KR101513248B1 - Air pressurized bleeding measurement device - Google Patents

Abstract

In the present invention, provided is a pneumatic bleeding measuring device comprising a container which stores samples of porous materials to test bleeding inside; a pressurizing plate which is installed on the upper part of the container to vertically pressurize the sample downward; a pressure container which is connected to the upper part of the container and stores compressed air to supply a certain amount of air pressure to the upper part of the pressurizing plate in the container; a displacement measuring part which is installed on the upper part of the container and measures displacement of the pressurizing plate when air pressure is pressurized to the pressurizing plate; and a pressure measuring part which is installed on the lower part of the container and measures pressure pressurized to the sample when air pressure is pressurized to the pressurizing plate.

Description

{AIR PRESSURIZED BLEEDING MEASUREMENT DEVICE}

The present invention relates to a pneumatic bleeding measurement apparatus, and more particularly, to a pneumatic bleeding measurement apparatus which, when pressurized to measure bleeding of a non-hardened concrete mixture subjected to vertical pressure, prevents air from directly contacting sample concrete, To a pneumatic bleeding measuring device capable of precisely measuring the amount of consolidation, displacement, drainage rate, water content, and the like.

Generally, a bleeding phenomenon is one of the characteristics of a porous material such as unhardened concrete (hereinafter, concrete is described as an example). It is a kind of a kind of mixed water generated by the precipitation of cement particles and aggregate, Material separation phenomenon.

The bleeding phenomenon that occurs after the concrete is laid in this way not only causes settlement and cracking but also causes a sand road or a water stream to occur on the mold surface. In addition, in the interior of concrete, water gap is formed on the underside of aggregate or reinforcing steel, which causes deterioration of strength of reinforcing steel and concrete, deterioration of strength, and deterioration of durability.

Therefore, it is very important to understand how much of the burdening phenomenon occurs with the basic properties of concrete, so we measured the bleeding of the concrete to show the quantitative value of the bleeding.

In order to measure such bleeding, conventionally, a self-centering method of measuring the degree of sinking of concrete by its own weight is used.

That is, in the self-centering method, the concrete sample to be tested is put into the test beaker, and after a certain time, the solid particles in the concrete sink down to the bottom of the test beaker and the water contained in the concrete is separated This is the method of measuring the amount of consolidation, that is, the amount of consolidation.

However, according to the conventional self-centering method, only the amount of sinking due to the weight of the concrete can be measured, and the amount of bleeding represented by the water gap in the concrete or the amount of consolidation due to the additional pressure applied to the concrete And it is also difficult to measure the drainage rate indicating the water dropout rate from the concrete over time and the drainage amount due to the consolidation and the water content indicating the amount of water contained in the concrete at a high pressure over a certain size.

The present invention can prevent the air from directly contacting the sample concrete when pressurized to measure the bleeding of the unreinforced concrete mixture subjected to the vertical pressure and to prevent the air from penetrating into the sample concrete. The amount of consolidation, And to provide a pneumatic bleeding measurement device capable of accurately measuring drainage rate, moisture content, and the like.

According to one embodiment of the present invention, there is provided a container for containing a sample of a porous material for a bleeding test,

A pressure plate provided on an upper portion of the sample contained in the container, for pressing the sample vertically downward of the container,

A pressure vessel connected to an upper portion of the vessel and storing compressed air to provide a constant-sized air pressure on the platen in the vessel,

A displacement measuring unit provided at an upper portion of the vessel, for measuring displacement of the platen when air pressure acts on the platen, and

And a pressure measuring unit provided at a lower portion of the container and measuring a pressure applied to the sample when air pressure acts on the pressure plate.

And a water content measuring unit for measuring the amount of water exuding from the sample when the air pressure acts on the pressure plate may be installed in the lower part of the container.

The top of the vessel is open to allow the sample to be contained in the vessel,

A cap for covering and sealing the container can be removably coupled to the upper end of the container.

The supply hole formed in the lid of the container may be equipped with a connection pipe for connection with the pressure vessel.

The connection pipe may be provided with a pneumatic control valve for controlling supply of compressed air from the pressure vessel to the container and measuring air pressure supplied from the pressure vessel to the container.

Wherein the displacement measuring unit is disposed at a predetermined distance from the upper portion of the vessel and is displaced integrally with the pressure plate when the pressure plate is pressed,

And a displacement measurement sensor provided on the displacement member and measuring a distance to the displacement member when the pressure plate is pressed.

The displacement measuring unit may include a connection rod formed at an upper end of the pressure plate and integrally connecting the pressure plate and the displacement member.

The displacement measuring sensor is mounted on a mounting member disposed at a predetermined distance from the top of the lid,

The mounting member may be combined with a supporting member supported on the lid.

The pressure measuring unit may include a pressure measuring sensor installed on a bottom surface of the container and measuring a vertical pressure applied to the sample in the vertical direction when air pressure is applied to the pressure plate.

Wherein the water content measuring unit includes a discharge hole formed on a bottom surface of the container for discharging water from the container,

A discharge pipe connected to the discharge hole and discharging the water discharged through the discharge hole to the outside,

And a flow rate control valve installed in the discharge pipe to control the discharge of water from the discharge pipe and to measure the amount of water discharged from the discharge pipe and the drainage rate.

The bottom surface of the container may be provided with a filtration member for filtering water exuding from the sample when the pressure plate is pressed.

The drainage rate of the filtration member may be made larger than the permeability coefficient of the sample.

According to this embodiment, it is possible to prevent the air from directly contacting the sample concrete and pressurize the air into the sample concrete at the time of pressurization for measuring the bleeding of the uncured concrete mixture subjected to the vertical pressure, , Drainage amount, drainage rate, water content, etc. can be accurately measured.

1 is a schematic diagram of a pneumatic bleeding measurement device according to an embodiment of the present invention.
FIG. 2 shows a test state of a pressurized bleeding measurement apparatus according to an embodiment of the present invention. FIG. 2 shows the discharge state of water existing in the vessel with time under an atmospheric pressure and an additional pressure according to a pressure.
FIG. 3 is a view showing a test state of a pressurized bleeding measurement apparatus according to an embodiment of the present invention, which is classified into two stages according to the state of a sample, in which (a) is a state in which a pressure plate is placed on a non- (B) is a view showing a state in which pressure is applied to the surface of the sample to consolidate the sample, and (c) is a view showing a state in which water is discharged from the sample while the sample is being compacted.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Wherever possible, the same or similar parts are denoted using the same reference numerals in the drawings.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the invention. The singular forms as used herein include plural forms as long as the phrases do not expressly express the opposite meaning thereto. Means that a particular feature, region, integer, step, operation, element and / or component is specified, and that other specific features, regions, integers, steps, operations, elements, components, and / And the like.

All terms including technical and scientific terms used herein have the same meaning as commonly understood by those of ordinary skill in the art to which the present invention belongs. Predefined terms are further interpreted as having a meaning consistent with the relevant technical literature and the present disclosure, and are not to be construed as ideal or very formal meanings unless defined otherwise.

1 is a schematic diagram of a pneumatic bleeding measurement device according to an embodiment of the present invention.

1, a pneumatic bleeding measurement apparatus according to an embodiment of the present invention includes a container 100 for containing a sample 10 of a porous material for a bleeding test,

A pressure plate 200 provided at an upper portion of the sample 10 contained in the container 100 and for pressing the sample 10 vertically downward of the container 100,

A pressure vessel 300 connected to the vessel 100 and storing the compressed air to provide an air pressure of a predetermined magnitude above the pressure plate 200 in the vessel,

A displacement measuring unit 400 provided at an upper portion of the vessel 100 for measuring a displacement of the pressure plate 200 when air pressure acts on the pressure plate 200,

And a pressure measuring unit 500 provided at a lower portion of the container 100 and measuring a pressure applied to the sample 10 when air pressure is applied to the pressure plate 200.

A water content measuring part 600 for measuring the amount of water exuding from the sample 10 when air pressure acts on the pressure plate 200 may be installed in the lower part of the container 100.

The sample 10 may comprise a porous material, such as a fresh concrete or the like.

The container 100 is formed in a cylindrical shape or a polyhedron shape so that the container 100 can be easily manufactured and easily cleaned, and the container 100 can be opened at an upper portion to contain the sample 10 therein.

The upper portion of the vessel 100 is open to contain a sample in the vessel,

A lid 110 for covering and sealing the container may be removably coupled to the upper end of the container 100. A flange 120 may be formed on the upper end of the container 100 to be coupled to the lid 110 by a coupling means such as a bolt 130 or the like.

The pressure plate 200 is moved in the vertical direction of the container 100 in the container 100 so that the same center of the container 100 as the container 100 can be pressurized uniformly And may be formed to have a size slightly smaller than the inner surface or inner diameter of the container 100.

A supply hole 111 for receiving compressed air from the pressure vessel 300 into the vessel is formed in the lid 110 of the vessel 100 and the pressure vessel 300 is connected to the supply hole 111. [ And a connection pipe 700 for connection with the connector 700 can be mounted.

The connection pipe 700 is provided with a control unit for controlling the supply of compressed air from the pressure vessel 300 to the vessel 100 and measuring the air pressure supplied from the pressure vessel 300 to the vessel 100 A pneumatic control valve 710 may be provided.

The displacement measuring unit 400 includes a displacement member 410 disposed at a predetermined distance from the upper portion of the container 100 and moved integrally with the pressure plate 200 when the pressure plate 200 is pressed,

And a displacement measurement sensor 420 provided on the displacement member 410 and measuring the distance to the displacement member 410 when the pressure plate 200 is pressed.

The displacement measuring unit 400 may include a connection rod 430 formed at the center of the upper end of the pressure plate 200 and integrally connecting the pressure plate 200 and the displacement member 410 have.

The displacement measuring sensor 420 is mounted on a mounting member 440 disposed at a predetermined distance from the upper portion of the lid 110,

The mounting member 440 may be coupled to the supporting member 450 supported at a predetermined angle with the lid 110 in a vertical direction.

The pressure measuring unit 500 is installed on the bottom surface of the container 100 and includes a pressure measuring sensor for measuring a vertical pressure applied to the sample 10 in a vertical direction when air pressure acts on the pressure plate 200, 510 < / RTI >

The pressure measurement sensor 510 may be installed at the center of the bottom surface of the vessel 100 to accurately measure the vertical pressure applied to the sample 10 in the vertical direction.

The pressure measuring sensor 510 can measure at least 0 to 30 times (30 bar) or more of the atmospheric pressure with the sealing pressure.

A filtration member 520 may be installed on the bottom surface of the container 100 to filter water exuding from the sample 10 when the pressure plate 200 is pressed. That is, the filter member 520 may be positioned at the lower end of the sample 10 to filter the water exuding from the sample 10.

The filtering member 520 effectively filters the water exuding from the sample 10 when the pressure plate 200 is pressed and the porous stone 200 to pressurize the sample 10 with ease. (porous stone), but is not limited thereto, and any material can be used as long as it can filter water.

The drainage rate of the filtration member 520 for the drainage rate measurement of the sample is larger than that of the sample.

The water content measuring unit 600 includes a drain hole 610 formed on a bottom surface of the container 100 for discharging water from the container 100,

A discharge pipe 620 coupled to the discharge hole 610 for discharging the water discharged through the discharge hole 610 to the outside,

And a flow rate control valve 630 installed in the discharge pipe 620 and controlling the discharge of water from the discharge pipe 620 and measuring the amount of water discharged from the discharge pipe 620 and the drainage rate .

A storage vessel 800 for storing water discharged through the discharge pipe 620 may be installed at a lower portion of the vessel 100 at a predetermined distance.

First, when the lid 110 of the container 100 of the pressurized type bleeding tester is opened, the uncured concrete containing a certain amount of water as a sample 10 for the bleeding test in the container 100, Take it. The flange portion 120 of the container 100 is coupled to the lid 110 by a coupling means such as a bolt 130 or the like.

At this time, the pressure plate 200 does not yet pressurize the sample 10, that is, the pneumatic control valve 710 of the pressure vessel 300 is closed, And the displacement measurement sensor 420 always detects that the pressure plate 200 is still in contact with the sample 10 so that the sample 100 is not supplied into the container 100, (I.e., the reference distance) to the displacement member 410 without pressurizing the displacement member 410.

When the pneumatic control valve 710 is opened, compressed air of a predetermined size (for example, 3 bar) of the pressure vessel 300 is supplied into the vessel 100 through the connection pipe 700 .

As compressed air of a certain pressure is supplied into the container 100 through the connection pipe 700, pressure of compressed air is applied to the pressure plate 200. As pressure is applied to the pressure plate 200, (200) is moved vertically downward of the container (100) by a certain distance.

The displacement member 410 is moved by a predetermined distance below the vertical direction of the container 100 by the connection rod 430 in the same manner as the pressure plate 200. At this time, The distance to the displacement member 410 is measured. The difference between the measured distance and the reference distance is the compression (consolidation) length of the sample.

When the pressure plate 200 is moved vertically downward of the container 100 by a predetermined distance, the pressure plate 200 contacts the surface of the sample 10, So that the pressure is applied to the lower portion of the vertical wall. At this time, for example, a pressure of about 3 bar is applied to the pressure plate 200.

At this time, the pressure applied to the sample 10 is measured by the pressure measuring sensor 510.

As the sample 10 is applied with the pressure by the pressure plate 200, the sample 10 is compressed and becomes compaction so that the water contained in the sample 10 exudes.

The water leaking from the sample 10 is filtered through the filtration member 520 and discharged through the discharge hole 610 of the container 100. At this time, if the flow rate control valve 630 installed in the discharge pipe 620 is opened, the flow rate control valve 630 measures the amount of water discharged to the outside through the discharge pipe 620 and the drainage rate.

By measuring the amount of water discharged through the discharge pipe 620 and the drainage rate, the drainage amount of the concrete can be measured, and the amount of water, that is, water content, contained in the concrete can be measured.

In addition, the permeability of the sample can be measured since it is possible to measure the rate of withdrawal (discharge) of water exiting the concrete with time, and the displacement measurement sensor measures the distance to the displacement member, Since the sensor can measure the pressure applied to the sample, it is possible to measure an odeometric modulus that can be known how much the sample is pressed (pressurized) according to the pressure of the pneumatic cylinder or the pressure plate.

FIG. 2 shows a test state of a pressurized bleeding measurement apparatus according to an embodiment of the present invention. FIG. 2 shows the discharge state of water existing in the vessel with time under an atmospheric pressure and an additional pressure according to a pressure.

Here, the atmospheric pressure was 1 bar and the additional pressure was 2.5 bar. It can be seen that the water drainage increases linearly with time and the slope of the water discharge curve increases with increasing pressure.

3 is a view showing a test state of a pressurized bleeding measurement apparatus according to an embodiment of the present invention, which is divided into two stages according to the state of a sample. In (a), a pressure plate is placed on a non- (B) is a view showing a state in which pressure is applied to the surface of the sample to consolidate the sample, and (c) is a view showing a state in which water is discharged from the sample while the sample is being consolidated to be.

Here, a pressure of 2.5 bar is applied to the surface of the sample, and the pressure applied to the sample is measured by a pressure measurement sensor located at the bottom of the sample. The sample is a non-hardened concrete containing mortar, paste, water, air, gravel and the like.

As the sample is pressurized, it is compressed by a certain distance (s), water is drained from the sample and stored in the reservoir for a certain height (w).

100: vessel 200: pressure plate
300: pressure vessel 400: displacement measuring unit
500: pressure measuring unit 600: water content measuring unit
700: connector 800: storage container

Claims (12)

A container for containing therein a sample of a porous material for a bleeding test,
A pressure plate provided on an upper portion of the sample contained in the container, for pressing the sample vertically downward of the container,
A pressure vessel connected to an upper portion of the vessel and storing compressed air to provide a constant-sized air pressure on the platen in the vessel,
A displacement measuring unit provided at an upper portion of the vessel, for measuring displacement of the platen when air pressure acts on the platen, and
A pressure measuring unit provided at a lower portion of the container and measuring pressure applied to the sample when air pressure acts on the pressure plate,
And a pneumatic bleeding measuring device. The method according to claim 1,
And a water content measuring unit for measuring an amount of water exuding from the sample when air pressure acts on the pressure plate is installed in the lower part of the container. 3. The method according to claim 1 or 2,
The top of the vessel is open to allow the sample to be contained in the vessel,
And a cap for covering and sealing the container is detachably coupled to an upper end of the container. The method of claim 3,
And a connection pipe for connection to the pressure vessel is mounted in a supply hole formed in a lid of the container. 5. The method of claim 4,
Wherein the connection pipe is provided with a pneumatic control valve for controlling the supply of compressed air from the pressure vessel to the container and for measuring the air pressure supplied from the pressure vessel to the container. 6. The method of claim 5,
Wherein the displacement measuring unit is disposed at a predetermined distance from the upper portion of the vessel and is displaced integrally with the pressure plate when the pressure plate is pressed,
And a displacement measuring sensor provided on an upper portion of the displacement member and measuring a distance to the displacement member when the pressure plate is pressed. The method according to claim 6,
Wherein the displacement measuring unit includes a connection rod formed at an upper end of the pressure plate and integrally connecting the pressure plate and the displacement member. 8. The method of claim 7,
The displacement measuring sensor is mounted on a mounting member disposed at a predetermined distance from the top of the lid,
Wherein the mounting member is coupled to a support member supported on the lid. The method of claim 3,
Wherein the pressure measuring unit comprises a pressure measuring sensor provided on a bottom surface of the container and measuring a vertical pressure applied to the sample in a direction perpendicular to the pressure when the air pressure acts on the pressure plate. 3. The method of claim 2,
Wherein the water content measuring unit includes a discharge hole formed on a bottom surface of the container for discharging water from the container,
A discharge pipe connected to the discharge hole and discharging the water discharged through the discharge hole to the outside,
And a flow rate control valve mounted on the discharge pipe for controlling discharge of water from the discharge pipe and for measuring an amount of water discharged through the discharge pipe. The method of claim 3,
Wherein the bottom surface of the container is provided with a filtration member for filtering water exuding from the sample when the pressure plate is pressed. 12. The method of claim 11,
Wherein the drainage rate of the filtration member is greater than the permeability coefficient of the sample.

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