KR20200052767A - Concrete panel specimen for fiber mesh pull-out test and method for manufacturing the same, pull-out testing method for fiber mesh and pull-out tester for fiber mesh - Google Patents

Abstract

Disclosed are a concrete panel specimen for a fiber mesh pull-out test and a manufacturing method thereof, a pull-out testing method of a fiber mesh, and a pull-out testing apparatus of the fiber mesh. According to one aspect of the present invention, as the specimen for performing the fiber mesh pull-out test consisting of a polymer fiber comprising a warp yarn and a weft yarn disposed in the transverse direction to the warp, provided is the specimen for the fiber mesh pull-out test, comprising: a rectangular-shaped concrete panel; and the fiber mesh which is flatly embedded in the center of the concrete panel. The specimen for the fiber mesh pull-out test selects a pull-out test fiber from the fiber mesh by sawing the concrete panel.

Description

Concrete panel specimen for fiber mesh pull-out test and its manufacturing method, fiber mesh pull-out test method and fiber mesh pull-out test device {Concrete panel specimen for fiber mesh pull-out test and method for manufacturing the same, pull-out testing method for fiber mesh and pull-out tester for fiber mesh}

The present invention relates to a concrete panel test body for a fiber net drawing test and a method for manufacturing the same, a method for drawing a fiber net, and a test apparatus for drawing a fiber net.

In recent years, in accordance with the trend of not using a wire mesh as a support material for tunnels, shotcrete mixed with steel fibers is sometimes used. In the process of transporting shotcrete, there is a problem that workability deteriorates due to frequent aggregation in the transport hose due to the magnetism between the steel fibers, and shortcrete Rebounding occurs during the spraying process of the steel fiber, which causes environmental problems because the steel fibers are discharged like an amber rock.

As an initial support material for the tunnel, a wire mesh made of a polymer material can be used without using a wire mesh made of a steel material, and the fiber net reinforced shotcrete can be configured with a thin coating thickness, which is economical and eco-friendly.

When using a fiber mesh as a reinforcing material as described above, it is very important to attach it with shotcrete to secure mechanical performance. In the behavior of a fiberglass reinforced shotcrete, the tensile force expression is dominated by the adhesion stress-slip relationship between the cement matrix and the fiber mesh. .

The adhesion stress-slip relationship of conventional reinforced concrete is generally derived according to the pull-out test method shown in the standard test regulations. However, since the shape and characteristics of reinforcing bars and fiber nets are different from each other, it is not appropriate to apply the same pull-out test method applied to existing reinforced concrete to fiber-reinforced shotcrete.

In the case of a pull-out test on reinforced concrete, since the reinforcing bar is an isotropic material, the specimen is not damaged even when the test is carried out by directly holding the reinforcing bar to the test device. It has a relatively weak characteristic to the force pulling in the direction. Due to these characteristics, when the fiber mesh is directly caught, there is a high possibility of breaking of the fiber at the joint.

Therefore, it is judged that the conventional pull-out test for reinforced concrete is not suitable for fiberglass reinforced shotcrete, and a pull-out test method suitable for fiber netting is required.

Korean Patent Publication No. 10-2018-0102757 (published on September 18, 2018)

The present invention is intended to accurately measure the pull-out test of a fiber net that is embedded as a reinforcing material in shotcrete or concrete, a concrete panel test specimen for a fiber net pull-out test suitable for the pull-out test of a fiber net and a manufacturing method thereof, a pull-out test method of a fiber net and It is intended to provide a pull-out test apparatus for a fiber mesh.

According to an aspect of the present invention, as a test body for performing a pull-out test of a fiber mesh made of a polymer fiber comprising a warp (經 絲) and a weft (緯 絲) disposed in the transverse direction with respect to the warp, rectangular shape A concrete panel; Provided is a concrete panel test body for a fiber mesh pull-out test, comprising a fiber mesh that is flatly embedded in the center of the concrete panel, and selecting the pull-out test fiber from the fiber mesh by sawing the concrete panel.

The polymer fiber may include any one or more of polyester fiber, aramid fiber, and carbon fiber.

The inclination is greater than that of the weft yarn, the concrete panel has a rectangular shape, and the fiber mesh may be buried so that the inclination of the fiber mesh is arranged in the long side direction of the concrete panel.

Saw in the width direction of the concrete panel at both side ends of the concrete panel so that the test slope located at the center of the width of the concrete panel is selected, and the concrete panel in the width direction of the concrete panel so that the buried length of the test slope is determined Can shoot the central part of the. And, it can be sawed in the longitudinal direction of the concrete panel so that the test weft located within the buried length of the test slope is selected.

A holding portion having a stepped jaw may be formed at each of both ends of the concrete panel.

According to another aspect of the present invention, a concrete panel for a fiber mesh pull-out test for performing a pull-out test of a fiber mesh made of a polymer fiber comprising a warp and a weft arranged in a transverse direction with respect to the warp A method for manufacturing a test body, comprising: preparing a formwork corresponding to the concrete panel test body; A step in which the fiber mesh having a width corresponding to the width of the concrete panel test body and longer than the length of the concrete panel test body is laid flat in the center of the formwork; Pulling both ends of the fiber mesh to fix the fiber mesh to the formwork; Pouring and curing unconsolidated concrete inside the formwork; Provided is a method for producing a concrete panel test body for a fiber net drawing test, comprising the step of demolding the formwork.

The formwork has a bottom plate, a height corresponding to half the thickness of the concrete panel test body, and a pair of lower short-side members disposed opposite to each other on the bottom plate, and a height corresponding to the overall thickness of the concrete panel test body. It includes a formwork body including a pair of long side members disposed opposite to each other on the bottom plate to form a rectangle with the lower short side member, and a pair of upper short side members respectively coupled to the upper side of the lower short side member. In this case, the step of fixing the fiber mesh may include fixing the upper short side members to the lower short side members by pulling both ends of the fiber mesh.

The inclination has a greater rigidity than the weft yarn, the formwork has a rectangular shape, and the fiber mesh can be seated so that the inclination of the fiber mesh is arranged in the long side direction of the formwork.

In the concrete panel test body, a holding part having a stepped surface may be formed, and in this case, the formwork may be manufactured corresponding to the concrete panel test body having the holding part.

According to another aspect of the present invention, as a pull-out test method of a fiber mesh made of a polymer fiber comprising a warp (되는) and a weft (緯 絲) disposed transverse to the warp, the fiber mesh is in the center Preparing a concrete panel test body for testing a fiber net drawing to be flatly embedded; Selecting a pull-out test fiber from the fiber mesh by sawing the concrete panel test body; A method for drawing a fiber mesh is provided, comprising stretching both ends of the concrete panel test body to measure the pulling force of the fiber mesh.

The inclination is greater rigidity than the weft yarn, the concrete panel test body has a rectangular shape, and the fiber mesh network is embedded so that the inclination of the fiber mesh network is arranged in the long side direction of the concrete panel test body, in this case, among the fiber mesh networks. The step of selecting a pull-out test fiber includes: sawing in the width direction of the concrete panel test body at both side ends of the concrete panel test body such that a test slope located at the center of the width of the concrete panel test body is selected; It may include the step of sawing the center of the concrete panel test body in the width direction of the concrete panel test body so that the buried length of the test slope is determined.

And, it may further include the step of sawing in the longitudinal direction of the concrete panel test body so that the test weft located within the buried length of the test slope is selected.

According to another aspect of the present invention, the fiber mesh network consisting of polymer fibers including warp (經 絲) and wefts (緯 絲) disposed in the transverse direction to the warp is flatly embedded in the center of the fiber mesh drawing test concrete A pair of clamps for clamping both ends of the panel specimen; A pair of fixing portions each extending outwardly to one end of the clamp and connected to the tensioning device; A pull-out test apparatus for a fiber net is provided, comprising a displacement meter connected between the pair of clamps and measuring a separation distance between the pair of clamps.

One of the pair of fixing parts is fixed to the fixed end of the tensioning device, the other of the pair of fixing parts is fixed to the movable end of the tensioning device, and the movable end has a load cell for measuring the tensile force. It may be provided.

The clamp, the lower plate; An upper plate spaced apart from the upper portion of the lower plate so that an end portion of the concrete panel test body is interposed; A pressure plate positioned at a lower portion of the upper plate to press the upper end of the concrete panel test body; It may include a pressing bolt screwed to the upper plate to press the pressing plate through the upper plate.

Unevenness may be formed on the upper surface of the lower plate and the lower surface of the pressing plate.

According to an embodiment of the present invention, it is possible to accurately measure the pull-out test of a fiber net that is embedded as a reinforcing material in shotcrete or concrete.

1 is a perspective view of a concrete panel test body for fiber net drawing test according to an embodiment of the present invention.
Figure 2 is a plan view of a concrete panel test body for fiber net drawing test according to an embodiment of the present invention.
Figure 3 is a side view of a concrete panel test body for fiber net drawing test according to an embodiment of the present invention.
4 and 5 are views for explaining a sawing method of a concrete panel test body for a fiber net drawing test according to an embodiment of the present invention.
Figure 6 is a modified example of the concrete panel test body for fiber net drawing test according to an embodiment of the present invention.
Figure 7 is a flow diagram of a method for producing a concrete panel test body for fiber net drawing test according to an embodiment of the present invention.
8 is an exploded perspective view of a formwork for manufacturing a concrete panel test body for a fiber net drawing test according to an embodiment of the present invention.
Figure 9 is a flow chart of a method for testing the pulling of a fiber net according to another embodiment of the present invention.
10 is a perspective view of a pultrusion test body used in a method for pultrusion test of a fiber net according to another embodiment of the present invention.
11 is a view for explaining a pull-out test apparatus used in a pull-out test method of a fiber net according to another embodiment of the present invention.

The present invention can be applied to various transformations and may have various embodiments, and specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all conversions, equivalents, and substitutes included in the spirit and scope of the present invention. In the description of the present invention, when it is determined that detailed descriptions of related well-known technologies may obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

Hereinafter, an embodiment of a concrete panel test body for fiber mesh drawing test and its manufacturing method, a fiber mesh drawing method and a fiber mesh drawing apparatus will be described in detail with reference to the accompanying drawings, and refer to the accompanying drawings. In the following description, the same or corresponding components are assigned the same reference numbers, and redundant descriptions thereof will be omitted.

1 is a perspective view of a concrete panel test body for a fiber mesh drawing test according to an embodiment of the present invention, Figure 2 is a plan view of a concrete panel test body for a fiber mesh drawing test according to an embodiment of the present invention, Figure 3 is the present invention It is a side view of a concrete panel test body for a fiber net drawing test according to an embodiment. And, Figures 4 and 5 is a view for explaining a sawing method of a concrete panel test body for fiber net drawing test according to an embodiment of the present invention. And, Figure 6 is a modified example of a concrete panel test body for fiber net drawing test according to an embodiment of the present invention.

1 to 6, the concrete panel test body 10 for the fiber mesh drawing test, the concrete panel 12, the fiber mesh 14, the inclined 16, the weft yarn 18, the sawing line 20, The test slope 22, the test weft 24, the holding portion 26, and the pressing bolt 27 are shown.

Concrete panel test specimen 10 for fiber net drawing test according to the present embodiment, a polymer fiber comprising a weft (經 絲) (18) disposed in the transverse direction with respect to the inclined (16) and inclined (16) As a test body for performing a pull-out test of the fiber mesh (14) made of a rectangular concrete panel (12); It includes a fiber mesh 14 that is flatly embedded in the central portion of the concrete panel 12, and the pulling test fibers 22 and 24 can be selected from among the fiber mesh 14 by sawing the concrete panel 12. .

The fiber net 14 is a fiber net 14 that is embedded in concrete or shotcrete to reinforce the structure, and wefts made of polymer fibers arranged transverse to the warp 16 made of polymer fibers and warp 16 ( 18) to form a lattice mesh. An epoxy or urethane coating film may be coated on the surface of the fiber mesh 14.

The concrete panel 12 may be manufactured by mixing in the same manner as an actual concrete structure in which the fibrous mesh 14 is embedded as a reinforcing material in a rectangular shape. For example, when spraying and pouring shotcrete on the fiber mesh 14 as a tunnel support material, the concrete panel 12 can be produced with the same formulation, and when the fiber mesh 14 is used as a reinforcing material in the concrete structure, it is the same as the concrete structure. The concrete panel 12 can be produced by mixing.

The concrete panel 12 is manufactured in the form of a substantially rectangular flat plate having a thin thickness to allow sawing along the sawing line 20 (sawing line) by a concrete cutting saw.

In this embodiment, the concrete panel 12 is produced in a long rectangular shape in one direction, and the tensile force can be easily applied to the inclined 16 by arranging the inclined 16 of the fiber mesh 14 in the long direction. In this case, the inclination 16 of the fiber mesh 14 may have a stiffness greater than that of the weft yarn 18, and a draw test may be performed on the inclination 16 having a greater stiffness.

The fiber mesh 14 is disposed flatly embedded in the center of the concrete panel 12. 1 to 3, it can be seen that the grid-shaped fiber mesh 14 is flatly embedded in the center of the concrete panel 12.

In this embodiment, the fiber in the form of an epoxy or urethane coating film coated on a grid mesh including a warp (16) made of polyester yarn and a weft (18) made of polyester yarn disposed transversely to the warp (16) The mesh 14 is presented.

The polymer fibers constituting the fiber mesh 14 may be made of polyester fiber, glass fiber, aramid fiber, carbon fiber, etc., and combined with concrete or shotcrete on the surface. For enhancement, an epoxy or urethane coating film is coated.

The fiber mesh 14 as described above is flatly embedded in the center of the concrete panel 12, and test fibers 22 and 24 can be selected by sawing the concrete panel 12 by a concrete cutting saw or the like.

It can be assumed that a part of the fiber is embedded in concrete for the pull-out test on the fiber, and the pull-out test is performed by pulling the fiber, but in this case, the fiber is damaged by pulling the fiber directly, and the fiber may break before being pulled. I have a concern.

In this embodiment, the pull-out test is performed without damaging the fiber net 14 by pulling the concrete panel test specimen 10 covering the fiber net 14 at both ends without directly pulling the fibers of the fiber net 14. It can be done.

4 and 5 show a sawing method of a concrete panel test body 10 for a fiber net drawing test according to this embodiment.

In the case of Figure 4, the form of the sawing the concrete panel 12 for the pull-out test of the test slope 22 located in the center of the concrete panel 12, first, the test located in the center of the width of the concrete panel 12 Saw along the sawing line 20 in the width direction of the concrete panel 12 at both ends of the concrete panel 12 so that the slope 22 is selected, and the concrete panel 12 so that the buried length of the test slope 22 is determined ) In the width direction of the concrete panel 12 sowing along the sawing line 20. In this state, by applying a tensile force to both ends of the concrete panel 12, it is possible to perform a pull test on the test slope 22 located in the center.

In the case of Figure 5, for the drawing test to the test weft (22) and the test weft (24) connected to the test slope 22 located in the center of the concrete panel 12, first, located in the center of the width of the concrete panel (12) Sowing in the width direction of the concrete panel 12 at both ends of the concrete panel 12 so that the test slope 22 is selected, the concrete in the width direction of the concrete panel 12 so that the buried length of the test slope 22 is determined After sawing the central portion of the panel 12, the sawing along the sawing line 20 again in the longitudinal direction of the concrete panel 12 so that the test weft 24 located within the buried length of the test slope 22 is selected to be. In this state, when a tensile force is applied at both ends of the concrete panel 12, a pull test may be performed on the test slope 22 located in the central portion and the test weft 24 connected thereto.

6 shows a modified example of the concrete panel test body 10 for a fiber net drawing test according to this embodiment.

In order to easily clamp both ends of the tensile device during the pull-out test of the fiber panel pull-out test concrete panel test body 10, by forming a holding portion 26 with a stepped at each end of the concrete panel 12, It is a form that is made so that the pressing bolt 27 of the tensioning device is supported on the stepped jaw to apply uniform tensile force at both ends of the concrete panel 12.

7 is a flow chart of a method for manufacturing a concrete panel test body for a fiber net drawing test according to an embodiment of the present invention, and FIG. 8 is an exploded perspective view of a formwork for manufacturing a concrete panel test body for a fiber net drawing test according to an embodiment of the present invention .

8, the formwork 28, the formwork body 30, the bottom plate 32, the lower short side member 34, the long side member 36, the upper short side member 38 is shown.

In this embodiment, the fiber 16 for drawing the fiber mesh for performing the drawing test of the fiber mesh 14 made of polymer fibers comprising the warp 16 and the weft yarns 18 transversely arranged with respect to the warp 16 A method for manufacturing a panel test body, comprising: preparing a formwork 28 corresponding to a concrete panel test body 10; A step of flatly seating a fiber net 14 having a width corresponding to the width of the concrete panel test body 10 and longer than the length of the concrete panel test body 10 in the center of the formwork 28; Pulling both ends of the fiber mesh (14) to fix the fiber mesh (14) to the formwork (28); Pouring and curing unconsolidated concrete inside the formwork 28; And demoulding the formwork 28.

This embodiment relates to a method of manufacturing the above-described concrete panel test body 10 for the fiber mesh pull-out test, while manufacturing the concrete panel test body 10 while flatly seating the fiber mesh net 14 in the center of the concrete panel test body 10 shall.

Accordingly, first, the formwork 28 corresponding to the concrete panel test body 10 to be prepared is prepared (S100). Since the concrete panel test body 10 to be manufactured is a rectangular panel shape, the formwork 28 has a certain thickness and can be manufactured in a rectangular box shape with an open top surface.

In this embodiment, as shown in Figure 8, the bottom plate 32 and the pair of concrete panels having a height corresponding to half the thickness of the test body 10 and disposed to face each other on the bottom plate 32 A pair of long sides having a height corresponding to the entire thickness of the lower short side member 34 and the concrete panel test body 10 and being arranged opposite to each other on the bottom plate 32 to form a rectangle with the lower short side member 34. A formwork body (30) comprising a member (36) and a formwork (28) comprising a pair of upper short-side members (38) respectively coupled to the upper side of the lower short-side member (34) are presented.

In order to facilitate the demolding of the formwork 28, the fixing of the long side member 36 and the lower short side member 34 to the bottom plate 32 can be detachably coupled by fastening means such as bolts and screws.

Next, a fiber mesh 14 having a width corresponding to the width of the concrete panel test body 10 to be produced and longer than the length of the concrete panel test body 10 is placed flatly in the center of the formwork 28 (S200). . Since the fiber mesh 14 is buried in the interior of the concrete panel test body 10 and must be pulled tightly and embedded in the center of the concrete panel test body 10, the width corresponding to the width of the concrete panel test body 10 to be manufactured is Prepare a fiber mesh 14 that is longer than the length of the concrete panel test body 10 to be produced. In such a state that the fiber mesh 14 is arranged in the center of the thickness direction of the formwork 28, both ends are fixed in the center of the formwork 28 by pulling both ends in the longitudinal direction of the fiber mesh network 14. Since the length of the fiber mesh 14 is longer than the length of the formwork 28, it can be fixed to the center of the formwork 28 in a state where the fiber mesh 14 is pulled in the longitudinal direction.

In the case of using the formwork 28 presented in this embodiment, the upper short side member in a state in which the fiber meshes 14 are arranged in the longitudinal direction of the formwork body 30 and both ends of the fiber meshes 14 are pulled in the longitudinal direction (38) is fixed to the upper portion of the lower short side member (34), respectively, and fixed flat in the center of the formwork (28) while the fiber mesh (14) is pulled.

In this embodiment, the formwork 28 is produced in a long rectangular shape in one direction, and the fiber mesh netting 14 is arranged so that the inclination 16 of the fiber mesh netting 14 faces the longitudinal direction of the formwork 28 After the production of the concrete panel test body 10 for the pull-out test, it was manufactured to enable the pull-out test in the direction of the inclination 16 of the fiber mesh 14. In this case, the inclination 16 of the fiber mesh 14 is greater in stiffness than the weft yarn 18, and a pultrusion test is performed on the inclination 16 in greater stiffness.

Next, the concrete that is not hardened is poured into the formwork 28 and cured (S300). The mixing ratio of the non-hardening concrete may be the same or similar to the mixing ratio of the actual concrete structure as described above. Concrete panel test specimens can be produced according to standard wet curing.

Next, the mold 28 is demolded (S400). When the concrete has a certain strength through the curing period of the concrete, the formwork 28 is demolded to produce a concrete panel test body 10 for fiber net drawing test.

In the case of using the formwork 28 presented in the present embodiment, the fastening means that secure the long side member 36, the lower long side member 36, and the upper long side member 36 are released and released.

On the other hand, in the case of manufacturing the concrete panel test body 10 for a fiber net drawing test according to the above-described modification, corresponding to be formed so that a holding portion 26 having a stepped on each of both ends of the concrete panel test body 10 to be produced By doing so, the formwork 28 can be produced.

9 is a flow chart of a method for testing a fiber mesh drawing according to another embodiment of the present invention.

 The pull-out test method of the fiber net according to the present embodiment is a pull-out test method of a fiber net 14 made of a polymer fiber including wefts 18 arranged in a transverse direction with respect to the warp 16 and the warp 16. , Preparing a concrete panel test body 10 for a fiber net drawing test in which the fiber net 14 is flatly embedded in the central portion; Selecting a pull-out test fiber among the fiber meshes 14 by sawing the concrete panel test body 10; And stretching both ends of the concrete panel test body 10 to measure the pulling force of the fiber mesh 14.

Concrete panel test specimen for fiber mesh drawing test in which the fiber mesh 14 made of polymer fibers including the above-mentioned warp yarns 16 and the weft yarns 18 disposed in the transverse direction is flatly embedded in the center portion ( 10), a test fiber may be selected from among the fiber meshes 14 to conduct a pull-out test.

First, a concrete panel test body 10 for a fiber mesh drawing test in which the fiber mesh 14 is flatly embedded in the center is prepared (S1000). In this embodiment, the concrete panel test body 10 is produced in a long rectangular shape in one direction, and the tensile force is applied to the slope 16 by arranging the inclination 16 of the fiber mesh 14 in the long direction of the concrete panel test body 10. It was made easy to apply. In this case, the inclination 16 of the fiber mesh 14 is greater in stiffness than the weft yarn 18, and a pull test is performed on the inclination 16 in which the rigidity is greater.

Since the concrete panel test body 10 for the fiber net drawing test in which the fiber net 14 is flatly embedded in the center is as described above, a detailed description is omitted.

Next, the concrete panel test body 10 is sawed to select a pull-out test fiber among the fiber meshes 14 (S2000). The concrete panel test body 10 for the fiber mesh pull-out test used in this embodiment selects the test fiber to be tested by sawing a part of the concrete panel test body 10 with a concrete cutting saw or the like.

That is, FIGS. 4 and 5 show the sawing method of the concrete panel test body 10 for fiber net drawing test. Referring to FIGS. 4 and 5, in the case of FIG. 4, the concrete panel is located at the center of the test body 10 As a form of sawing the concrete panel test body 10 for the pull-out test of the test slope 22, first, the concrete panel test body 10 so that the test slope 22 located in the center of the width of the concrete panel test body 10 is selected ) In both widths of the concrete panel test body 10, and the center portion of the concrete panel test body 10 in the width direction of the concrete panel test body 10 so that the buried length of the test slope 22 is determined. . In this state, by applying a tensile force to both ends of the concrete panel test body 10, it is possible to perform a pull test on the test slope 22 located in the center.

In the case of Figure 5, for the drawing test to the test weft (22) and the test weft (24) connected to the test slope 22 located at the center of the concrete panel test body 10, first, in the center of the width of the concrete panel test body (10) Concrete panel test body 10 so as to be positioned in the width direction of the concrete panel test body 10 at both ends of the concrete panel test body 10 so that the test slope 22 located is selected, and the buried length of the test slope 22 is determined After ssoing the central portion of the concrete panel test body 10 in the width direction of the, the form of the saw again in the longitudinal direction of the concrete panel test body 10 so that the test weft (24) located within the buried length of the test slope 22 is selected to be. In this state, when a tensile force is applied at both ends of the concrete panel test body 10, a pull test may be performed on the test slope 22 located in the central portion and the test weft 24 connected thereto.

Next, by pulling both ends of the concrete panel test body 10 to measure the pulling force of the fiber mesh (14) (S3000). As described above, when the selection of test fibers to perform a pull-out test by sawing the concrete panel test body 10 is made, the both ends of the concrete panel test body 10 are tensioned to measure the pulling force of the fiber mesh 14.

A separate tensioning device is required for tensioning the concrete panel test body 10, and the tensioning device is equipped with a load cell 54 for measuring the tensile force and a displacement meter 44 for measuring displacement during drawing of the test fiber. The pull force of the test fiber can be measured.

10 is a perspective view of a drawing test body used in a method for drawing a fiber mesh according to another embodiment of the present invention, and FIG. 11 is a drawing method used in a drawing method for drawing a fiber mesh 14 according to another embodiment of the present invention It is a figure for explaining a test apparatus.

10 and 11, the concrete panel test body 10 for the fiber net drawing test, the pressing bolt 27, the clamp 40, the fixing part 42, the displacement gauge 44, the lower plate 46, the upper plate 48 ), The pressure plate 50, the unevenness 52, the load cell 54, the movable end 56, the fixed end 58, the actuator 60 is shown.

In the pull-out test apparatus for a fiber net according to the present embodiment, the fiber net 14 made of polymer fibers including warp 16 and wefts 18 disposed in the transverse direction with respect to the warp 16 is flat in the center portion A pair of clamps 40 for clamping both ends of the concrete panel test body 10 for testing a fiber net drawing to be buried, respectively; A pair of fixing parts 42 respectively extending outwardly at one end of the clamp 40 and connected to the tensioning device; And a displacement gauge 44 connected between the pair of clamps 40 to measure the separation distance between the pair of clamps 40.

The clamps 40 are for clamping both ends of the plate-shaped concrete panel test body 10, respectively, and are paired. Clamp 40 according to this embodiment, the lower plate 46 and; An upper plate 48 spaced apart from the upper portion of the lower plate 46 so that an end portion of the concrete panel test body 10 is interposed; A pressure plate 50 positioned at a lower portion of the upper plate 48 to press the upper end of the concrete panel test body 10; Clamping the end of the plate-shaped concrete panel test body 10 by pressing force, including a pressing bolt 27 screwed to the upper plate 48 to press the pressing plate 50 through the upper plate 48 It is configured to.

The lower plate 46 and the upper plate 48 are spaced apart from each other by a predetermined distance, and a pressure plate 50 is disposed therebetween. While the end of the concrete panel test body 10 is interposed between the lower plate 46 and the press plate 50, the press plate 50 presses the end of the concrete panel test body 10, and the press plate 50 and the bottom The plate 46 clamps the end of the concrete panel test body 10. In order to apply a pressing force to the pressing plate 50, the pressing bolt 27 is screwed through the upper plate 48, and according to the screwing of the pressing bolt 27, the pressing bolt 27 is pressurized plate 50 Will press the top of.

In order to prevent the concrete panel test body 10 from slipping in the clamp 40 during the drawing test, the unevenness 52 may be formed on the upper surface of the lower plate 46 and the lower surface of the pressure plate 50.

The fixing part 42 extends outwardly at one end of the clamp 40 and is connected to the tensioning device. The fixing part 42 is a part connecting the clamp 40 clamping the end of the concrete panel test body 10 to the tensioning device, and the concrete panel test body 10 is mounted to the tensioning device via the fixing part 42.

One of the pair of fixing parts 42 is fixed to the fixed end 58 of the tensioning device, and the other of the pair of fixing parts 42 is fixed to the movable end 56 of the tensioning device, and the movable end ( In accordance with the linear movement of 56), the tensile force is applied by pulling both ends of the concrete panel test body 10. In order to measure the tensile force applied to the concrete panel test body 10, the movable end 56 is provided with a load cell 54 for measuring the tensile force.

Referring to Figure 11, the end of the movable end 56 may be coupled to the actuator 60 for applying a tensile force to the concrete panel test body 10, the movable end 56 according to the operation of the actuator 60 While moving in a straight line, a tensile force is applied to the concrete panel test body 10.

The displacement meter 44 is connected between the pair of clamps 40 and measures the separation distance between the pair of clamps 40. In the process of applying a tensile force to the concrete panel test body 10, the displacement of the concrete panel can be measured by measuring the separation distance of the pair of clamps 40.

Although the embodiments of the present invention have been described above, the spirit of the present invention is not limited to the embodiments presented herein, and those skilled in the art to understand the spirit of the present invention may add elements within the scope of the same spirit. However, other embodiments may be easily proposed by changing, deleting, adding, or the like, but this will also be considered to be within the scope of the present invention.

10: Concrete panel test specimen for fiber net drawing test
12: concrete panel 14: fiber mesh
16: slope 18: weft
20: sawing line 22: test slope
24; Test weft 26: holding department
27: pressure bolt 28: formwork
30: formwork body 32: bottom plate
34: lower short side member 36: long side member
38: upper short side member 40: clamp
42: fixing part 44: displacement meter
46: lower plate 48: upper plate
50: pressure plate 52: irregularities
54: load cell 56: movable stage
58: fixed end 60: actuator

Claims (17)

As a test body for performing a pull-out test of a fiber net consisting of a polymer fiber comprising a warp (위) and weft (되는) disposed in the transverse direction to the warp,
A rectangular-shaped concrete panel;
It includes a fiber mesh that is flatly embedded in the center of the concrete panel,
A concrete panel test body for pulling out a fiber net, which is to select the pullout test fiber among the fiber netting by sawing the concrete panel.
According to claim 1,
The polymer fiber,
Characterized in that it comprises at least one of a polyester fiber, aramid fiber, carbon fiber, a concrete panel test body for fiber net drawing test.
According to claim 1,
The inclination is more rigid than the weft yarn,
The concrete panel has a rectangular shape,
The fiber mesh net is characterized in that the fiber mesh is buried so that the inclination of the fiber mesh is disposed in the long side direction of the concrete panel, a concrete panel test specimen for fiber mesh drawing.
According to claim 3,
Saw in the width direction of the concrete panel at both ends of the concrete panel so that the test slope located in the center of the width of the concrete panel is selected,
Characterized in that the center portion of the concrete panel in the width direction of the concrete panel so that the buried length of the test slope is determined, a concrete panel test specimen for fiber net drawing.
The method of claim 4,
The test panel located in the length of the buried test slope, characterized in that the sowing in the longitudinal direction of the concrete panel, so that the test panel for a fiber net drawing.
According to claim 1,
Each of both ends of the concrete panel is characterized in that a holding portion having a step is formed, a concrete panel test body for fiber net drawing test.
As a method for manufacturing a concrete panel test body for a fiber mesh drawing test for performing a drawing test of a fiber mesh made of polymer fibers comprising warp yarns and wefts arranged transversely to the warp,
Preparing a formwork corresponding to the concrete panel test body;
A step in which the fiber mesh having a width corresponding to the width of the concrete panel test body and longer than the length of the concrete panel test body is laid flat in the center of the formwork;
Pulling both ends of the fiber mesh to fix the fiber mesh to the formwork;
Pouring and curing unconsolidated concrete inside the formwork;
The method comprising the step of demolding the form, a method for producing a concrete panel test body for fiber net drawing test.
The method of claim 7,
The formwork,
The bottom plate has a height corresponding to half the thickness of the concrete panel test body and a pair of lower short-side members disposed opposite to each other on the bottom plate, and a height corresponding to the overall thickness of the concrete panel test body, and A formwork body including a pair of long side members disposed opposite to each other on the bottom plate to form a rectangle together with the lower short side member, and a pair of upper short side members respectively coupled to the upper side of the lower short side member,
The step of fixing the fiber mesh,
And pulling the both ends of the fiber net to fix the upper short side members to the lower short side members, respectively.
The method of claim 7,
The inclination is more rigid than the weft yarn,
The formwork has a rectangular shape,
The fiber mesh screen is characterized in that the fiber mesh is seated so that the inclination of the fiber mesh is disposed in the direction of the long side of the formwork, a method for producing a concrete panel test specimen for fiber mesh drawing.
The method of claim 7,
A holding portion having a stepped jaw is formed on the concrete panel test body,
The formwork
Characterized in that it is produced in correspondence with the concrete panel test body having the holding portion, a method for producing a concrete panel test body for fiber net drawing test.
As a pull-out test method of a fiber mesh consisting of a polymer fiber comprising a warp (위) and a weft (緯 絲) disposed in the transverse direction to the warp,
Preparing a concrete panel test body for a fiber mesh drawing test in which the fiber mesh is flatly embedded in a central portion;
Selecting a pull-out test fiber from the fiber mesh by sawing the concrete panel test body;
And stretching both ends of the concrete panel test body to measure the pull force of the fiber mesh.
The method of claim 11,
The inclination is more rigid than the weft yarn,
The concrete panel test body has a rectangular shape, and the fiber mesh network is embedded so that the inclination of the fiber mesh network is arranged in the long side direction of the concrete panel test body,
The step of selecting a pull-out test fiber among the fiber nets,
Sawing in the width direction of the concrete panel test body at both sides of the concrete panel test body so that a test slope located at the center of the width of the concrete panel test body is selected;
And sawing the central portion of the concrete panel test body in the width direction of the concrete panel test body so that the buried length of the test slope is determined.
The method of claim 12,
And characterized in that it further comprises the step of sawing in the longitudinal direction of the concrete panel test body so that the test weft located in the buried length of the test slope, the method for drawing a fiber mesh.
As long as the fiber meshes made of polymer fibers including warp yarns and weft yarns arranged transversely to the warp are clamped at both ends of the concrete panel test specimen for fiber mesh drawing test, which is flatly embedded in the center. A pair of clamps;
A pair of fixing portions each extending outwardly to one end of the clamp and connected to the tensioning device;
And a displacement meter connected between the pair of clamps and measuring a separation distance between the pair of clamps.
The method of claim 14,
One of the pair of fixing parts is fixed to the fixing end of the tensioning device,
The other of the pair of fixing parts is fixed to the movable end of the tensioning device,
Characterized in that the movable end is provided with a load cell for measuring the tensile force, a pull-out test apparatus for a fiber net.
The method of claim 14,
The clamp,
A lower plate;
An upper plate spaced apart from the upper portion of the lower plate so that an end portion of the concrete panel test body is interposed;
A pressure plate positioned at a lower portion of the upper plate to press the upper end of the concrete panel test body; And a pressing bolt screwed to the upper plate to penetrate the upper plate and pressurize the pressing plate.
The method of claim 16,
Unevenness is formed on the upper surface of the lower plate and the lower surface of the pressure plate, a pull-out test apparatus for a fiber net.

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