KR101962368B1 - Salt contamination test apparatus of concrete structure under pressure and method thereof - Google Patents

Abstract

Disclosed is an apparatus for testing indoor salt damage of concrete under pressure. The apparatus for testing an indoor salt damage of concrete under pressure, according to the present invention, comprises: a specimen mounting member including a seating space for a concrete specimen to be seated and provided, and an inlet and an outlet communicating with the seating space such that air or water pressure acts on the specimen provided in the seating space; and a pressure applying unit for supplying air containing chloride ions to the inlet of the specimen mounting member to apply pressure to the specimen, or for supplying seawater to the inlet of the specimen mounting member to apply water pressure. According to the present invention, concrete specimens collected or manufactured directly from concrete structures which are expected to be used as offshore concrete structures under pressure at construction sites, or concrete test specimens manufactured under the same conditions as concrete to be used as offshore concrete structures under pressure at construction sites can be exposed to pressure (air pressure) or chloride ions (hydraulic pressure) indoors, thereby predicting and determining salt damage of marine concrete according to the pressure.

Description

Technical Field [0001] The present invention relates to a method for testing indoor salt resistance of a concrete under pressure,

More particularly, the present invention relates to a device for testing indoor salinity of concrete under pressure capable of predicting and evaluating the salinity of a concrete under pressure and a method therefor will be.

Generally, in a reinforced concrete structure (hereinafter referred to as a concrete structure), reinforcing bars in concrete are protected from corrosion by forming a passive film on a surface protected by a pore solution of a high-pH concrete.

However, concrete exposed to the marine environment is exposed to chloride ions such as seawater or saline, and chloride ions penetrate into the concrete. If the accumulated chloride content exceeds the allowable limit, the passive coating of steel And corrosion of the steel material greatly affects the durability of the marine concrete structure.

In other words, the corrosion caused by the rebar decreases the bond strength between the reinforcing steel and concrete and causes the corrosion cracks of the concrete due to the volume expansion of the corrosion product. In severe cases, it causes peeling and peeling of the coated concrete. Factors that cause corrosion of reinforcing bars in reinforced concrete structures include oxygen, neutralization, temperature and humidity, chloride concentration and pH, macrocels, resistivity of concrete, americ current, sulfate reduction bacteria, quality of concrete, Components, and the most detrimental ones are chloride concentration and pH.

In particular, in the case of bridges constructed near the coast and bridges installed in the sea, corrosion of steel bars is determined depending on chloride concentration and pH. In the case of offshore structures, as the water depth becomes deeper, In case of cast wave power generation structure, the durability of the structure can be greatly lowered by the air pressure containing the chloride concentration in the air.

In the case of a concrete structure with a concrete structure as described above, it is confirmed that the durability of the salt is weaker than that of the concrete structure which is not pressured by the hydraulic pressure and the pneumatic pressure.

Therefore, in the case of marine concrete structures, it was necessary to check whether or not the salt penetrated into the concrete, and to take necessary measures when the salt penetrated.

However, conventionally, in order to measure the salt concentration penetrated into the interior of a marine concrete structure, concrete specimens are taken at a predetermined time period, and the collected test pieces are crushed and ground to measure the concentration of the salt contained in the concrete The measurement of salinity was very inconvenient.

As a conventional technique for solving such a problem, Korean Patent Registration No. 10-1273623 (Publication Date: 2013.06.11) discloses a salinity measurement sensor and a salinity measurement apparatus using the same. The chloride measurement sensor is embedded in the concrete structure, and the chloride measurement sensor directly contacts the moisture contained in the pores inside the concrete structure, so that an electrical signal corresponding to the salt penetrated into the concrete is transferred to the outside of the concrete structure And the measurement module is configured to measure the concentration of the salt contained in the concrete by using the electrical signal inputted from the salt measurement sensor in the measurement module.

However, the apparatus for measuring the salinity of such a structure can detect the salinity concentration in real time, but it has a problem that it is difficult to grasp the degree of salting according to the pressure (water pressure depending on the water depth). That is, since the durability of the marine concrete structure is weaker than that of a concrete structure that is not subjected to hydraulic pressure or pneumatic pressure, it is necessary to measure the penetration of chloride ions according to the pressure. However, There is a problem that the means for measuring is not presented.

For example, in the case of the vibration power type wave power generation, wave energy is generated in the air chamber made of a concrete structure to change the water level in the air chamber and to discharge the internal air to the duct. In the vibration power type wave power generator, In this case, not only concrete structures that are submerged in seawater but also concrete structures not exposed to seawater are exposed to chloride by internal air. Especially, when pressure is applied to the internal air chamber made of concrete structure, durability It is found that there is a problem that it is more vulnerable than general concrete structure.

Therefore, a means for predicting the amount of chloride in a marine concrete structure depending on hydraulic pressure or pneumatic pressure, that is, means for judging and evaluating whether or not the salt has been required.

. Korean Patent No. 10-1273623 (Notification date: 2013.06.11)

It is an object of the present invention to provide a means for predicting, evaluating and evaluating whether or not a concrete specimen is exposed to pressure (air pressure or sea water pressure) or chloride ion (water pressure) indoors.

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to at least partially solve the problems in the conventional arts. It can be understood.

According to an aspect of the present invention, there is provided a test piece mounting apparatus comprising: a test piece mounting member having a seating space for seating and installing a concrete test piece, and an inlet and an outlet communicating with the seating space such that air pressure or water pressure acts on the test piece installed in the seating space; And a pressure applying unit configured to pressurize the test piece by supplying air containing chloride ions to the inlet of the test piece mounting member or pressurize the water pressure by supplying seawater to the inlet of the test piece mounting member. This is accomplished by an indoor salt tester of concrete under pressure.

When the air containing chloride ions is pressurized on the test piece provided in the seating space, the pressure applying portion includes an air chamber configured to receive seawater and air in the receiving space together; An air compressor for generating air pressure to supply the air in the accommodation space to the inlet to act on the test piece; And a pressure regulator installed between the air compressor and the air chamber to regulate the pressure.

A recovery line for recovering the air discharged from the seating space to the air chamber is provided at an exit of the seating space, and an inlet of the seating space is provided with air from the air chamber to the inlet A supply line can be installed.

The pressure applying unit may further include a pressure reducing valve installed between the pressure regulator and the air chamber for reducing the pressure of the accommodation space to periodically perform an operation of pressing and depressurizing the pressure of the seating space, The compressor, the pressure regulator, and the pressure reducing valve.

Wherein when the water pressure is applied to the test piece provided in the seating space, the pressure applying portion includes a seawater chamber configured to receive seawater in the receiving space; And a seawater pump for supplying seawater of the accommodation space to the inlet so as to act on the test piece.

At this time, the water pump or the supply line may be provided with a water pressure regulator for regulating the pressure of seawater supplied to the seating space.

A recovery line for recovering the seawater discharged from the seating space to the seawater chamber is provided at an outlet of the seating space, and at the entrance of the seating space, seawater is supplied from the seawater chamber to the inlet A supply line can be installed.

According to the present invention, there is provided a method for producing a test specimen, comprising the steps of: collecting a test specimen in a concrete manufactured to be used as a marine concrete structure, preparing a concrete specimen directly, or collecting a test specimen from a concrete structure to be used as a marine concrete structure; A test piece mounting step of installing and fixing the test piece taken in the test catching step in a seating space provided in a test piece mounting member of an indoor salt tester of a concrete under pressure according to any one of claims 1 to 6; When air pressure containing chloride ions is pressurized to the test piece provided in the seating space by the test piece mounting step, air containing chloride ions is supplied to the inlet of the test piece mounting member to pressurize the test piece, A pressure exposing step of supplying seawater to the inlet of the test piece mounting member to pressurize the seawater to the test piece when the water pressure is to be pressurized; Exposing the test piece exposed to the air pressure or water pressure by the pressure exposure step to the test piece mounting member, spraying the reagent reactive with the chloride ion to the divided portion after the rinsing; A chloride ion penetration depth acquiring step of acquiring a chloride ion penetration depth value by measuring a depth of a boundary that has been discolored to white from the surface of the test piece exposed to the reagent in the reagent exposure step; And evaluating the saltiness of the concrete under pressure based on the chloride ion penetration depth value obtained in the step of obtaining the chloride ion penetration depth.

The pressure exposing step may be performed by applying pressure to the test specimen at the air pressure value or the hydraulic pressure value measured after measuring the air pressure or the water pressure at the construction site where the marine concrete structure is to be installed, The air pressure may be applied to the pressure reducing valve, or the pressure reducing and pressuring may be performed periodically.

The reagent may consist of silver nitrate reacting with chloride ions.

The step of acquiring the chloride ion penetration depth may further include the step of measuring the depth from the surface to the boundary at 5 to 9 places at intervals of 10 to 15 mm and then calculating an average value of the depth as a chloride ion penetration depth have.

According to the present invention, a test specimen obtained from a concrete structure expected to be used as a marine concrete structure at a construction site under pressure, or a concrete specimen prepared under the same conditions as a concrete to be used as a marine concrete structure at a construction site under pressure, It is possible to expose to the pressure (air pressure) or the chloride ion (water pressure) in the room, so that it is possible to predict and determine whether or not the marine concrete is salted due to the pressure, as well as to provide an evaluation effect.

In addition, the durability of the marine concrete structure can be predicted in advance by the pressure of the concrete specimen in the room, so that it is necessary to take necessary measures according to the decrease of the durability of the marine concrete structure before the marine concrete structure is applied to the site It is possible to provide an effect that can be achieved.

1 is a schematic view for explaining an apparatus for testing indoor chlorination of concrete under pressure according to a first embodiment of the present invention.
2 is a schematic view for explaining an apparatus for testing indoor chlorination of concrete under pressure according to a second embodiment of the present invention.
3 is a flowchart illustrating a method for evaluating indoor salinity of concrete under pressure according to the present invention.
FIG. 4 is a view for explaining a method of acquiring the chloride ion penetration depth value in the resultant by the indoor chloride testing apparatus of the concrete under pressure according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, the well-known functions or constructions are not described in order to simplify the gist of the present invention.

1 is a schematic view for explaining an apparatus for testing indoor chlorination of concrete under pressure according to a first embodiment of the present invention.

As shown in FIG. 1, the apparatus 10 for testing indoor salinity of a concrete under pressure according to the present invention can be used as a test specimen 20 of a concrete structure to be used as a marine concrete structure or a concrete structure to be used as a marine concrete structure The present invention relates to an apparatus for predicting whether or not a test piece (20) is salted under a pressure by applying air pressure containing chloride ions in a room to a test piece (20) of a concrete structure made of a concrete structure An inlet 32 and an outlet 34 communicating with the seating space 31 so that the air pressure acts on the test piece 20 installed in the seating space 31. The mounting space 31 is provided with the test piece 20, And a pressure applying unit 40 for supplying air containing chloride ions to the inlet 32 of the test piece mounting member 30 and pressing the test piece 20 against the test piece 20, .

This will be described more specifically.

The test piece (20) can be obtained from concrete produced as a condition to be used as a marine concrete structure, or taken from a concrete structure to be used as a marine concrete structure, and can be used as a test piece (20). That is, when the test piece 20 is used in a test on the assumption that it is exposed to an environment in which constant air pressure containing chloride ions is applied, the test piece 20 is taken from a concrete specimen manufactured under the same condition as a marine concrete structure to be installed in such environment A concrete structure to be used as a marine concrete structure, or a marine concrete structure already used and used, or a concrete test piece 20 may be directly manufactured.

The test piece mounting member 30 is constructed such that a test piece 20 made of concrete is seated and fixed and air pressure acts on one surface of the test piece 20. As shown in Fig. 1, a lower seating portion 36A An upper body 37 configured to open downward in a seating space 31 communicating with the inlet 32 and the outlet 34 on both sides of the upper portion; The upper body 37 is attached to the lower body 36 so that the lower surface is hermetically coupled to the upper surface of the lower body 36 so that the upper portion of the test piece 20 is positioned in the seating space 31 in a state in which the test piece 20 is seated. (36). At this time, the pressing portion 38 includes an upper supporting member 38B for supporting the tightening and loosening of the handle, and a lower supporting member 38C for supporting the lower supporting member 38C and the upper supporting member 38B A connecting member 38A and a handle 39 for supporting the upper body 37 against the lower body 36 with a screw portion which is rotatably supported by the upper supporting member 38B so as to be raised and lowered by a tightening and loosening operation .

With this structure, when the handle 39 of the pressing portion 38 is tightened with the test piece 20 placed between the lower body 36 and the upper body 37, the lower body 36 and the upper body 37 are tightened, The seating space 31 in which the one surface of the test piece 20 is exposed is sealed so that the pressure does not leak even if a predetermined pressure (pneumatic or hydraulic pressure) is applied to the seating space 31 It is possible to maintain the sealed state.

In the present embodiment, the test piece mounting member 30 is constructed as described above, but the test piece 20 is placed in a closed space, and a pressure is applied to the closed space so that a predetermined pressure is applied to the test piece 20 ) Can also be applied.

The pressure applying section 40 pressurizes the air containing the chloride ion into the seating space 31 in which the test piece 20 is installed under a predetermined pressure so that the air containing the chloride ion is pressurized at a predetermined pressure, (42) having a pressure gauge (43) and adapted to receive seawater and air in the containing space (S1), and an air pressure generator And the pressure applied to the air chamber 42 provided between the air compressor 44 and the air chamber 42, that is, the pressure applied to the seat space 31 And a pressure regulator 46 for regulating the pressure applied to the pressure regulator.

The pressure application unit 40 may further include a pressure reducing valve 48 installed between the pressure regulator 46 and the air chamber 42 to reduce the pressure of the accommodation space S1. The valve 48 is for reducing the pressure inside the air chamber 42 and is used only when the pressure inside the air chamber 42 is depressurized or reduced.

A recovery line 45 for recovering the air discharged from the seating space 31 to the air chamber 42 is provided with a recovery valve 45A at the exit of the seating space 31, 31 is provided with a supply line 47 for supplying air from the air chamber 42 to the inlet 32. An open / close valve 47 may be provided in the supply line 47.

On the other hand, the air compressor 44 and the pressure regulator 46 of the pressure application unit 40 are controlled by a control unit 50 having a timer 52. That is, the control unit 50 is configured to control the air compressor 44 and the pressure regulator 46 so as to pressurize the compressed air with a constant pressure for a predetermined time. At this time, when the pressure-applying unit 40 is provided with the pressure-reducing valve 48, the air compressor 44, the pressure regulator 46, and the pressure-reducing valve 48 are controlled so that the pressurization and the depressurization are periodically repeated for a predetermined period of time. .

In the case of the test on the assumption that the test piece 20 is exposed to an environment in which a constant air pressure is applied, the air compressor 44 and the pressure regulator 46 are controlled so as to pressurize the compressed air at a constant pressure for a predetermined period of time The pressure regulator 46 and the pressure regulator 46 are controlled such that the pressure and the pressure are periodically repeated for a predetermined period of time when the test piece 20 is subjected to a test under the assumption that the test piece 20 is exposed to an environment in which the pressure is reduced and / And controls the pressure reducing valve (48).

The operation process of the indoor chlorination testing apparatus 10 of the concrete under the pressure thus constructed will be described.

First, the test piece 20 is installed in the seating space 31 of the test piece mounting member 30 when the test piece 20 made of concrete is exposed to an environment in which a constant air pressure is applied.

Subsequently, when the control unit 50 actuates the pressure applying unit 40, the air compressor 44 is operated to supply the compressed air to the air chamber 42, so that the pressure inside the air chamber 42 rises . At the same time, since the air chamber 42 and the inlet 32 are connected by the supply line 47 to the seating space 31, the pressure in the seating space 31 also increases.

At this time, the air supplied to the seating space 31 is the air contained in the air chamber 42 like seawater, and the air continuously supplied by the air compressor 44 is also supplied to the receiving space S1 So that the air supplied to the seating space 31 contains chloride ions. Therefore, the air containing the chloride ion acts on the test piece 20 at a predetermined pressure.

The chloride ion contained in the air penetrates into the surface of the test piece 20 as the above process is applied at a predetermined pressure for a predetermined time.

After the process is completed, the test piece 20 is separated from the test piece mounting member 30, and the reagent reactive with chloride ions is sprayed onto the test piece 20 to measure the depth (D) of the boundary BL that is discolored by the reagent . Through these measurement results, it is possible to predict and understand how much the specimen 20 undergoes a certain degree of salt damage.

On the other hand, when the test is performed on the assumption that the test piece 20 is exposed to an environment in which the air is pressurized and depressurized by a constant air pressure, a salt corrosion test apparatus 10 provided with a pressure reducing valve 48 is used. That is, the control unit 50 controls the timer 52 to periodically perform the depressurization and the depressurization at a predetermined pressure for a predetermined period of time. This process makes it possible to predict the salinity of marine concrete structures exposed to the environment in which chloride ion-containing air is pressurized and decompressed.

2 is a schematic view for explaining an apparatus for testing indoor chlorination of concrete under pressure according to a second embodiment of the present invention.

As shown in FIG. 2, the apparatus 10 for testing indoor chlorination of concrete under pressure according to the second embodiment is configured such that the pressure applying unit 40 supplies seawater to a test piece 20 provided in the seating space 31 So as to pressurize the water pressure.

That is, the pressure application unit 40 includes a seawater chamber 42 configured to receive seawater in the receiving space S1, and a seawater supply unit 40 configured to supply the seawater in the receiving space S1 to the inlet 32, And a seawater pump (49) for acting on the test piece (20).

Therefore, when the seawater pump 49 is operated by the control unit 50, the seawater is supplied to the seating space 31 at a predetermined pressure for a predetermined time to act on the test piece 20, The chloride ion penetrates into the surface of the test piece 20 and the penetration depth of the chloride ion is measured in the test piece 20 at a later time to determine whether the test piece 20 exposed to the seawater of the predetermined pressure region is salt- It is possible to grasp the degree.

That is, by operating the seawater at a predetermined pressure on the test piece 20, it becomes possible to predict the environment exposed to the seawater, that is, the salinity of the marine concrete structure exposed to the water pressure installed in the sea.

Hereinafter, a method for evaluating the indoor salinity of concrete under pressure in the room using the indoor salinity tester 10 of the concrete subjected to the pressure as described above will be described with reference to FIG. 1 to FIG.

. The test specimen collection or production step (ST1)

The test specimen (20) is to be taken from the concrete manufactured to be used as a marine concrete structure, or the test specimen (20) is taken from the concrete structure to be used as a marine concrete structure. At this time, the concrete test body may be directly manufactured and used as the test piece 20.

. Test piece installation step (ST2)

The test piece 20 collected in the above-described test piece picking or production step ST1 is installed and fixed in the seating space 31 provided in the test piece mounting member 30 of the above-described salinity test device 10. That is, after the test piece 20 is installed between the lower body 36 and the upper body 37, the upper body 37 and the lower body 36 are brought into close contact with each other by operating the handle 39 of the pressing portion 38 . In this process, the rest space 31 is sealed except for the inlet 32 and the outlet 34, so that compressed air or seawater is not leaked.

Next, the recovery line 45 is connected to the outlet 34 and the air chamber 42, and the supply line 32 is connected to the inlet 32 and the air chamber 42. One end of the supply line 32 connected to the air chamber 42 is connected to the upper side of the accommodation space S1 so that seawater is not discharged into the seating space 31 when pressure is applied to the air chamber 42. [

. The pressure exposure step (ST3)

When the test piece 20 is installed in the test piece mounting step ST2 and air pressure including chloride ions is to be applied to the test piece 20 provided in the seating space 31, the pressure applying unit 40 is operated Air containing chloride ions contained in the air chamber 42 is supplied to the inlet of the test piece mounting member 30 and is pressed against the test piece 20. [ That is, when air containing chloride ions is pressurized into the seating space 31, air containing chloride ions acts on the surface of the test piece 20 at a predetermined pressure, and after a predetermined time has elapsed, 34 is opened, the air in the seating space 31 is discharged to the air chamber 42 through the recovery line 34.

This process is carried out by the control unit 50, and the chloride ions contained in the air penetrate into the surface of the test piece 20.

On the other hand, when the sea water is supplied to the seating space 31 provided with the test piece 20 at a predetermined pressure to pressurize the test piece 20, as shown in FIG. 2, the sea water pump 49 is operated, The seawater is supplied to the inlet 32 of the seating space 31 of the mounting member 30 to cause the test piece 20 to operate at a predetermined pressure.

 The control unit 50 controls the air compressor 44, the pressure regulator 46, and the pressure reducing valve 48 in the case where the air containing chloride ions is to be repeatedly pressed and depressurized periodically in the test piece 20 So that the pressure inside the seating space 31 is pressurized and reduced. In this process, the air containing chloride ions is pressurized and depressurized in the test piece 20 installed in the seating space 31 for a predetermined period of time.

In this pressure exposing step S3, pressure is applied to the test piece 20 by the air pressure value or the water pressure value measured after the air pressure or the water pressure at the construction site where the marine concrete structure is to be installed, In this case, it may further include the step of applying air pressure or periodically applying the depressurization and pressurization for the set time. This is to understand and predict the salinity that will occur in the environment of the construction site where the marine concrete structure will be installed.

. The reagent exposure step (ST4)

The test piece 20 exposed to the air pressure or the water pressure by the above-described pressure exposure step ST3 is separated from the seating space 31 of the test piece mounting member 30, and the reagent reacting with the chloride ion, That is, 0.1 N silver nitrate (AgNO 3) is sprayed to react.

In this process, the area where the chloride ions penetrate is discolored from the surface to white, and silver chloride (AgCl) is produced.

. Chloride ion penetration depth acquisition step (ST5)

The chloride ion penetration depth value is obtained by measuring the depth (D) of the boundary (BL) discolored to white from the surface of the test piece (20) exposed to the reagent in the reagent exposure step (ST4).

At this time, the depth from the surface of the test piece 20 to the boundary BL is measured at intervals of 10 to 15 mm at intervals of 5 to 9, and the average value of the depth (D) is calculated as the chloride penetration depth. That is, as shown in FIG. 4, the distance from the non-regular boundary BL to the surface is measured at several places, and the average value is obtained as a chloride ion penetration depth value.

. In the seawater evaluation step (ST6)

Based on the chloride ion penetration depth value obtained in the step (ST5) of acquiring the chloride ion penetration depth described above, the salt corrosion of the pressed concrete is evaluated. In other words, it is possible to predict the saltiness and shape of the marine concrete structure to be applied to the pressure receiving environment based on the time of exposure to the pressure and the chloride penetration depth. Based on the predicted salinity information, measures for supplementing and reinforcing the durability of the marine concrete structure to be installed in the ocean can be taken in advance.

. Test Example

Different concrete specimens were exposed to pressures of 2-6 bar for 1-3 days in order to predict and evaluate the chloride attack of marine concrete structures affected by pneumatic or hydraulic pressure. This test was conducted by varying the magnitude of the pressure and the exposure time on the concrete specimen.

The results are shown in Table 1 below.

Size of pressure (bar) The pressure applied time (time) Penetration depth of chloride ion (mm) 2 24 0.80 2 72 1.13 6 24 1.29 6 72 1.49

At this time, the concrete specimen used for the test was f _ck = 35 MPa (W / C 38.2%).

As can be seen in Table 1 above, the penetration depth of the chloride ion can be predicted by the magnitude of the pressure and the time of exposure to the pressure.

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, It is obvious to those who have. Accordingly, it should be understood that such modifications or alterations should not be understood individually from the technical spirit and viewpoint of the present invention, and that modified embodiments fall within the scope of the claims of the present invention.

10: Salting test device 20: Test piece
30: specimen mounting member 31: mounting space
32: inlet 34: outlet
40: pressure-applying part 42: air chamber, seawater chamber
44: air compressor 46: pressure regulator
48: Pressure reducing valve 49: Seawater pump
50: control unit 52: timer
S1: accommodation space D: depth
BL: Boundary

Claims (10)

A lower body having a lower seating portion formed on an upper surface thereof, an upper body communicating with an inlet and an outlet on both sides of the upper portion and configured to open a seating space for seating a test piece made of concrete, Each of the connecting members connecting the lower supporting member and the upper supporting member, and a screw portion which is rotatably supported by the upper supporting member and is raised and lowered by a tightening and unclamping operation so as to press the upper body to the lower body The upper portion of the test piece is positioned in the seating space in a state where the test piece is seated on the lower seating portion including the handle and the upper body is pressed toward the lower body so that the bottom surface is hermetically coupled to the upper surface of the lower body And a pressurizing portion, wherein a test piece having air pressure applied to the test piece provided in the seating space is mounted absence;
And a pressure applying unit configured to pressurize the test piece by supplying air containing chloride ions to an inlet provided in the upper body of the test piece mounting member,
Wherein the pressurizing unit includes an air chamber configured to receive seawater and air in an accommodating space such that chlorine ions are contained in the accommodating air when the air containing chloride ions is pressurized on the test piece provided in the seating space; An air compressor for generating air pressure to supply the air in the accommodation space to the inlet to act on the test piece; A pressure regulator installed between the air compressor and the air chamber for regulating pressure; And a pressure reducing valve installed between the pressure regulator and the air chamber for reducing the pressure of the accommodation space. In the case of a test on the assumption that the test piece is exposed to an environment in which a constant air pressure acts, , The air compressor and the pressure regulator are controlled so as to pressurize the compressed air at a constant pressure during the test. When the test piece is exposed to an environment in which the test piece is pressurized and decompressed at a constant air pressure, pressurization and decompression are periodically Further comprising a controller for controlling the air compressor, the pressure regulator and the pressure reducing valve to be repeated,
A recovery line for recovering the air discharged from the seating space to the air chamber is provided at an exit of the seating space, and an inlet of the seating space is provided with air from the air chamber to the inlet Characterized in that a feed line
Indoor salt testing equipment for concrete under pressure. delete delete delete delete delete It is a method for predicting, evaluating and evaluating whether or not the concrete under pressure is salted.
Sampling or production of test specimens from concrete prepared for use as an offshore concrete structure, preparing concrete specimens directly, or extracting specimens from concrete structures to be used as an offshore concrete structure;
A test piece mounting step of installing and fixing the test specimen collected in the test specimen collection step in a seating space provided in a specimen mounting member of an indoor salinity test apparatus for concrete according to claim 1;
When the air pressure including the chloride ion is pressurized to the test piece provided in the seating space by the test piece mounting step, the air pressure at the construction site where the marine concrete structure is to be installed is measured, A pressure exposing step of receiving air containing chloride ions as seawater in a receiving space of the air chamber through an inlet, pressurizing the air containing chloride ions to the test piece, and recovering air discharged from the seating space to the air chamber;
Exposing the test piece exposed to the air pressure by the pressure exposure step to the test piece mounting member, spraying silver nitrate as a reagent reactive with the chloride ion on the divided part;
The depth from the surface of the test piece exposed to the reagent to the boundary of the white discoloration at the reagent exposure step was measured at 5 to 9 intervals at intervals of 10 to 15 mm, and the average value of the depth was calculated as the chloride ion penetration depth value Obtaining a chloride ion penetration depth; And
And evaluating the salinity of the pressed concrete based on the chloride ion penetration depth value obtained in the chloride ion penetration depth obtaining step.
Evaluation Method of Indoor Chloride in Concrete under Pressure. delete delete delete

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