KR100926317B1 - Pullout angle setting apparatus for pullout testing of underground structure - Google Patents

Abstract

The present invention relates to a drawing angle setting device for the drawing experiment of the structure embedded in the ground, in particular formed in a rectangular box shape to accommodate the soil of the target analysis ground, the upper surface is open, made of a transparent material that can be observed inside A test tank having a structure embedded therein; A traction motor installed at one side of an open upper portion of the test tank and pulling one end of a wire connected to one end of the structure; An angle main control unit installed at the other side of the open upper portion of the test tank and having a jaw formed in multiple stages; An angle auxiliary controller for changing an angle between the structure and the wire by the height of the jaw of the angle main controller; And a load cell installed on the wire to measure a load applied thereto.

According to the present invention as described above it is possible to increase the reproducibility of the test in a quantitative repetitive test by enabling to measure the pull bearing capacity of the structure at various angles at various locations of the structure, the inconvenience of setting the angle manually through a lot of time It is possible to solve the problem, to enable quantitative repetitive experiments, and to secure the reliability of the experiments, so that the mechanical properties of the structure can be accurately reproduced in the ground that is close to the actual ground.

 Soil, structural test, anchor, pipe, drawing angle, setting

Description

Pulling angle setting device for drawing experiment of buried structure {PULLOUT ANGLE SETTING APPARATUS FOR PULLOUT TESTING OF UNDERGROUND STRUCTURE}

The present invention relates to a drawing angle setting device for the drawing experiment of the structure buried in the ground, and in detail, it is possible to set the drawing angle of the structure in order to measure the bearing capacity of the structure buried in the ground (eg pile or anchor) It relates to a drawing angle setting device.

Structures (such as piles and anchors) are usually buried in the ground, and there are significant difficulties when trying to test the bearing capacity of such structures. That is, there is a problem in that it takes a considerable cost and time to test the measurement of the bearing capacity for the drawing of the anchor of the actual structure.

On the other hand, the anchor buried in the ground acts on the drawing force from a variety of angles, there has been a demand for the development of a test apparatus that can measure the bearing capacity for the drawing by implementing the draw force of various angles acting on the anchor of the actual structure.

In response to these demands, the present applicant has applied for an anchor pull bearing force test apparatus (public patent 10-2007-0099281) that can test the pull bearing force of the anchor while varying the angle of the pull force acting on the anchor embedded in the ground. It was.

As shown in Figure 1, the anchor pull bearing capacity test apparatus 100 is open at the top and the housing 10, the anchor (2) is built therein, is installed on the top of the housing 10 to the anchor (2) The driving unit 20 pulling the rope 4 to be connected, and the rope 4 connecting the driving unit 20 and the anchor 2 pass through and are installed to face the driving unit 20 in the housing 10. An angle adjusting unit 40 for changing an angle formed between the other end of the rope 4 connected to the anchor 2 and the ground (not shown), and a load cell for measuring the load applied to the rope 4 ( 60).

The housing 10 is provided with various components to be described later, the upper portion is opened so that the anchor (2) can be embedded therein.

Inside the housing 10 is an anchor 2 for testing the pull bearing force.

The anchor 2 to be tested is buried by the soil 6 in the housing 10, and if necessary, water 8 is placed on the upper portion of the soil 6 to create an environment similar to the place where the actual anchor is located. To improve the accuracy of the test results. The rope 4 is connected to one side of the anchor 2, and the rope 4 is connected to one end thereof to the driving unit 20 via the angle adjusting unit 40.

The drive unit 20 is installed on one side of the open upper portion of the housing 10 to pull one end of the rope 4. The driving unit 20 includes a base 22 fixed to an open upper side of the housing 10, a motor 24 installed on the base 22, and a rotation shaft 25 of the motor 24. A gear assembly 26 connected to transmit the rotational force of the motor 24 and a rotating drum axially connected to the gear assembly 26 and rotating by the gear assembly 26 to pull one end of the rope 4. (28).

The angle adjusting unit 40 has a first pulley member 42 fixed to the other side of the open upper portion of the housing 10 so as to face the drive unit 20, and the housing so that the gap between the first pulley member 42 is adjusted. The second pulley member 52 provided along the inner wall of 10 is included. The rope 4 extending from the drive unit 20 is connected to the anchor 2 via the first and second pulley members 42, 52.

The first and second pulley members 42 and 52 constituting the angle adjusting unit 40 will be described in detail as follows. The first pulley member 42 is fixed to the other side of the open upper portion of the housing 10 so as to face the drive unit 20. The first pulley member 42 includes a frame 43 coupled to the upper portion of the housing 10 by a bolt 47, and a pulley 45 rotatably installed at one end of the frame 43. Frame 43 is fixed to the upper portion of the housing 10 by a plurality of bolts 47, preferably the assembly plate 50 is first fixed by the bolt 49 on the upper portion of the housing 10, and assembled The frame 43 is fixed to the upper portion of the plate 50. The rope 4 extending from the drive unit 20 faces the second pulley member 52 via the pulley 45 rotatably installed at one end of the frame 43. In this case, the groove 46 into which the rope 4 is inserted is formed along the circumference of the pulley 45 at the center of the pulley 45, so that the pulley when the rope 4 is pulled by the drive unit 20. It is to be fixed without moving along the width direction of (45).

The rope 4 passing through the pulley 45 of the first pulley member 42 faces the second pulley member 52. The second pulley member 52 is installed along the inner wall of the housing 10 under the first pulley member 42 so that the distance from the first pulley member 42 is adjusted. Specifically, the second pulley member 52 includes a frame 54 installed along the inner wall of the housing 10 and a pulley 55 rotatably installed at one end of the frame 54. The frame 54 is installed by being coupled to the side plate 58 fixed to the inner wall of the housing 10 by bolts 57. A plurality of fastening holes 59 are formed in the side plate 58 along a direction perpendicular to the ground, and the frame 54 is coupled to the fastening holes 59 of a suitable height by bolts 57. By changing the height of the fastening hole 59 to which the frame 4 is coupled, the angle of the rope 4 connected to the anchor 2 via the second pulley member 52 is adjusted, which will be described later in detail. Explain. The rope 4 passing through the pulley 45 of the first pulley member 42 is connected to the anchor 2 via the pulley 55 of the second pulley member 52. In this case, a groove 56 is also formed along the circumference in the center portion of the pulley 55 of the second pulley member 52 so as to be fixed without moving when the rope 4 is pulled.

However, such a conventional anchor pull bearing capacity tester has a problem in that it is not possible to measure the pull bearing force of various points of the structure because it can be drawn by changing only the draw angle after connecting the wire to a certain point of the structure.

The present invention is to solve the above problems, it is possible to increase the reproducibility of the test in a quantitative repetitive test by measuring the pull bearing capacity of the structure at various angles at various locations of the structure, and manual work through a lot of time It is possible to solve the inconvenience of setting the angle, to enable quantitative repetitive experiments, and to secure the reliability of the experiments, so that the structures built close to the actual ground can be accurately embedded in the ground to accurately reproduce the mechanical characteristics of the structure. It is to provide a drawing angle setting device for the drawing experiment of the.

Features of the present invention for achieving the above object,

A test tank formed in a rectangular box shape to receive the soil of the target analysis ground, the upper surface of which is opened, made of a transparent material that can be observed inside, and a structure embedded therein; A traction motor installed at one side of an open upper portion of the test tank and pulling one end of a wire connected to one end of the structure; An angle main control unit installed at the other side of the open upper portion of the test tank and having a jaw formed in multiple stages; An angle auxiliary controller for changing an angle between the structure and the wire by the height of the jaw of the angle main controller; And a load cell installed on the wire to measure a load applied thereto.

Here, the structure is formed with a plurality of wire connecting ring in the longitudinal direction on the outer surface.

Here, the angle main control unit is formed in a rectangular shape, the first to the third horizontal surface is formed in the step shape by the jaw, the base is formed on both sides of the coupling plate is bolted to the upper edge of the test tank; A through hole through which the angle auxiliary adjustment part is inserted and coupled to each other in a vertical direction in the first to third horizontal planes; A cutting groove formed by cutting in a downward direction from an upper surface in a longitudinal direction of the base to move the wire; A first pulley rotatably coupled to one side of the incision groove adjacent to the traction motor; And a drawing hole formed at a rear surface of the first pulley while being the bottom of the cutting groove so that the wire is directly drawn from the test tank to the first pulley.

The installation position according to the test specification angle is displayed on the first to third horizontal planes, respectively.

Here, the angle auxiliary control unit is formed in the shape of a rectangular plate, the first guide hole is formed in the center, the base panel which is installed in the upper and vertical guide rods on both sides of the first guide hole; A lifting panel formed in a rectangular plate shape, having a second guide hole formed at a position corresponding to the guide rod, and having a first screw hole formed at one side thereof to move up and down along the guide rod; It is formed in the shape of a rectangular plate, the third guide hole is formed in the longitudinal direction in the center portion, is vertically coupled at the bottom of the elevating panel, inserted through the first guide hole of the base panel to adjust the angle of elevation A panel; A support panel formed in a “a” shape and installed at a rear surface of the base panel, and having a second screw hole formed at a position corresponding to the first screw hole of the elevating panel; And a knob handle formed at one end and installed through a second screw hole of the support panel and a first screw hole of the elevating panel, and the other end of which is fixed to be axially rotated by a bearing on the base panel.

Here, the base panel further includes a second pulley installed in front of the first guide hole to guide the wire.

Here, the angle adjustment panel further includes a third pulley installed at a lower end of the third guide hole to guide the wire.

Here, the test tank divides the space by installing a partition wall in the width direction in the middle, and the traction motor, the angle main control unit and the angle auxiliary control unit are installed at positions corresponding to each other on the test tank at the same time to perform the experiment. Run

According to the drawing angle setting device for the drawing experiment of the structure embedded in the ground of the present invention constituted as described above, it is possible to measure the pull bearing capacity of the structure at various angles at various positions of the structure, The reproducibility can be improved, and the inconvenience of setting the angle manually by many times can be eliminated, the quantitative repetitive experiment can be performed, and the reliability of the experiment can be secured so that the mechanical characteristics of the structure are close to the actual ground. There is an advantage that can be reproduced accurately.

Hereinafter, a configuration of a drawing angle setting device for drawing experiments of a structure embedded in the ground according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, and may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the contents throughout the specification.

2 is a perspective view showing the configuration of the drawing angle setting device for the drawing experiment of the structure embedded in the ground according to the invention, Figure 3 is a drawing angle setting device for the drawing experiment of the structure embedded in the ground according to the present invention Figure 4 is a side cross-sectional view showing the configuration, Figure 4 is a plan view showing the configuration of the drawing angle setting device for the drawing experiment of the structure embedded in the ground according to the invention, Figure 5 is a drawing experiment of the structure embedded in the ground according to the present invention Figure 6 is a perspective view showing the configuration of the angle auxiliary control unit of the drawing angle setting device for drawing, Figure 6 is a front sectional view showing the configuration of the angle auxiliary control unit of the drawing angle setting device for drawing experiments buried in the ground according to the present invention, 7a to 7c are views showing the operation of the angle auxiliary control unit of the drawing angle setting device for drawing experiments of the structure embedded in the ground according to the present invention 8 is a side view illustrating a drawing angle setting device for drawing experiments of a structure embedded in ground according to another embodiment of the present invention, and FIG. 9 is a view of a structure embedded in ground according to another embodiment of the present invention. Front view showing a drawing angle setting device for the drawing experiment.

1 to 9, the drawing angle setting device 100 for drawing experiments of a structure embedded in the ground according to the present invention includes a test bath 110, a traction motor 120, and an angle main control unit. 130, and the angle auxiliary control unit 140 and the load cell 150.

First, the test tank 110 is formed in a rectangular box shape to accommodate the soil of the target analysis ground therein, the top is open, made of a transparent material such as transparent tempered glass or acrylic so that the inside can be observed, The structure 160 is embedded. Here, the structure 160 is formed with a plurality of wire connecting ring 161 in the longitudinal direction on the outer surface.

And, the traction motor 120 is installed on one side of the open upper portion of the test tank 110 to tow one end of the wire 170 is connected to the structure 160 and one end. At this time, since the traction motor 120 is the same as the conventional drive unit (20 in FIG. 1), its overlapping description is omitted.

In addition, the angle main control unit 130 is composed of a base 131, a through hole 133, a cutting groove 135, a first pulley 137 and the withdrawal hole 139.

The base 131 is formed in a rectangular plate shape of a metal material, and the first to third horizontal surfaces 131-2 to 131-4 are formed in a stair shape by the jaw 131-1, and the test tank ( Coupling plate 131-5 is bolted to the upper edge of the 110 is formed. Here, the installation positions according to the test specification angle are displayed on the first to third horizontal planes 131-2 to 131-4, respectively.

The through-holes 133 penetrate them vertically in the first to third horizontal planes 131-2 to 131-4, respectively, to which the angle auxiliary control unit 140 to be described below is inserted and coupled.

The cutting groove 135 is formed by cutting downward from the upper surface in the longitudinal direction of the base 131 so that the wire 170 can be moved.

The first pulley 137 is an incision groove 135 adjacent to the traction motor 120 to directly connect the wire 170 to the structure 160 and the traction motor 120 when measuring a pulling force of 90 kPa of the structure. It is coupled to one side of the rotatable.

The withdrawal hole 139 is a bottom surface of the incision groove 135 such that the wire 170 is directly drawn out from the test tank 110 to the first pulley 137 so as to measure the pulling support force of 90 kPa of the structure 160. While being formed on the rear surface of the first pulley 137.

In addition, the angle auxiliary control unit 140 is composed of a base panel 141, a lifting panel 143, an angle adjustment panel 145, a support panel 147, and a screw 149.

The base panel 141 is formed of a metal plate in the form of a rectangular plate, and has a first guide hole 141-1 formed at the center thereof. The base panel 141 has a guide rod vertically on both sides of the first guide hole 141-1. 141-3) are installed. Here, the base panel 141 further includes a second pulley 141-5 installed in front of the first guide hole 141-1 to guide the wire 170.

The elevating panel 143 is formed of a metal plate in a rectangular plate shape, and a second guide hole 143-1 is formed at a position corresponding to the guide rod 141-3, and the guide rod 141-3. The first screw hole (143-3) is formed on one side to move up and down along.

The angle control panel 145 is formed of a metal plate in a rectangular plate shape, and a third guide hole 145-1 is formed in the center in the longitudinal direction, and the first guide hole 141-1 of the base panel 141 is formed. It is inserted vertically and is coupled vertically at the bottom of the elevating panel 143 to be elevated through. Here, the angle adjustment panel 145 further includes a third pulley 145-3 installed at the lower end of the third guide hole 145-1 to guide the wire 170.

The support panel 147 is formed of a metal material in a shape of “a”, is installed at the rear surface of the base panel 141, and is formed at a position corresponding to the first screw hole 143-3 of the elevating panel 143. Two screw holes 147-1 are formed.

The screw 149 has a knob handle 149-1 formed at an upper end thereof, and a second screw hole 147-1 of the support panel 147 and a first screw hole 143-3 of the lifting panel 143. It is installed through, and the lower end is fixed to axial rotation by the bearing (149-3) on the base panel 141 and the support panel 147.

On the other hand, the load cell 150 is installed on the wire 170 so that the lifting panel 143 is located in the second guide hole 143-1 to measure the load applied thereto. Herein, when the load cell 150 pulls the wire 170 by the traction motor 120, the load cell 150 measures the load applied to the wire 170, and the structure 160 connected to the wire 170 is held by the load cell 150. When pulled out, that is, when drawn, the load is measured to measure the bearing capacity of the structure 160 to draw. Since the load cell 150 is well known in the art to which the present invention pertains, a detailed description thereof will be omitted.

On the other hand, the drawing angle setting device 100 for the drawing experiment of the structure embedded in the ground according to the present invention as shown in Figure 8 and 9 the partition wall 180 in the width direction in the middle of the test tank 110 Install and divide the space, the traction motor 120, the angle main control unit 130 and the angle auxiliary control unit 140 may be installed at a position corresponding to each other on the test tank 110 to perform the experiment at the same time. have. In this case, the structure 160, the wire 170, and the load cell 150 are also provided.

Hereinafter, with reference to the accompanying drawings, the operation of the drawing angle setting device for drawing experiments of the structure embedded in the ground according to the present invention will be described in detail.

10A to 10E are views for explaining the operation of the drawing angle setting device for the drawing experiment of the structure embedded in the ground according to the present invention.

First, the soil of the target analysis ground in the test tank 110 is accommodated at a predetermined height therein, and then the test tank 110 is leveled. At this time, the traction motor 120 is pre-installed on one side of the test tank 110.

In this state, the main angle control unit 130 is installed on the other upper surface of the test tank 110, in which the angle main control unit 130 is the angle auxiliary control unit 140 at the other end of the test tank 110. The base panel 141 is installed leaving a space where it can be installed.

Then, by connecting the wire 170 to the wire connecting ring 161 located at the bottom of the structure 160, as shown in Figure 10a to test the pull-out force for 0 ㅀ at that position as shown in Figure 10a The base panel 141 of the 140 is fixed to the other end of the test tank 110.

Then, the base 170 of the first pulley 137 of the angle main control unit 130 and the angle assist control unit 140 are connected to the traction motor 120 through the wire 170 having one end connected thereto. It is withdrawn through the second pulley (141-5) provided in the).

In this state, the wire 170 is connected to the wire connecting ring located at the bottom of the wire connecting ring 161 of the structure 160 and then the structure 160 is embedded in the ground.

When the difference between the specification angle and the installation angle occurs due to external factors, the knob handle 149-1 formed on the screw 149 of the angle auxiliary adjusting unit 140 is rotated.

Then, as the screw 149 is rotated, the elevating panel 143 is raised or lowered between the base panel 141 and the support panel 147, and thus, the angle adjusting panel 145 connected to the elevating panel 143. ) Will rise and fall.

As a result, the angle of the wire 170 is varied while the position of the third pulley 145-3 of the angle adjustment panel 145 is varied, and the experimenter sets the angle of the wire 170 to 0 °.

Then, by pulling the structure 160 connected to the wire 170 by operating the traction motor 120 to measure the pull-out force through the load cell 150.

In addition, by connecting the wire 170 to the wire connecting ring 161 located at the bottom of the structure 160, as shown in Figure 10b to test the pull-out capacity for 22.5 에서 at the corresponding position as shown in Figure 10b ) Is installed on the first horizontal surface 131-2 formed on the base 131 of the angle main control unit 130. At this time, the angle adjustment panel 145 of the angle auxiliary control unit 140 is introduced into the test tank 110 through the through hole 133 of the angle main control unit 130.

Then, the base 170 of the first pulley 137 of the angle main control unit 130 and the angle assist control unit 140 are connected to the traction motor 120 through the wire 170 having one end connected thereto. It is withdrawn through the second pulley (141-5) provided in the).

In this state, the wire 170 is connected to the wire connecting ring located at the bottom of the wire connecting ring 161 of the structure 160 and then the structure 160 is embedded in the ground.

When the difference between the specification angle and the installation angle occurs due to external factors, the knob handle 149-1 formed on the screw 149 of the angle auxiliary adjusting unit 140 is rotated.

Then, as the screw 149 is rotated, the elevating panel 143 is raised or lowered between the base panel 141 and the support panel 147, and thus, the angle adjusting panel 145 connected to the elevating panel 143. ) Will rise and fall.

As a result, the angle of the wire 170 is varied while the position of the third pulley 145-3 of the angle adjustment panel 145 is varied, and the experimenter sets the angle of the wire 170 to 22.5 ㅀ.

Then, by pulling the structure 160 connected to the wire 170 by operating the traction motor 120 to measure the pull-out force through the load cell 150.

In addition, by connecting the wire 170 to the wire connecting ring 161 located at the bottom of the structure 160, as shown in FIG. 10c, the angle auxiliary control unit 140 to test the pulling capacity for 45.0 kPa at the corresponding position. ) Is installed on the second horizontal surface 131-3 formed on the base 131 of the angle main control unit 130. At this time, the angle adjustment panel 145 of the angle auxiliary control unit 140 is introduced into the test tank 110 through the through hole 133 of the angle main control unit 130.

Then, the base 170 of the first pulley 137 of the angle main control unit 130 and the angle assist control unit 140 are connected to the traction motor 120 through the wire 170 having one end connected thereto. It is withdrawn through the second pulley (141-5) provided in the).

In this state, the wire 170 is connected to the wire connecting ring located at the bottom of the wire connecting ring 161 of the structure 160 and then the structure 160 is embedded in the ground.

When the difference between the specification angle and the installation angle occurs due to external factors, the knob handle 149-1 formed on the screw 149 of the angle auxiliary adjusting unit 140 is rotated.

Then, as the screw 149 is rotated, the elevating panel 143 is raised or lowered between the base panel 141 and the support panel 147, and thus, the angle adjusting panel 145 connected to the elevating panel 143. ) Will rise and fall.

As a result, the angle of the wire 170 is changed while the position of the third pulley 145-3 of the angle adjustment panel 145 is varied, and the experimenter sets the angle of the wire 170 to 45.0 kV.

Then, by pulling the structure 160 connected to the wire 170 by operating the traction motor 120 to measure the pull-out force through the load cell 150.

In addition, by connecting the wire 170 to the wire connecting ring 161 located at the bottom of the structure 160 as shown in Figure 10d to measure the pull bearing capacity for 65.5 kW at the corresponding position as the auxiliary angle adjusting unit 140 ) Is installed on the third horizontal surface 131-5 formed on the base 131 of the angle main control unit 130. At this time, the angle adjustment panel 145 of the angle auxiliary control unit 140 is introduced into the test tank 110 through the through hole 133 of the angle main control unit 130.

Then, the base 170 of the first pulley 137 of the angle main control unit 130 and the angle assist control unit 140 are connected to the traction motor 120 through the wire 170 having one end connected thereto. It is withdrawn through the second pulley (141-5) provided in the).

In this state, the wire 170 is connected to the wire connecting ring located at the bottom of the wire connecting ring 161 of the structure 160 and then the structure 160 is embedded in the ground.

When the difference between the specification angle and the installation angle occurs due to external factors, the knob handle 149-1 formed on the screw 149 of the angle auxiliary adjusting unit 140 is rotated.

Then, as the screw 149 is rotated, the elevating panel 143 is raised or lowered between the base panel 141 and the support panel 147, and thus, the angle adjusting panel 145 connected to the elevating panel 143. ) Will rise and fall.

As a result, the angle of the wire 170 is varied while the position of the third pulley 145-3 of the angle adjustment panel 145 is varied, and the experimenter sets the angle of the wire 170 to 65.5 ㅀ.

Then, by pulling the structure 160 connected to the wire 170 by operating the traction motor 120 to measure the pull-out force through the load cell 150.

On the other hand, by connecting the wire 170 to the wire connecting ring 161 located at the bottom of the structure 160 as shown in Figure 10e in order to test the pull bearing capacity for 90.0 kPa at that position to the traction motor 120 One end of the wire 170 is connected to the wire connecting ring located at the bottom of the wire connecting ring 161 of the structure 160 directly through the first pulley 137 and the withdrawal hole 139 of the angle main control unit 130; After connection, the structure 160 is embedded in the ground.

Then, by pulling the structure 160 connected to the wire 170 by operating the traction motor 120 to measure the pull-out force through the load cell 150.

In addition, the wire 170 is connected to the wire linking ring located at another position among the wire linking rings 161 of the structure 160 through the above process, and then pulls the structure 160 through the load cell 150. Measure

As those skilled in the art would realize, the described embodiments may be modified in various ways, all without departing from the spirit or scope of the present invention. It is to be understood, however, that the present invention is not limited to the specific forms referred to in the description, but rather includes all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. Should be.

1 is a perspective view showing a conventional anchor pull bearing capacity testing apparatus,

Figure 2 is a perspective view showing the configuration of the drawing angle setting device for drawing experiments of the structure embedded in the ground according to the present invention,

Figure 3 is a side cross-sectional view showing the configuration of the drawing angle setting device for drawing experiments of the structure embedded in the ground according to the present invention,

Figure 4 is a plan view showing the configuration of the drawing angle setting device for drawing experiments of the structure embedded in the ground according to the present invention,

Figure 5 is a perspective view showing the configuration of the angle auxiliary control unit of the drawing angle setting device for drawing experiments of the structure embedded in the ground according to the present invention,

6 is a front sectional view showing the configuration of the angle auxiliary control unit of the drawing angle setting device for drawing experiments embedded in the ground according to the present invention;

7a to 7c is a view showing the operation of the angle auxiliary control unit of the drawing angle setting device for drawing experiments of the structure embedded in the ground according to the present invention,

8 is a side view showing a drawing angle setting device for drawing experiments of the structure embedded in the ground according to another embodiment of the present invention,

9 is a front view showing a drawing angle setting device for a drawing experiment of the structure embedded in the ground according to another embodiment of the present invention,

10a to 10e is a view for explaining the operation of the drawing angle setting device for the drawing experiment of the structure embedded in the ground according to the present invention.

<Explanation of symbols on main parts of the drawings>

110: test tank 120: traction motor

130: angle main control unit 140: angle auxiliary control unit

150: load cell 160: structure

170: wire

Claims (8)

A test tank formed in a rectangular box shape to receive the soil of the target analysis ground, the upper surface of which is opened, made of a transparent material that can be observed inside, and having a structure embedded therein; A traction motor installed at one side of an open upper portion of the test tank and pulling one end of a wire connected to one end of the structure; An angle main control unit installed at the other side of the open upper portion of the test tank and having a jaw formed in multiple stages; An angle auxiliary controller for changing an angle between the structure and the wire by the height of the jaw of the angle main controller; And A draw angle setting device for drawing experiments of the structure embedded in the ground, characterized in that it comprises a load cell installed on the wire to measure the load applied thereto. The method of claim 1, The structure is, Drawing angle setting device for the drawing experiment of the structure embedded in the ground, characterized in that a plurality of wire connecting ring is formed on the outer surface in the longitudinal direction. The method of claim 1, The main angle control unit, A base having a rectangular shape, the base having first to third horizontal surfaces formed in a step shape by the jaw, and having a coupling plate bolted to the upper edge of the test tank on both sides; A through hole through which the angle auxiliary control unit is inserted and coupled to penetrate it vertically in the first to third horizontal planes; A cutting groove formed by cutting in a downward direction from an upper surface in a longitudinal direction of the base to move the wire; A first pulley rotatably coupled to one side of the incision groove adjacent to the traction motor; And Setting the draw angle for the drawing experiment of the structure embedded in the ground, characterized in that the bottom of the incision groove and the drawing hole formed in the back of the first pulley so that the wire is directly drawn out to the first pulley in the test tank Device. The method of claim 3, wherein In the first to third horizontal plane, A drawing angle setting device for drawing experiments of the structure embedded in the ground, characterized in that the installation position is displayed according to the test specification angle, respectively. The method according to claim 1 or 3, The angle auxiliary control unit, A base panel formed in a rectangular plate shape, having a first guide hole formed in a center portion thereof, and having a top surface and a guide rod vertically installed at both sides of the first guide hole; A lifting panel formed in a rectangular plate shape, having a second guide hole formed at a position corresponding to the guide rod, and having a first screw hole formed at one side thereof to move up and down along the guide rod; It is formed in the shape of a rectangular plate, the third guide hole is formed in the longitudinal direction in the center portion, is vertically coupled at the bottom of the elevating panel, inserted through the first guide hole of the base panel to adjust the angle of elevation A panel; A support panel formed in a “a” shape and installed at a rear surface of the base panel, and having a second screw hole formed at a position corresponding to the first screw hole of the elevating panel; And A knob handle is formed at one end, and is installed through a second screw hole of the support panel and a first screw hole of the elevating panel, and the other end comprises a screw fixed to be axially rotated by a bearing on the base panel. Drawing angle setting device for the drawing experiment of the structure embedded in the ground. The method of claim 5, wherein The base panel, And a second pulley installed at the front of the first guide hole to guide the wire. The method of claim 5, wherein The angle adjustment panel, A drawing angle setting device for drawing experiments of the structure embedded in the ground, characterized in that it further comprises a third pulley installed in the lower portion of the third guide hole to guide the wire. The method of claim 1, The test bath, Dividing the space by installing the partition wall in the width direction in the middle, the ground, characterized in that the traction motor, the angle main control unit and the angle auxiliary control unit to be installed in a position corresponding to each other on the test tank to run the experiment at the same time Drawing angle setting device for drawing experiments embedded in the structure.

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