KR20100100245A - Low-soil disturbance screw plate loading test device - Google Patents

Abstract

PURPOSE: A screw loading test device is provided to minimize the disturbance of the ground and to be used on land and water by reducing the volume and weight. CONSTITUTION: A screw loading test device comprises a pressure supply part(10) and a loading part. The pressure supply part comprises a table(12), a rail(22), a slider(24), a motor(18) and a first cylinder. The slider moves in horizontal direction on a rail. The first cylinder has one end fixed to the table, and a first screw piston is expanded from the other end of the first cylinder. The first screw piston is integrally formed with an output shaft of the motor. The loading part comprises a supporting beam, a lift arm, a rotary shaft, a second cylinder and a loading shaft. The supporting beam supports the body. The lift arm is installed on the upper of the supporting beam and controls the height of a mounting beam. The rotary shaft is vertically connected to the mounting beam. The loading shaft is fixed to a second piston which is drawn from the second cylinder.

Description

Low-Soil Disturbance Screw Plate Loading Test Device for Minimizing Ground Disturbance

The present invention relates to a screw load test device, and more particularly, to a screw load test device, which is an in-situ test method that can be used on land or at sea, and can minimize ground disturbance by reducing volume and weight. .

Construction of all civil structures, such as dams, tunnels, roads and bridges, takes place on or in the ground. The purpose of the ground survey is to obtain accurate ground information for the design and construction of these civil structures. The ground is very different from other civil materials such as iron, concrete, wood, etc., which can adjust their physical properties to some extent. There are many risk factors that are related to the ground in the construction of civil structures, but there are significant risks when constructing without understanding the characteristics of such ground. In addition, the collapse of foundations, delays in construction, and the excess of construction costs are often caused by inadequate understanding of the nature of the ground or the result of inappropriate ground surveys.

Therefore, interest and importance in the ground survey is increasing day by day. In general, various field tests and indoor tests have been conducted to calculate the ground characteristics and soil clarity. The reason is that disturbance of the sample due to sampling is generally known to cause errors in laboratory tests to determine the properties of the soil. However, the field dynamics test is also considered the biggest problem in the installation of the test equipment and the ground disturbance.

In addition, in recent years, domestic geotechnical survey technology has grown remarkably and reached a considerable level. However, due to lack of awareness of the importance of the ground survey, lack of survey quantity, and lack of omission, analysis of the existing data in the literature is still applied without sufficient information about the ground. In addition, there are many cases where the survey method is determined in a uniform manner without considering the adequacy of the survey method according to the ground conditions.

The cost of the ground survey has also increased much compared to the past, but there is still not enough cost for the survey. At present, the state-of-the-art equipment is used a lot in domestic geotechnical survey, but most of them use the equipment imported from foreign countries with expensive foreign currency. Therefore, there is a considerable difficulty in maintenance.

Therefore, it is necessary to develop field test equipment that combines construction and economic feasibility, which minimizes ground disturbance and enables accurate analysis of the ground.

An object of the present invention for solving the above problems is to provide a screw loading test apparatus which is an in-situ test method that can be used on land or on the ground, and can minimize ground disturbance by reducing the volume and weight.

The present invention for solving the above problems, a table constituting the body, a rail provided on one side of the table, a slider capable of parallel movement on the rail, a motor installed on the slider, one end is the table A pressure supply unit having a first cylinder fixed on the first screw piston and extending from the other end to a first cylinder integrally with the output shaft of the motor; And a support beam constituting the body, an installation beam installed on the upper side of the frame, a rotation shaft vertically connected to the installation beam, and a second end fixed to the rotation shaft and connected to the first cylinder by a hydraulic transmission hose. It is a screw loading test apparatus including a cylinder and a load loading portion having a loading axis fixed to the second piston to be inserted from the second cylinder and rotatably formed at the end.

The hydraulic pressure transfer hose is characterized in that the pressure gauge is installed.

In addition, a scale is formed on the rail, and a reference point corresponding to the scale is formed on the slider.

In addition, the motor is provided with an extension in a direction perpendicular to the rail, the end of the extension is characterized in that the displacement pin of the displacement measuring instrument fixed to the table is fixed.

In addition, the installation beam is installed on the upper portion of the frame is characterized in that the fixed to the upper end of the lift arm that can adjust the height of the installation beam.

In addition, the reload shaft is rotatably installed on the second piston by a connecting pivot formed integrally with the upper end.

In addition, the table is characterized in that the movement wheel is disposed on the moving frame is installed.

In addition, the loading plate is formed spaced apart from the lower end of the loading axis to the upper side, characterized in that consisting of a spiral auger of one rotation.

In addition, the re-shaft is characterized in that the rotary knob is formed to facilitate the rotation.

The screw loading test apparatus according to the present invention reduces the volume and weight, and can be used on land or at sea because of its excellent mobility, and can minimize ground disturbances. The characteristics of the behavior and the reduction of construction cost can be expected.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In adding reference numerals to components of the following drawings, it is determined that the same components have the same reference numerals as much as possible even if displayed on different drawings, and it is determined that they may unnecessarily obscure the subject matter of the present invention. Detailed descriptions of well-known functions and configurations will be omitted.

  1 is a schematic front view of a screw loading test apparatus according to an embodiment of the present invention, Figure 2 is a schematic perspective view of the pressure supply of the screw loading test apparatus.

The screw loading test apparatus is largely comprised of a pressure supply unit 10 and a load loading unit 38.

The pressure supply part 10 and the load bearing part 38 are connected by a hydraulic pressure transfer hose 36.

The pressure supply unit 10 generates a hydraulic pressure and has a measurement function, and includes a table 12 constituting a body, a rail 22 installed at one side of the table 12, and the rail 22. A slider 24 capable of riding parallel movement, a motor 18 mounted to the slider 24, and a first screw piston 32 having one end fixed on the table 12 and extending to the other end are described above. It comprises a first cylinder formed integrally with the output shaft of the motor.

 The table 12 is preferably installed to be horizontal to the plane for accurate measurement, it is disposed on the moving frame 14 is installed on the lower wheel to move the weight 16 and to facilitate the movement.

One pair of rails 22 is disposed on one side of the table 12. In addition, a slider 24 capable of horizontally moving on the rail 22 is disposed on the rail 22. The slider 24 is provided with sliding legs which are in sliding contact with the rail 22 on both sides.

The motor 18 is fixed to the slider 24 so that the slider 24 and the motor 18 are horizontally moved integrally.

The motor 18 should have a torque capable of sufficiently pressurizing the first cylinder 30, the first screw piston 32 is integrally formed on the output shaft of the motor 18, the motor 18 The first screw piston 32 is rotated according to the rotation.

The first screw piston 32 serves as a feed feeder, and serves to convert the rotational force of the motor 18 into a linear pressure force.

In particular, as a displacement measuring method, in the embodiment of the present invention, the extension part 25 is provided on the motor 18 in a direction perpendicular to the rail 22, and the table (at the end of the extension part 25) is provided. The displacement pin 27 of the displacement measuring instrument 29 fixed to 12 is fixed.

Therefore, the displacement pin 27 is moved together with the movement of the motor 18 to measure the displacement amount.

In addition, a first cylinder 30 into which the first screw piston 32 is inserted in the longitudinal direction of the first screw piston 32 is installed on the table 12. The first cylinder 30 is fixed by a pair of first cylinder supports 26 and 28 formed on the table 12.

Accordingly, as the motor 18 rotates, the slider 24 integrated with the motor 18 moves horizontally, and at the same time, the first screw piston 32 is inserted into the first cylinder 30. Thus, the first cylinder 30 may be pressurized or released.

One end of the first cylinder 30 is connected to the hydraulic transfer hose 36, so that the hydraulic oil filled in the first cylinder 30 can move.

The hydraulic pressure transmission hose 36 is provided with a pressure gauge 34 so as to measure the magnitude of the current pressure.

The load bearing portion 38 is a support beam 40 for supporting the body, a lift arm 42 is installed above the support beam 40 to adjust the height of the installation beam 44, and the installation beam ( A second cylinder 46 connected with the first cylinder 30 by the hydraulic transmission hose 36 and having one end fixed to the rotary shaft 45 and vertically connected to the rotary shaft 45. And a loading shaft 50 fixed to the second piston 48, which is inserted from the two cylinders 46.

In addition, for example, when installed on the target ground to be measured outdoors, such as a field test, the load loading portion 38 is connected to the existing cylinder second cylinder 46 to the support beam 40, It serves as a lift arm 42, the installation beam 44.

As in the embodiment of the present invention, the support beam 40 is installed in the upper part of the box (soil) through which the specimen of the target ground is opened, and serves to support the second cylinder 46. .

The support beam 40 is preferably made of aluminum alloy, such as light, easy to move and high strength.

In addition, a lift arm 42 is installed on the support beam 40. It is also possible to install a support arm whose length does not change instead of the lift arm 42. However, the ground and the loading shaft 50, the load bearing portion 38 is a support beam 40 for supporting the body, and the lift is installed on the upper side of the support beam 40 to adjust the height of the installation beam 44 An arm 42, a rotating shaft 45 vertically connected to the installation beam 44, and an end thereof fixed to the rotating shaft 45 and connected to the first cylinder 30 by the hydraulic transmission hose 36; And a second cylinder 46 and a loading shaft 50 fixed to the second piston 48 inserted from the second cylinder 46.

In addition, for example, when installed on the target ground to be measured outdoors, such as a field test, the load loading portion 38 is connected to the existing cylinder second cylinder 46 to the support beam 40, It serves as a lift arm 42, the installation beam 44.

As in the embodiment of the present invention, the support beam 40 is installed in the upper part of the box (soil) through which the specimen of the target ground is opened, and serves to support the second cylinder 46. .

The support beam 40 is preferably made of aluminum alloy, such as light, easy to move and high strength.

In addition, a lift arm 42 is installed on the support beam 40. It is also possible to install a support arm whose length does not change instead of the lift arm 42. However, since the distance between the ground and the loading axis 50 is not constant, it is preferable to use the lift arm 42.

The lift arm 42 is easy to adjust the length, as shown in Figure 1 can be fixed in a specific position, it is possible to use a screw jack type mechanism that can withstand a large load.

In addition, for example, when installed in the target ground to be measured outdoors, such as a field test, by connecting the rod to the second cylinder 46 vertically to adjust the length to replace the role of the lift arm 42 do.

The mounting beam 44 is fixed integrally to the upper side of the lift arm 42, and the second cylinder 46 is installed on the mounting beam 44 to face the second piston 48 below.

The loading shaft 50 is integrally installed at the lower end of the second piston 48.

The loading shaft 50 is fixed to the second piston 48 integrally, and moves up and down together according to the vertical movement of the second piston 48.

The loading shaft 50 has a connection pivot 54 is installed at the upper end for the connection with the second piston 48, the lower plate 52 is formed for contact with the ground.

The connecting pivot 54 has a thread for joining the second piston 48 while surrounding the journal and the journal integral with the loading shaft 50 so that the vertical rotation of the loading shaft 50 is freely performed. It is made in the form of.

As shown in FIG. 3, the loading plate 52 is formed to be spaced apart from the lower end of the loading shaft 50 to the upper side, and includes a spiral auger of one rotation.

In addition, in order to minimize the disturbance of the ground, it is preferable that the ratio of the loading plate 52 and the loading axis 50 is manufactured by an appropriate ratio.

Screw loading test apparatus according to an embodiment of the present invention is basically configured as described above. Hereinafter, the operation method and operation principle of the screw loading test apparatus will be described.

First, the load-bearing portion 38 is provided at a place for measuring the load, or the support beam 40 of the load-bearing portion 38 is installed on the test ground. The pressure supply part 10 is disposed around the load bearing part 38.

Then, the second cylinder 46 of the load bearing portion 38 and the first cylinder 30 of the pressure supply unit 10 are connected to the hydraulic transfer hose 36. At this time, the pressure gauge 34 is installed on the hydraulic pressure transfer hose (36).

Then, the lift arm 42 of the load loading portion 38 is used to contact the surface of the ground of the loading plate 52 of the loading shaft 50. In this state, the rotating shaft 45 is rotated to fix the loading plate 52 to the ground.

When the first screw piston 32 is rotated by operating the motor 18, the slider 24 integrated with the motor 18 is transported on the rail 22, and thus the first screw piston 32 is rotated. One screw piston 32 is inserted into the first cylinder 30.

Accordingly, the pressure in the first cylinder 30 rises, and the hydraulic oil in the first cylinder 30 is transferred to the second cylinder 46 by riding the hydraulic transfer hose 36. The two cylinders 46 push the second piston 48 to urge the lower shaft 50 downward.

Therefore, as shown in FIG. 4, the hydraulic pressure generated in the first cylinder 30 of the pressure supply part 10 may move the second piston 48 of the second cylinder 48 of the load bearing part 38. In this case, the load can be measured by measuring the force between the hydraulic pressure to be pushed out and the strata not to be pushed.

That is, the generated load may be expressed as the product of the pressure measured by the pressure gauge 34 installed in the hydraulic transfer hose 36 and the unit area of the first cylinder 30. In addition, the generated displacement is the product of the displacement of the first screw piston 32 and the cross-sectional area of the first cylinder 30, the product of the displacement of the second piston 48 and the cross-sectional area of the second cylinder 46 and Since it is the same, it can be calculated from this.

Here, since the displacement of the first screw piston 32 is the same as the displacement of the motor 18 and the slider 24, the displacement of the displacement pin 27 integrally displaced in the motor 18 is measured. It can measure conveniently by the displacement measuring device 29.

Alternatively, the displacement of the first screw piston 32 may be understood as the product of the rotation speed of the motor 18 and the lead length of the first screw piston 32. In this case, a counter capable of checking the rotation speed of the motor 18 should be installed in the motor 18.

Alternatively, the displacement of the first screw piston 32 is the same as the displacement of the motor 18 and the slider 24, so that the displacement of the displacement pin 27 integrally displaces the motor 18. It can be conveniently measured by the displacement measuring device 29 for measuring the.

As described above, it has been described with reference to the preferred embodiment of the present invention, but those skilled in the art various modifications and changes of the present invention without departing from the spirit and scope of the present invention described in the claims below I can understand that you can.

1 is a schematic front view of a screw loading test apparatus according to an embodiment of the present invention.

Figure 2 is a schematic perspective view of the pressure supply of the screw loading test apparatus of FIG.

3 is a front view of a loading shaft and a loading plate of the screw loading test apparatus of FIG.

Figure 4 is a schematic diagram illustrating the operating principle of the screw loading test apparatus of FIG.

<Description of the symbols for the main parts of the drawings>

10: pressure supply 12: table

14: moving frame 16: moving wheel

18: motor 22: rail

24: slider 25: extension part

27: displacement pin 29: displacement measuring instrument

26: the first cylinder moving support 28: the first cylinder fixed support

30: first cylinder 32: first screw piston

34: Pressure gauge 36: Hydraulic transmission hose

38: load bearing part 40: support beam

42: lift arm 44: mounting beam

45: rotation axis 46: the second cylinder

48: second piston 50: reaxial

52: Reload 54: Connect Pivot

Claims (9)

A table constituting the body, a rail provided on one side of the table, a slider capable of parallel movement on the rail, a motor installed on the slider, and a first end fixed on the table and extending to the other end A pressure supply unit having a first piston having a screw piston integrally formed with an output shaft of the motor; And A support beam constituting a body, an installation beam installed on the upper side of the frame, a rotation shaft connected to the installation beam vertically, and a second cylinder having one end fixed to the rotation shaft and connected to the first cylinder by a hydraulic transmission hose. And a load bearing part fixed to the second piston inserted from the second cylinder to be rotatable and having a loading axis having a loading plate formed at an end thereof. The screw loading test apparatus according to claim 1, wherein the hydraulic pressure hose is provided with a pressure gauge. According to claim 1, wherein the scale is formed on the rail, the screw loading test apparatus, characterized in that the reference point corresponding to the scale is formed on the slider. The screw loading test apparatus according to claim 1, wherein the extension part is installed in a direction perpendicular to the rail, and the displacement pin of the displacement measuring instrument fixed to the table is fixed to an end of the extension part. According to claim 1, The mounting beam is a screw loading test apparatus, characterized in that fixed to the upper end of the lift arm which is installed on the top of the frame to adjust the height of the mounting beam. The screw loading test apparatus according to claim 1, wherein the loading shaft is rotatably installed on the second piston by a connecting pivot integrally formed at an upper end portion. According to claim 1, wherein the table is a screw loading test apparatus, characterized in that disposed on the moving frame is installed a moving wheel. The screw loading test apparatus according to claim 1, wherein the loading plate is formed to be spaced apart from the lower end of the loading shaft and is formed in a spiral auger of one rotation. The screw loading test apparatus according to claim 1, wherein a rotation knob is formed on the loading shaft to facilitate rotation.

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