KR20120054428A - Measuring apparatus of frost heaving pressure for earth and sand - Google Patents

Abstract

PURPOSE: A device for testing frost heaving pressure in soils is provided to test the frost heaving pressure in soils to consider the frost heaving pressure in soils consisting of the ground for a stability analysis and whole number of design when designing an underground structure in a frozen soil region. CONSTITUTION: A device for testing frost heaving pressure in soils comprises a soil container(10), a freezing unit, and a measuring unit(30). The soil container is filled with a test sample. The freezing unit freezes the test sample inside the soil container. The measuring unit measures the frost heaving pressure of the test sample in frozen soils. The freezing unit is installed to be contacted to the test sample inside the soil container by using refrigerant.

Description

Emulsion power tester of Tosa {MEASURING APPARATUS OF FROST HEAVING PRESSURE FOR EARTH AND SAND}

The present invention relates to a frost frost test apparatus that can test the frost power of frostbite, frostbite pressure and the like due to freezing of the soil.

In winter, road pavements and structures are heavily damaged by frost heaving. In other words, if the temperature of the low temperature continues in winter, the ice layer develops by freezing moisture in the auxiliary base or roadbed, and the ice layer grows by absorbing the surrounding moisture, and as the volume expands, tremendous frostbite force acts on the ground such as road pavement. During this uplift, damage to structures such as road pavement, railways, and water pipes is called frostbite.

In order to prevent such frostbite phenomena, the frostbite forces (ie, volume expansion due to frostbite) of soils that make up the ground are analyzed for design constants and stability analysis when designing ground structures in the tundra area where conditions of frostbite are prepared. Force to be suppressed).

The present invention has been made to solve the above problems, to test the frost power of the earth and sand to consider the frost power of the ground for the design constant, stability analysis, etc. when designing the ground structure of the tundra area. The purpose of the present invention is to provide an apparatus for testing the frost power of soil.

In order to solve the above problems, the present invention is a towing (10) is filled with a common object test sample 2; A freezing unit 20 which freezes the sample 2 in the soil 10; Presenting a frost power test apparatus comprising a; measurement unit 30 for measuring the frost power of the sample (2) in the freezing soil 10.

The freezing unit 20 may be installed to use the coolant 20A and contact the sample 2 in the toner 10.

The earthwork 10 has a structure in which the upper and lower surfaces are open respectively; The freezing unit 20 is a lower freezing unit 22 coupled to the toboggan 10 to cover the open lower surface of the toboggan 10, and from the upper side of the toboggan 10 toward the toboggan 10. It may include a top freezing portion 24 installed to cover the open upper surface of the toil 10 by moving downward.

The freezing unit 20 may include a freezing unit temperature sensor 20C for measuring the temperature of the freezing unit 20.

It may further include a sample temperature sensor 50 for measuring the temperature of the sample (2) in the tank 10.

The measurement unit 30 is installed between the load-bearing portion 34 that loads the sample 2 in the soil 10 and between the load-bearing portion 34 and the sample 2 in the soil 10. It may include a load cell 32 to measure the load according to the freezing of the sample (2) in the pit 10.

The freezing section (20) includes an upper freezing section (24) which is installed to cover the open top surface of the bath (10) by moving downward from the top of the tank (10) toward the bath (10); The load cell 32 is installed on the upper side of the upper freezing unit 24 so that the load transferred from the sample 2 in the bath 10 through the upper freezing unit 24 can be measured. It can be coupled with the 24 and the reaction force member (32A).

The measurement unit 30 may further include a displacement meter 36 for measuring a volume change due to the freezing of the sample 2 in the tank 10.

It has a space to be installed therein 10, and may further include an inner heat insulating cell (60) (cell) made of a heat insulating structure.

It has a space in which the toil 10, the freezing unit 20, the measuring unit 30 is installed therein, and may further include an outer heat insulating cell 70 made of a heat insulating structure.

It may further include a water supply unit 80 for supplying water to the sample (2) in the tank 10.

The water supply unit 80 may include a water supply pipe 82 connected to a lower side of the water tank 10, and a drain pipe 84 installed at an upper side of the water tank 10 to drain water supplied to the water tank 10. It may include.

The present invention can freely measure the frost power (ie, frost pressure, frostbite amount) according to the freezing of the soil by artificially freezing the soil.

1 or less relates to the frost power test apparatus of the earth and sand according to an embodiment of the present invention,
1 is a front configuration diagram during the test.
Figure 2 is a side configuration during the test.
3 is a detail view of a portion shown in FIG.
4 is a side configuration diagram of the test standby state.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figure 1 below, the earth-force power test apparatus according to the present invention, the soil tank 10 is filled with the sample 2 of the power test object; A freezing unit 20 which freezes the sample 2 in the soil 10; It may include; measuring unit 30 for measuring the in-phase force of the sample (2) in the frozen tank 10.

That is, in-phase phenomena are caused by freezing the sample 2 in the soil 10 by the freezing unit 20, and the in-phase force caused by freezing of the sample 2 in the soil 10 frozen by the measuring unit 30. Can be measured.

Therefore, the test of the seismic power of the soil can be easily performed in this way, and the design constant, stability analysis, etc. can be prevented in consideration of the seismic power of the earth and sand when designing the ground structure of the frozen soil area. .

When described in more detail with respect to each configuration of the earth-to-force test apparatus according to the present invention as described above.

The earthenware 10 may take a variety of structures, and in particular, the upper and lower surfaces may be made of an open structure by acrylic.

The temperature of the sample 2 in the soil 10 is included in the soil 10 for the control of the freezing state of the sample 2 in the soil 10 and the analysis of the in-phase phenomenon caused by the freezing of the sample 2 in the soil 10. Sample temperature sensor 50 to measure the can be installed.

The freezing unit 20 may be in any manner as long as it can freeze the sample 2 in the tank 10, but using the coolant 20A as shown in the drawing to contact the sample 2 in the tank 10. If installed, it may be more preferable in the following points.

That is, the freezing unit 20 can be easily configured by using the refrigerant 20A, which is widely known as a cooling method, and can be frozen quickly without heat loss by directly freezing the sample 2 in the toner 10. In addition to being able to control the temperature for freezing.

At this time, the refrigerant 20A of the freezing unit 20 may be circulated along the heat exchange cycle like an air conditioner such as an air conditioner. Here, since the heat exchange cycle of the air conditioner is a technology well known in the air conditioning art, further detailed description is omitted in order not to obscure the subject matter of the present invention.

In the main body 20B of the freezing section 20, at least the sample contact section 20C in contact with the sample 2 in the tank 10 facilitates temperature transfer between the coolant 20A and the sample 2 in the tank 10. It may be made of a metal material such as aluminum, such as aluminum having excellent heat transfer rate and excellent rigidity for pressurizing the sample (2) in the soil (10). In particular, the sample contact portion 20C of the freezing portion 20 may be made of a porous metal plate.

Such a freezing unit 20 may be coupled anywhere in the earth 10, but in particular, the lower freezing unit 22 coupled to the earth 10 to cover the open lower surface of the earth 10, and the It may include an upper freezing portion 24 installed to cover the open upper surface of the toil 10 by moving downward toward the toil 10 from the upper side.

That is, as the lower freezing unit 22 is integrally coupled with the soil bath 10 in a state in which the open lower surface of the soil bath 10 is covered, the soil freezer 10 and the lower ice freezing unit are formed by constituting a part of the soil bath 10. Since the overlapping part of (22) can be eliminated, it can be advantageous in terms of miniaturization and cost reduction. In particular, as described above, the lower freezing unit 22 may directly freeze by directly contacting the sample 2 in the bath 10.

And, the upper freezing section 24 is installed so as to be able to move up and down on the upper side of the toil 10, as shown in Figures 1 to 3, to move downward to cover the open upper surface of the toil 10 ( 10) can be frozen in direct contact with the sample (2), and as shown in Figure 4 by moving upward from the tank 10 to be structurally separated to open the upper surface of the tank 10 by the soil tank 10 The inner sample 2 can be put in and removed easily. The upper freezing part 24 may be moved up and down by a driving part such as a hydraulic cylinder, and is moved up and down by the loading part 34 by being integrally coupled to the loading part 34 as described below, in particular without a separate driving part. Can be.

In particular, as the upper freezing section 24 and the lower freezing section 22 are structurally divided up and down on the basis of the toil 10, the upper freezing section 24 and the lower freezing section 22 are simultaneously 10) freezing the sample (2) in the inside or the upper freezing section 24 and the lower freezing section 22 may freeze the sample (2) in the soil 10 in sequence, the upper freezing section 24 and the lower Only one of the freezing sections 22 may freeze the sample 2 in the bath 10. Therefore, the ground and the ground surface are substantially different in temperature, and as the upper freezing section 24 and the lower freezing section 22 are structurally separated to freeze the sample 2 in the soil 10 respectively, various variables are changed. In turn, empirical tests of frostbite soil can be done.

On the other hand, the freezing unit 20 is to determine the temperature of the refrigerant 20A delivered to the soil in the sample (2) so that the freezing state of the soil in the sample (2) can be adjusted by the temperature or the like of the freezing unit (20). It may include a freezing unit temperature sensor (not shown) for measuring the temperature.

 The measurement unit 30 may measure a load due to freezing of the sample 2 in the towing 10 so that the measurement force of the sample 2 in the towing 10 may be directly measured. load cell) 32.

The load cell 32 may have any structure as long as the load cell 32 can receive the load due to the freezing of the sample 2 in the soil 10.

However, the load cell 32 is installed on the upper side of the upper freezing unit 24 so as to measure the load transmitted from the sample 2 in the tank 10 through the upper freezing unit 24 and the upper freezing unit 24. And coupled through the reaction force member 32A may be more advantageous as follows. That is, in this case, as the upper freezing part 24 also serves as a pressure plate for load transfer according to the freezing of the sample 2 in the towing 10, the overlapping portion of the upper freezing part 24 and the load cell 32 Can be eliminated, it can be advantageous in terms of structure. In addition, as the upper freezing part 24 serves as a pressure plate, the upper and lower parts 24 may flow up and down while being in contact with the sample 2 in the toner 10 in response to the expansion of the sample 2 in the toner 10 according to the freezing. Therefore, even if the upper freezing section 24 is installed on the upper side of the sample 2 in the soil tank 10, the load cell 32 makes it possible to accurately correct the in-phase force, ie, in-phase pressure, caused by the freezing of the sample 2 in the soil tank 10. It can be measured.

On the other hand, the measurement unit 30 is installed in the upper portion of the load cell 32 through the upper freezing unit 24 connected to the load cell 32 in order to measure empirical frost power through the load cell 32 in the earthwork 10. It may further include a load-bearing portion 34 for loading the sample (2). The load bearing portion 34 may be formed by a hydraulic cylinder method or the like. Here, since the present invention is not related to the structure of the load bearing portion 34 and the load bearing portion 34 is a technology well known in the art, such as earth pressure measurement, detailed description in order not to obscure the subject matter of the present invention. Is omitted.

In addition, the measurement unit 30 may further include a displacement meter 36 to measure the volume change due to the freezing of the sample 2 in the soil 10, that is, the in-phase amount. For example, the displacement meter 36 is connected by the load cell 32 to measure the vertical displacement of the load cell 32 in accordance with the freezing of the sample 2 in the tank 10, so that the displacement of the load cell 32 through the vertical displacement of the load cell 32 10) The in-phase amount of the sample 2 can be measured. Here, since the present invention is not related to the structure of the displacement meter 36, and the displacement meter 36 is a technology well known in the art, such as measurement, further detailed description will be omitted in order not to obscure the subject matter of the present invention.

On the other hand, the present invention has a space in which the earthwork 10 is installed therein, and may further include an internal heat insulating cell (60) formed of a heat insulating material such as styrofoam and made of a heat insulating structure. Accordingly, the freezing delay and freezing caused by the influence of the external temperature when the sample 2 in the tank 10 is frozen by the freezing unit 20 do not proceed in the vertical direction of the tank 10 but do not freeze. It can be prevented from proceeding from the start. Such internal insulation cells 60 may take a hermetic structure as shown for an insulation structure.

In addition, the present invention has a space in which the earthwork 10, the freezing unit 20, the measuring unit 30 is installed therein, and further comprises an outer heat insulating cell 70 formed of a heat insulating material such as styrofoam and made of a heat insulating structure. Can be. The outer insulation cell 70 may also be made similarly to the inner insulation cell 60.

In addition, the present invention may further include a water supply unit 80 for supplying water to the sample (2) in the soil 10. That is, the frostbite phenomenon of the earth and sand is due to the water condensation in the soil at low temperature, so that the water content of the sample 2 in the soil 10 is supplied to the sample 2 in the soil 10 through the water supply unit 80. It can be easily adjusted so that the sample 2 in the soil can be empirically frozen.

In particular, the water supply part 80 is a water supply pipe 82 connected to the lower side of the soil tank 10, a drain pipe 84 installed above the soil tank 10, the water supply to the water tank 10 is drained, water supply control It may include a water supply control unit 86, such as a valve for. That is, as the water supply is made in the reverse direction from the lower side to the upper side, since the water can be supplied from the bottom of the sample 2 to the surface of the tank 10, the sample 2 in the soil tank 10 can be sufficiently functioned as a whole. In addition, as the sample 2 in the soil 10 is sufficiently functioned as described above, air between the samples 2 in the soil 10 can be removed. In addition, when the sample 2 in the soil 10 is sufficiently functioned, the water supplied to the soil 10 through the drain pipe 84 is naturally drained, and from this, the sample 2 in the soil 10 is sufficiently functioned. The water supply can be easily adjusted.

In this case, the water supply pipe 82 and the drain pipe 84 may be integrally connected to the lower freezing unit 22 and the upper freezing unit 24, respectively.

Meanwhile, reference numeral '90' in FIG. 1 denotes a control panel 90 for circulating the refrigerant 20B of the freezing section 20, adjusting the load loading of the load loading section 34, and the reference numeral '92'. The load cell 32 and the server 92 which process the signal measured by the displacement meter 36 are instruct | indicated.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

2; Sample 10; Tojo
20; Freezing section 20A; Refrigerant
22; Lower freezer 24; Upper freezing part
30; A measuring unit 32; Load cell
34; Load bearing section 36; Displacement meter
50; Sample temperature sensor 60; Internal thermal insulation cell
70; Outer insulating cell 80; Water supply

Claims (12)

A soil bath 10 in which a common-state test object sample 2 is filled;
A freezing unit 20 which freezes the sample 2 in the soil 10;
A measuring unit 30 for measuring the in-phase force of the sample 2 in the freezing vessel 10;
Tosa frost power test apparatus comprising a. The method according to claim 1,
The freezing unit 20 is a frost power test apparatus, characterized in that installed using the refrigerant (20A) to contact the sample (2) in the soil 10. The method according to claim 2,
The earthwork 10 has a structure in which the upper and lower surfaces are open respectively;
The freezing unit 20 is a lower freezing unit 22 coupled to the toboggan 10 to cover the open lower surface of the toboggan 10, and from the upper side of the toboggan 10 toward the toboggan 10. An earth force test device of the earth and sand, characterized in that it comprises a top freezing unit 24 is installed to cover the open top surface of the earthwork 10 by moving downward. The method according to any one of claims 1 to 3,
The freezing unit 20 is a frost power test apparatus, characterized in that it comprises a freezing unit temperature sensor (20C) for measuring the temperature of the freezing unit (20). The method according to any one of claims 1 to 3,
An earth force test device of the earth and sand further comprises a sample temperature sensor (50) for measuring the temperature of the sample (2) in the soil (10). The method according to any one of claims 1 to 3,
The measurement unit 30 is installed between the load-bearing portion 34 that loads the sample 2 in the soil 10 and between the load-bearing portion 34 and the sample 2 in the soil 10. And a load cell (32) for measuring a load according to freezing of the sample (2) in the earthenware (10). The method of claim 6,
The freezing section (20) includes an upper freezing section (24) which is installed to cover the open top surface of the bath (10) by moving downward from the top of the tank (10) toward the bath (10);
The load cell 32 is installed on the upper side of the upper freezing unit 24 so that the load transferred from the sample 2 in the bath 10 through the upper freezing unit 24 can be measured. Tosa frost power test apparatus, characterized in that coupled through the 24 and the reaction force member (32A). The method of claim 6,
The measurement unit 30 further comprises a displacement meter (36) for measuring the change in volume due to the freezing of the sample (2) in the soil (10). The method according to any one of claims 1 to 3,
An earth force test device having a space therein is installed therein, and further comprising an inner heat insulation cell (60) formed of a heat insulation structure. The method according to any one of claims 1 to 3,
An earth force test device of the earth and sand, characterized in that it further comprises an outer heat insulating cell (70) made of a heat insulating structure having a space in which the earth (10) and the freezing unit 20, the measuring unit 30 is installed. The method according to any one of claims 1 to 3,
Earthing force test apparatus of the earth and sand further comprises a water supply unit 80 for supplying water to the sample (2) in the soil tank (10). The method of claim 11,
The water supply unit 80 may include a water supply pipe 82 connected to a lower side of the water tank 10, and a drain pipe 84 installed at an upper side of the water tank 10 to drain water supplied to the water tank 10. Tosa frost power test apparatus comprising a.

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