KR101190021B1 - Loading and load maintenance system for concrete creep test - Google Patents

Abstract

The present invention discloses a concrete test load bearing system. According to an aspect of the present invention, an air compressor for producing compressed air using an electric motor, connected to the air compressor, an air pressure pump for flowing the compressed air produced by the air compressor, and The compressed air is supplied through the pneumatic pump to load the test object to be tested, and the creep is configured to measure the deformation of the test object by continuously loading the test object through the hydraulic jack after mounting the test object. There is provided a concrete test load bearing system including a tester and a pressure adjusting device to maintain a constant pressure by adjusting the air pressure supplied from the pneumatic pump to the creep tester.

Description

Loading and load maintenance system for concrete creep test

The present invention relates to a concrete creep test load carrying system, and more particularly, to a concrete creep test load carrying system which enables to maintain a constant load automatically during the concrete creep test until the end of the test.

In general, creep tests are performed to reflect deformation in the design due to the continuous load of the structure by predicting the deformation of the material in the environment in which the concrete product will be used to extend the life of the structure.

Concrete, like many structural materials, has a certain degree of elasticity. These materials are characterized by an increase in deformation over time under continuous loading, which is called a creep, and a tester that measures this is called a creep tester.

The creep test is intended to measure compressive creep stains until the material converges at displacement at constant temperature and humidity.

In addition, the concrete creep test method is set to perform the test by loading the load within 40% of the compressive strength of the test body after setting the concrete of the test body on the pressure plate (132d) of the creep tester to press a certain load.

According to the conventional creep test method described above, the load on the test specimen (concrete) must maintain the load during the test period, and the displacement of the test specimen is measured using a measuring instrument according to the procedure.

Therefore, as an important matter regarding the load management during creep test, the creep coefficient of the target concrete is determined according to the magnitude of the load and the displacement caused by the load within the elastic range of the test specimen set in the testing machine. Maintain the rated load on the specimen.

However, in the conventional creep test, the hydraulic jack and the pneumatic pump 120 are used to apply the load to the test body, so that the load is continuously checked during the test period, and there is an inconvenience to compensate by adjusting the insufficient load as the deformation of the test body. .

In addition, in the conventional creep test, when the plurality of creep testers are operated, the air compressor is operated in the same number as the number of creep testers, thereby causing a waste of power.

That is, when each creep tester carries out a different load test, there is no device that can adjust the air pressure supplied from the air compressor. Therefore, a large amount of power was consumed by installing an air compressor for each creep tester.

Therefore, the applicant of the present invention has come up with a concrete creep test load holding system that can solve the problems described above.

Embodiments of the present invention are to provide a concrete creep test load maintenance system to maintain the rated load to the test specimen during the creep test period by continuously supplying the insufficient load automatically in performing the creep test .

According to an aspect of the present invention, an air compressor for producing compressed air using an electric motor, connected to the air compressor, an air pressure pump for flowing the compressed air produced by the air compressor, and The compressed air is supplied through the pneumatic pump to load the test object to be tested, and the creep is configured to measure the deformation of the test object by continuously loading the test object through the hydraulic jack after mounting the test object. There is provided a concrete test load bearing system including a tester and a pressure adjusting device to maintain a constant pressure by adjusting the air pressure supplied from the pneumatic pump to the creep tester.

In addition, the creep tester is installed between the base, the first fixing plate and the second fixing plate which is spaced in the vertical direction by a plurality of guide rods on the upper surface of the base, and the first fixing plate and the second fixing plate and selectively A body part comprising a pressure plate formed to mount a test body to be tested by being raised and lowered, a load spring installed between the first fixing plate and the pressure plate, and installed between the base and the first fixing plate, and the pneumatic pump It is characterized in that it comprises a hydraulic jack which is partially lifted in the vertical direction by the pneumatic pressure supplied from, and the measuring pin is installed on the test body mounted on the pressure plate.

In addition, the lower portion of the base is characterized in that the shock absorbing member is installed to absorb the aftershocks.

In addition, the pressure regulating device is installed between the pneumatic pump and the hydraulic jack, the pressure locking device to selectively block the pneumatic pressure supplied from the pneumatic pump, the pressure locking device and one side is connected, the air pressure Pressure gauge to control the pneumatic pressure supplied from the pump and to maintain a constant, and to display the pneumatic pressure controlled by the pressure reducing valve, one end is coupled to the pressure reducing valve, the other end is connected to the hydraulic jack pressure gauge Characterized in that it comprises a.

In addition, the pressure reducing valve is formed with an inlet for discharging the inlet and the inlet for introducing the pneumatic pressure supplied to the pneumatic pump, a through hole for partitioning the inlet and the outlet therein A housing formed, an opening and closing member having a predetermined length and having one end contacted with the through hole to be selectively sealed, an elastic plate contacting the other end of the opening and closing member and sealing a portion of the housing to guide the pneumatic pressure; To be screwed to one side of the housing to be advanced back and forth according to the rotation, the pressure adjusting screw to adjust the inlet air pressure, and installed between the elastic plate and the pressure adjusting screw to elastically support the elastic plate, Pressing the elastic plate in accordance with the forward and backward movement of the pressure adjusting screw to allow the opening and closing member to be selectively transported First elastic member, the one ends of the urging of the closing member to be installed on the inlet side in the housing characterized by comprising second elastic members.

In addition, the concrete test load load holding system is characterized in that the plurality of the creep tester and the plurality of pressure regulators connected to the air compressor and the pneumatic pump can be installed at the same time to perform a plurality of tests.

Concrete creep test load load maintenance system according to an embodiment of the present invention by installing a pressure regulator that can supply a constant air pressure to the hydraulic jack to apply a load to the test body by using the air pressure, the hydraulic pressure insufficient for the test period automatically The test can be performed conveniently and reliably in managing the load.

1 is a block diagram of a concrete creep test load bearing system according to an embodiment of the present invention.
2 is a view schematically showing a creep tester used in the concrete creep test load bearing system according to an embodiment of the present invention.
3 is a front view of Fig.
4 is a view schematically showing a pressure regulating device used in the concrete creep test load bearing system according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings an embodiment of the concrete creep test load loading system according to an embodiment of the present invention will be described in more detail.

1 is a block diagram of a concrete creep test load bearing system according to an embodiment of the present invention.

Referring to the drawings, the concrete creep test load carrying system of the present invention includes an air compressor 110, an air pressure pump 120, a creep tester 130, and a pressure regulator (140).

The air compressor 110 is a device that compresses air by using an electric motor, and functions to store the air at high pneumatic pressure after producing air by receiving power from the outside.

In addition, the pneumatic pump 120 functions to supply the compressed air stored in connection with the air compressor 110 to a device that requires pneumatic pressure as needed.

That is, by supplying the compressed air produced by the air compressor 110 to the creep tester 130 to be described later to load the concrete test body (P).

Here, the air compressor 110 and the air pressure pump 120 is a technique already known to the public already, detailed description thereof will be omitted.

2 is a view schematically showing a creep tester 130 used in the concrete creep test load bearing system according to an embodiment of the present invention, Figure 3 is a front view of FIG.

Referring to the drawings, the creep tester 130 is loaded with a constant pressure to the concrete test body (P) to be tested by using the compressed air supplied through the pneumatic pump 120 to deform the test body (P). In order to be able to measure, it largely includes the body 132, the load spring 134, and the hydraulic jack 136.

The body portion 132 includes a base 132a, a first fixing plate 132b and a second fixing plate 132c which are vertically spaced apart from the upper surface of the base 132a, and the first fixing plate 132b and the The pressure plate 132d positioned between the second fixing plate 132c, and one end is coupled to the base 132a, and the other end is coupled to the second fixing plate 132c so that the pressure plate 132d is coupled therethrough. It includes a plurality of guide rods (132e).

Specifically, the base 132a is formed in a plate shape having a predetermined area, and a shock absorbing member 133 is installed at the lower portion so as to absorb aftershocks.

Here, the shock absorbing member 133 has a function of elastically supporting the base 132a as a compression coil spring so as to absorb shock when an aftershock occurs in a building or the ground on which the creep tester 130 is installed.

In addition, the first fixing plate 132b and the second fixing plate 132c which are spaced apart from the upper surface of the base 132a are configured to be selectively controlled in height in a state supported by the guide rod 132e. A nut 132f is provided to restrain the positions of the adjusted first fixing plate 132b and the second fixing plate 132c.

At this time, the nut 132f to restrain the positions of the first fixing plate 132b and the second fixing plate 132c is lowered to restrain the positional movement in the downward direction in the case of the first fixing plate 132b. It is installed only on the side, and in the case of the second fixing plate 132c so as to be installed in both the upper and lower parts so that there is no position movement.

And, the pressure plate 132d is formed to be seated so that the concrete test body (P) to be tested is formed in a plate shape, it is coupled so that it can be selectively elevated along the guide rod (132e).

In addition, a load spring 134 is provided between the pressing plate 132d and the first fixing plate 132b to elastically support the pressing plate 132d.

At this time, the load spring 134 is positioned to surround each of the plurality of guide rods 132e installed to penetrate the pressing plate 132d.

In addition, a hydraulic jack 136 is installed between the first fixing plate 132b and the base 132a.

The hydraulic jack 136 is operated by the pneumatic pressure supplied by the pneumatic pump 120, by pressing the first fixing plate 132b, the pressure plate 132d installed to be elastically supported by the load spring 134 While pressing to move to the second fixing plate 132c side serves to apply a compressive force to the test body (P).

That is, the first fixing plate 132b restrains only movement in the downward direction by the nut 132f. When the hydraulic jack 136 installed in the lower part is operated, the piston is directed upwards, so that the first fixing plate 132b is moved. Pressurized.

Accordingly, by pressing the pressure plate 132d while the load spring 134 is compressed, the test body P mounted on the pressure plate 132d is compressed by the pressure plate 132d and the second fixing plate 132c.

In this case, a plurality of measuring pins 135 are inserted into the test body P at equal intervals, and the distance between the measuring pins 135 that approaches the pressing plate 132d and the second fixing plate 132c is measured. By this, the strain of the test body P can be confirmed.

On the other hand, the pressure regulator 140 is installed between the pneumatic pump 120 and the creep tester 130.

4 is a view schematically showing a pressure regulating device 140 used in the concrete creep test load bearing system according to an embodiment of the present invention.

Referring to the drawings, the pressure regulating device 140 serves to maintain a constant pressure by reducing the pneumatic pressure supplied into the hydraulic jack 136 by the pneumatic pump 120, of the hydraulic jack 136 It is installed on one side

Specifically, the pressure regulator 140 is installed to be connected to the pneumatic cable (S) connecting the pneumatic pump 120 and the hydraulic jack 136, the pressure locking device 141, the pressure reducing valve 142, Pressure gauge 148.

The pressure locking device 141 may selectively block the pneumatic pressure supplied through the pneumatic pump 120, and manually removes the flow of pneumatic pressure when the air compressor 110 or the pneumatic pump 120 malfunctions or malfunctions. It is formed to be blocked.

The pressure reducing valve 142 is formed to maintain the rated air pressure by reducing the air pressure supplied to the hydraulic jack 136 through the pneumatic pump 120, the housing 143, the opening and closing member 144, the elastic plate 145, a pressure adjusting screw 146, and an elastic member 147.

The housing 143 is an inlet port 143a to allow the pneumatic pressure supplied through the pneumatic pump 120 to be introduced, and the pneumatic pressure introduced into the housing 143 is converted into the rated pneumatic pressure to be discharged to the hydraulic jack 136. And an outlet 143b to be made.

At this time, the inlet 143a and the outlet 143b are partitioned by partitions 143c formed in the housing 143, and the partitions 143c are formed with through holes 143d to allow pneumatic flow.

The opening and closing member 144 is formed to have a predetermined length, and both ends thereof are formed to extend in the circumferential direction, and are positioned to penetrate the through hole 143d to selectively open and close the through hole 143d. .

That is, the opening and closing member 144 is positioned so that one end can be selectively closed by contacting the through hole 143d, and the other end is in contact with the elastic plate 145 described later.

The elastic plate 145 is formed to guide the pneumatic pressure introduced by sealing a part of the housing 143 to be discharged through the outlet 143b.

In addition, the pressure adjusting screw 146 is screwed to one side of the housing 143.

The pressure adjusting screw 146 adjusts the pneumatic pressure flowing through the inlet 143a, and is advanced back and forth into the housing 143 as it rotates.

The elastic member 147 elastically supports one end of the first elastic member 147a installed between the elastic plate 145 and the pressure adjusting screw 146 and the opening / closing member 144 located at the inlet side. The second elastic member 147b is formed.

That is, the second elastic member 147b is positioned to elastically support one end of the opening and closing member 144 positioned at the inlet 143a and the elastic plate 145 is in contact with the other end of the opening and closing member 144. ) Is a configuration in which the first elastic member 147a is installed to elastically support ().

In this case, the first elastic member 147a is formed to have a higher elastic force than the second elastic member 147b so that the opening and closing member 144 is compressed toward the inlet 143a when the first elastic member 147 is compressed. As a result, the through hole 143d is opened.

On the other hand, the pressure gauge 148 is installed in the outlet 143b of the housing 143.

The pressure gauge 148 is a function of displaying the pneumatic pressure flowing into the pressure reducing valve 142, one end is connected to the outlet 143b of the housing 143, the other end is connected to the hydraulic jack 136 do.

Referring to the operating state of the concrete creep test load loading system according to an embodiment of the present invention made as described above are as follows.

First, power is supplied to the air compressor 110 so that the air compressor 110 is driven.

Thereafter, the compressed air produced by the air compressor 110 flows to the pressure reducing valve 142 through the air pressure pump 120.

Thereafter, by using the pressure adjusting screw 146 and the pressure gauge 148 of the pressure reducing valve 142, the air pressure flowing into the pressure reducing valve 142 may be converted into the rated air pressure required for the creep test and supplied to the hydraulic jack 136. Make sure

Thereafter, the piston of the hydraulic jack 136 is raised by the pneumatic pressure supplied into the hydraulic jack 136 to press the first fixing plate 132b, and as the first fixing plate 132b rises, the load spring 134 As the pressure plate 132d positioned to be elastically supported rises, the test body P is pressed to measure the strain of the test body P.

Therefore, the concrete creep test load loading system according to an embodiment of the present invention always installs the rated air pressure in the hydraulic jack 136 by installing the pressure regulating device 140 between the pneumatic pump 120 and the creep tester 130. Can supply

Accordingly, the operator does not have to continuously adjust the pressure of the creep tester 130, it is possible to perform a convenient and stable test.

In addition, when driving a plurality of creep tester 130 to produce compressed air through a single air compressor 110, each creep tester 130 by installing a pressure regulator 140 on each side of each creep tester Different numbers of rated air pressures can be supplied to (130), allowing for multiple tests at once.

In addition, even when the single air compressor 110 is driven, the plurality of creep testers 130 may be operated to save power due to the air compressor 110 being driven.

So far, the present invention has been described in detail with reference to embodiments of the present invention, but the scope of the present invention is not limited thereto, and it will be included to substantially equivalent ranges with the embodiments of the present invention.

110: air compressor 120: air pressure pump
130: creep tester 132: body portion
132a: base 132b: first fixing plate
132c: second fixing plate 132d: pressure plate
132e: Guide rod 132f: Nut
133: buffer member 134: load spring
135: measuring pin 136: hydraulic jack
140: pressure regulating device 141: pressure locking device
142: pressure reducing valve 143: housing
143a: inlet 143b: outlet
143c: bulkhead 143d: through hole
144: opening and closing member 145: elastic plate
146: pressure adjusting screw 147: elastic member
148: pressure gauge P: test body

Claims (6)

An air compressor capable of producing compressed air using an electric motor,
An air pressure pump connected to the air compressor and configured to flow compressed air produced by the air compressor;
A creep tester which receives compressed air through the pneumatic pump and loads the test body to be tested to measure deformation of the test body;
It includes a pressure regulator to maintain a constant pressure by adjusting the pneumatic pressure supplied to the creep tester from the pneumatic pump,
The creep tester
A base, a first fixing plate and a second fixing plate which are spaced in the vertical direction by a plurality of guide rods on the upper surface of the base, and a pressing plate which is selectively lifted up and down between the first fixing plate and the second fixing plate. Body,
A load spring installed between the first fixing plate and the pressing plate;
A hydraulic jack installed between the base and the first fixing plate, the hydraulic jack being partially lifted up and down by pneumatic pressure supplied from the pneumatic pump,
Concrete creep test load load holding system, characterized in that it comprises a measuring pin installed on the test body mounted on the pressure plate delete The method according to claim 1, wherein the lower portion of the base is a concrete creep test load load retention system, characterized in that the shock absorbing member is installed to absorb the aftershocks, etc. The method of claim 1, wherein the pressure regulator is installed between the pneumatic pump and the hydraulic jack,
A pressure lock device for selectively blocking the pneumatic pressure supplied from the pneumatic pump;
A pressure reducing valve connected to one side of the pressure locking device and configured to maintain a constant pressure by adjusting the air pressure supplied from the air pressure pump;
Indicating the pneumatic pressure controlled by the pressure reducing valve, one end is coupled to the pressure reducing valve, the other end is a concrete creep test load load holding system comprising a pressure gauge connected to the hydraulic jack The method of claim 4, wherein the pressure reducing valve
A housing formed with an inlet for introducing the pneumatic pressure supplied to the pneumatic pump and an outlet for discharging the introduced pneumatic pressure, and having a hole formed therein for partitioning the inlet and the outlet;
An opening and closing member having a predetermined length and having one end contacted with the through hole to be selectively sealed;
An elastic plate contacting the other end of the opening and closing member and guiding pneumatic pressure introduced by sealing a part of the housing;
A pressure adjusting screw which is screwed to one side of the housing and moved forwards and backwards by rotation, so as to adjust the inlet air pressure;
A first elastic member installed between the elastic plate and the pressure adjusting screw to elastically support the elastic plate, and pressurizing the elastic plate according to forward and backward advancement of the pressure adjusting screw so that the opening and closing member can be selectively transported; ,
The concrete creep test load carrying system, characterized in that the second elastic member is installed on the inlet side of the housing to elastically support one end of the opening and closing member. The system of claim 1, wherein the concrete test load bearing system is
Concrete creep test load loading system, characterized in that a plurality of tests can be performed at the same time by installing a plurality of the creep tester and a plurality of the pressure control device connected to the air compressor and the air pressure pump.

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