.

In general, the fiber mixed polymer is commonly referred to as FRP, which stands for Fiber Reinforced Polymer, and is formed by containing special fibers such as carbon fiber, glass fiber, or aramid fiber in a matrix having a thermosetting resin as a main component. The fiber mixed polymer has excellent corrosion resistance due to its material properties, and has excellent nonmagnetic, light weight and elastic modulus. In particular, fiber interpolymers have very good tensile strength due to their high modulus. Therefore, fiber interpolymers have recently been widely used as reinforcing bars for construction because of their excellent tensile strength. Of course, the fiber mixed polymer is manufactured in the form of rebar and used as a reinforcing bar for construction. That is, the fiber mixed polymer is manufactured and used as a reinforcing bar in the form of reinforcing bars.

The reinforcing bar made of such a fiber mixed polymer, that is, the fiber mixed polymer reinforcing bar is measured by the tensile tester 10 as shown in FIG. At this time, the fiber mixed polymer reinforcement 1 is performed by the displacement transducer 16 with one end gripped by the gripper 20 as shown, and the other end bonded to the concrete 14 on the base 12. This is measured.

However, the gripper 20 described above cannot stably hold the fiber interpolymer reinforced muscle 1. Because the gripper 20 is made of metal and is designed to be suitable for reinforcing bars having strong rigidity, when the fiber mixed polymer reinforcing bar 1 is gripped, the fiber mixed polymer reinforcing bar 1 is broken (the base material of the surface Because it is fragile and broken). In particular, the above-described gripper 20 more easily breaks the fiber mixed polymer reinforcement 1 when the sawtooth-shaped unevenness is formed on the inner side that is in close contact with the outer circumferential surface of the fiber mixed polymer reinforcement 1. In addition, since the gripper 20 is formed in a plate shape, there is also a problem that the fiber mixed polymer reinforcement 1 slips off. Therefore, the fiber mixed polymer reinforcement 1 is virtually impossible to measure with the gripper 20 described above.

However, the fiber mixed polymer reinforcement (1) has excellent tensile strength and corrosion resistance, but its performance test data is insufficient because of its short history in construction. That is, the fiber mixed polymer reinforcement 1 has little accumulated information on the performance test. Therefore, fiber reinforced polymer reinforcement (1) is required to have sufficient reliability due to the characteristics used in the construction, there is a continuous need for sufficient research and accurate performance test for long-term behavior under various environmental conditions and load conditions.

The present invention has been made to solve the conventional problems as described above, and is designed to suit the material properties of the fiber mixed polymer reinforcement to prevent the breakage of the fiber mixed polymer reinforcement while firmly holding a part of the fiber mixed polymer reinforcement In addition, the object of the present invention is to provide a clamper for a fiber mixed polymer reinforcing muscle which can prevent slippage of the fiber mixed polymer reinforcing muscle by the locking structure.

In particular, to provide a fiber interpolymer reinforcement clamper which clamps the fiber interpolymer reinforcement by a screwing method by holding the fiber interpolymer reinforcement while being integrally coupled with the fiber intermixer reinforcement by screwing. Purpose.

The fiber mixed polymer reinforcement clamper according to the present invention for achieving the above object, in the clamper for fiber mixed polymer reinforcement used to clamp the fiber mixed polymer reinforcement for measuring the performance of the rod-shaped fiber mixed polymer reinforcement formed in a straight line A screw shaft which is integrally engaged with the fiber mixed polymer reinforcement and substantially clamps the fiber mixed polymer reinforcement as one side is inserted into one end of the fiber mixed polymer reinforcement in alignment with the fiber mixed polymer reinforcement; And a rotation shaft which is integrally connected to the other side of the screw shaft while forming a different angle from the screw shaft and rotates by the external force to rotate the screw shaft.

The clamper for fiber mixed polymer reinforcement according to the present invention as described above, because the screw shaft is screwed to one end of the fiber mixed polymer reinforcement, it is possible to firmly grip one end of the fiber mixed polymer reinforcement whose performance is measured, There is an effect that one end of the fiber mixed polymer reinforcement pulled by the tensile tester can be prevented from being broken.

Hereinafter, referring to the accompanying drawings, the fiber mixed polymer reinforcement clamper according to the present invention will be described as follows, and FIG. 2 is a longitudinal sectional view of the fiber mixed polymer reinforcement clamper according to the embodiment of the present invention.

As shown, the clamper for fiber mixed polymer reinforcement according to an embodiment of the present invention is a vertical screw shaft 50; It includes a rotating shaft 60 connected to the screw shaft 50 in a horizontal state.

Screw shaft 50 is a male thread is formed on the outer peripheral surface as shown is screwed to one end of the straight rod-shaped fiber mixed polymer reinforcement (1). At this time, the screw shaft 50 is inserted into one end portion of the fiber mixed polymer reinforcement (1) as shown is screwed. Of course, the fiber mixed polymer reinforcement (1) is apparent that the female threaded hole (S) is inserted into one end of the screw shaft 50 is formed on one side as shown. Therefore, the screw shaft 50 is fastened in a straight line to the fiber mixed polymer reinforcement (1) while being aligned with the fiber mixed polymer reinforcement (1). That is, the screw shaft 50 is integrally fastened to the fiber mixed polymer reinforcement (1).

The screw shaft 50 is caught in the inner circumferential surface of the female screw hole (S) as one end is screwed while being inserted into the female screw hole (S) of the fiber mixed polymer reinforcement (1). That is, the screw shaft 50 is fixed to one end of the fiber mixed polymer reinforcement 1 in a locked state.

As shown, the rotation shaft 60 is integrally connected to the other side of the screw shaft 50 to form an angle different from that of the screw shaft 50. Of course, the rotating shaft 60 is connected to the screw shaft 50 at a right angle as described above. The rotation shaft 60 is rotated by the user grip when the screw shaft 50 is screwed to the fiber mixed polymer reinforcement (1). That is, the rotating shaft 60 is rotated by an external force. At this time, the rotation shaft 60 rotates together with the screw shaft 50. Thus, the rotating shaft 60 is screwed to the screw shaft 50 to the fiber mixed polymer reinforcement (1).

Here, the above-described rotation shaft 60 is preferably manufactured separately from the screw shaft 50, it may be formed as a square bar as shown, or alternatively may be formed as a cylindrical rod. In addition, the rotating shaft 60 may be configured such that a part thereof is permanently fixed to the other side of the screw shaft 50 by welding, so as to form a single body with the screw shaft 50 as shown in the enlarged view "A" in the drawing. .

On the other hand, the fiber mixed polymer reinforcement (1) is formed in various thicknesses. In particular, the fiber mixed polymer reinforcement (1) is formed in a variety of thicknesses the same or similar to the thickness of the reinforcing bar to cope with the various reinforcing bars are formed with a diameter of about 10mm ~ 35mm. Of course, the screw shaft 50 is formed thinner than the thickness of the fiber mixed polymer reinforcement (1) to be inserted into one end of the fiber mixed polymer reinforcement (1).

On the other hand, the screw shaft 50 described above is the diameter and length is determined by the performance test conditions of the fiber mixed polymer reinforcement (1). That is, the screw shaft 50 is designed in diameter and length in consideration of the adhesion strength of the fiber mixed polymer reinforcement 1, the size of the force surface of the force device, and the like. Of course, the fiber mixed polymer reinforcement (1) is the diameter and length of the female thread hole (S) is determined by the screw shaft 50 is designed as described above.

On the other hand, the clamper for fiber mixed polymer reinforcement according to the embodiment of the present invention needs to further comprise an orthogonal bolt 70 as shown in the enlarged view "B" in the drawing. The orthogonal bolt 70 is fastened to the screw shaft 50 through the fiber mixed polymer reinforcement (1) while making orthogonal to the axial direction of the fiber mixed polymer reinforcement (1) as shown enlarged. That is, the orthogonal bolt 70 penetrates the side of the fiber mixed polymer reinforcement 1 in a horizontal state. Of course, the orthogonal bolt 70 is substantially fastened to the screw shaft 50 as the nut is fastened as shown. At this time, the screw shaft 50 is formed to be thicker than the diameter of the orthogonal bolt 70 is preferably formed a hole through which the orthogonal bolt 70 penetrates. That is, the orthogonal bolt 50 passes through the hole formed in the screw shaft 50 and is fastened to the nut described above.

The fiber mixed polymer reinforcement clamper according to the embodiment of the present invention configured as described above has a screw shaft 50 coupled to the rotating shaft 60 in a single body as shown in the female thread hole (S) of the fiber mixed polymer reinforcement (1). Is inserted. At this time, the rotation shaft 60 rotates the screw shaft 50 while being rotated by an external force. Therefore, the screw shaft 50 is inserted and screwed into the female thread hole S of the fiber mixed polymer reinforcement 1 as shown in the enlarged view "B" in the drawing. That is, the screw shaft 50 substantially clamps one end of the fiber intermixer reinforcement 1 while being integrally fastened to one end of the fiber intermixer reinforcement 1.

The screw shaft 50 is caught on the inner circumferential surface of the female screw hole (S) as one end is screwed while being inserted into the female screw hole (S) of the fiber mixed polymer reinforcement (1). Thus, the screw shaft 50 prevents the fiber admixture reinforcement 1 from being separated by sliding.

On the other hand, the fiber mixed polymer reinforcement (1) to which the screw shaft 50 is fastened is pulled at the upper end by a tensile tester (not shown). At this time, the screw shaft 50 is clamped at one end, that is, the lower end of the fiber mixed polymer reinforcement (1) to prevent the fiber mixed polymer reinforcement (1) to move upward. Therefore, the fiber mixed polymer reinforcement 1 is easily measured in tensile strength.

In this embodiment of the present invention, when the orthogonal bolt 70 as shown in the enlarged view "B" in the drawing is provided, the screw shaft 50 more firmly supports the lower end of the fiber mixed polymer reinforcement (1) can do. Therefore, the tensile tester can more accurately measure the tensile strength of the fiber mixed polymer reinforcement (1). That is, the tensile tester can more accurately measure the performance of the fiber mixed polymer reinforcement (1).

On the other hand, Figure 3 attached is a longitudinal cross-sectional view of the fiber mixed polymer reinforcement clamper according to another embodiment of the present invention, the clamper according to another embodiment further includes a holding member 82 and a fastener 84 as shown This is different from the clamper of the above-described embodiment. Accordingly, only these differences will be described with reference to the accompanying drawings.

As shown, the clamper according to another embodiment grips the grip member 82 by pressing the outer peripheral surface of one end of the fiber mixed polymer reinforcement (1). This holding member 82 is integrally fixed to the rotation shaft 60 of the clamper by the fastener 84 as shown.

Here, the gripping member 82 described above has, for example, an insertion groove G into which the fiber mixed polymer reinforcement 1 is inserted is formed along the length direction and faces each other, A plurality of pressing plates 82a for pressing at least both sides; And a fastening screw 82b which penetrates the pressure plate 82a at a right angle to the longitudinal direction and is fastened to the pressure plate 82a. That is, the holding member 82 may be configured to include a pressing plate 82a and a fastening screw 82b.

The fastener 84 described above may be, for example, a bolt that penetrates the rotation shaft 60 at a right angle and is fastened to the gripping member 82.

Here, the above-mentioned fastening screw 82b is fastened through both sides of the pressing plate 82a as shown in the enlarged view "C" in the drawing. At this time. The fastening screw 82b penetrates both sides of the insertion groove G of the pressure plate 82a as shown in an enlarged manner. Therefore, the fastening screw 82b is fastened to the pressure plate 82a past both sides of the fiber mixed polymer reinforcement 1. Of course, the plurality of pressure plates 82a pressurizes the outer circumferential surface of the fiber mixed polymer reinforcement 1 by the fastening force of the fastening screw 82b.

On the other hand, the holding member 82 is easy to grip the fiber mixed polymer reinforcement (1) because the fiber mixed polymer reinforcement (1) is inserted into the insertion groove (G) formed in the center of the inner side as shown in the enlarged view "C" Not only can you do this, but you can hold it more reliably and firmly. Of course, the gripping member 82 may grip the fiber mixed polymer reinforcement (1) more firmly when fine unevenness is formed on the inner circumferential surface of the insertion groove (G). That is, the insertion groove (G) may be formed on the inner circumferential surface fine slip to prevent slipping. Therefore, the gripping member 82 can grip the fiber mixed polymer reinforcement 1 more stably and firmly without slipping due to minute irregularities formed on the inner circumferential surface of the insertion groove G.

Such a holding member 82 is preferably formed with a flange (P) at the lower end of the pressure plate (82a) as shown in the enlarged view "C". This flange P is fastened with fasteners 84, such as bolts, as shown. Thus, the fastener 84 is firmly fixed to the gripping member 82.

On the other hand, the aforementioned screw shaft 50 and the rotating shaft 60 may be manufactured separately from each other, and may be configured to be integrally formed by the fastening member 62 as shown in the enlarged view "E" in the drawing. That is, the screw shaft 50 and the rotation shaft 60 can be formed integrally by screwing, not welding. The fastening member 62 is fastened to the end of the screw shaft 50 after vertically penetrating the rotating shaft 60 as shown. Of course, it is obvious that the screw shaft 50 should be formed with a fastening hole for fastening the fastening member 62 to the end. Therefore, the screw shaft 50 and the rotating shaft 60 can be separated from each other if necessary.

At this time, the fastening member 62 is preferably formed in a direction opposite to the screw thread direction of the screw shaft 50. That is, the fastening member 62 is preferably formed of a left screw when the screw shaft 50 is a right screw. As such, the reason why the screw thread direction of the fastening member 62 is formed opposite to the screw shaft 50 is to prevent the fastening member 62 from loosening when the screw shaft 50 is rotated. That is, when the screw thread direction of the fastening member 62 is formed to be opposite to the screw shaft 50, the fastening member 62 is turned opposite to the rotation direction of the screw shaft 50. Thus, the fastening member 62 is not only loosened even when the screw shaft 50 is rotated, but is fastened more firmly.

Since the above embodiments are merely illustrative of preferred embodiments of the present invention, the scope of application of the present invention is not limited to the above, and appropriate modifications are possible within the scope of the same idea. Therefore, since the shape and structure of each component shown in the embodiment of the present invention can be carried out by deformation, it is natural that the modification of the shape and structure belong to the appended claims of the present invention.

1 is a longitudinal sectional view showing a state of use of a general rebar clamper;

Figure 2 is a longitudinal cross-sectional view of the clamper for fiber mixed polymer reinforcement according to an embodiment of the present invention; And

Figure 3 is a longitudinal cross-sectional view of the clamper for fiber mixed polymer reinforcement according to another embodiment of the present invention.

<Description of Major Symbols in Drawing>

1: Fiber mixed polymer reinforcement

50: screw shaft

60: axis of rotation

62: fastening member

70: Ortho bolt

82: holding member

82a: pressure plate

82b: tightening screw

84: fasteners

Claims (12)

delete delete delete delete delete delete delete delete delete In the clamper for fiber mixed polymer reinforcement used to hold the fiber mixed polymer reinforcement (1) to measure the performance of the bar-shaped fiber mixed polymer reinforcement (1) formed in a straight line, As one side is inserted into one end portion of the fiber mixed polymer reinforcement (1) in a state aligned with the fiber mixed polymer reinforcement (1), while being integral with the fiber mixed polymer reinforcement (1), the fiber mixed polymer reinforcement ( A screw shaft 50 for substantially clamping 1); And And a rotation shaft 60 which is integrally connected to the other side of the screw shaft 50 to form a different angle from the screw shaft 50 to rotate the screw shaft 50 while rotating by an external force. The rotating shaft 60 is manufactured separately from the screw shaft 50, and forms a unitary body with the screw shaft 50 as a part is permanently fixed to the other side of the screw shaft 50 by welding: A gripping member 82 which presses and grips an outer peripheral surface of one end of the fiber mixed polymer reinforcement 1 and is integrally connected to the rotating shaft 60; And And a fastener 84 integrally fixing the gripping member 82 to the rotational shaft 60. The holding member 82 is, Insertion grooves (G) into which the fiber mixed polymer reinforcement (1) is inserted are formed along the longitudinal direction, and press at least both sides of the fiber mixed polymer reinforcement (1) facing each other, and the fastener (84) is fastened to the lower end. A plurality of pressure plates 82a in which the flanges P are integrally bent; And And a fastening screw 82b penetrating the pressure plates 82a at right angles to the pressure plates 82a to be fastened to the pressure plates 82a. The fastener 84 consists of a bolt which penetrates the rotation shaft 60 at right angles and is fastened to the pressing plate 82a of the gripping member 82: Clamper for fiber mixed polymer reinforcement, characterized in that the concave-convex contact with the outer surface of the fiber mixed polymer reinforcement (1) is formed in the center of the inner surface of the pressure plate (82a). delete delete

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