KR20130095501A - Thermophyscal properties measuring appratus of concrete and method for the same - Google Patents

Abstract

PURPOSE: A thermophysical amount testing apparatus and a method thereof are provided to transfer heat to a concrete sample by using hot water, thereby testing the thermophysical amount, such as the thermal conductive condition of concrete and the like. CONSTITUTION: A thermophysical amount testing apparatus includes a chamber (110) and a measuring machine. The chamber includes a curing space in which a concrete sample (100) is cured. The measuring machine is arranged on the concrete sample that is cured in the chamber.

Description

Thermophyscal properties measuring appratus of concrete and method for the same

The present invention relates to the field of construction and civil engineering, and more particularly, to an apparatus and a method for testing a thermal physics such as thermal conductivity of concrete.

Concrete is used as a major material for civil engineering and construction structures. It is a mixture of cement, sand, gravel, aggregate, etc., and kneading in water. Therefore, since concrete may vary in characteristics depending on the type of constituent materials, the mixing ratio, etc. of the concrete mixture, there is a great demand for the development of various materials according to the use. In particular, the concrete used as the material of the wall is required to develop a thermal insulation concrete having excellent thermal insulation to block the transfer of heat inside and outside through the wall.

However, if the newly developed concrete is used as the material of the actual structure and the site verification is very risky for the reliability of the newly developed concrete, the evaluation of the characteristics of the developed concrete before the actual use of the newly developed concrete is very large. And verification is required. In other words, in the case of insulating concrete, it is necessary to evaluate and verify the reliability of the insulating performance through a test approach on the thermal physics such as the thermal conductivity.

Therefore, there is an urgent need for a method of evaluating and verifying the thermal insulation performance of newly developed concrete by an experimental method instead of field verification.

1 is a block diagram of a heat physical quantity test of concrete according to the prior art, in the prior art by placing the heating wire 20 on one surface of the concrete specimen 10 to the heat generated from the heating wire 20 concrete specimen 10 After transferring to the temperature of the concrete specimen 10 was measured through a temperature sensor.

However, in the conventional case, since the measured value fluctuation is very large according to the dryness, the moisture content, etc. of the surface of the concrete specimen 10, the temperature of the heating wire 20 may be adjusted so that the measurement may be performed in the dried state of the concrete specimen 10. There is no choice but to set a very high temperature of 100 degrees or more, and while checking the moisture content of the concrete specimen 10 together, the measurement is made several times while changing the moisture content.

Therefore, an empirical test is not possible, and it is pointed out that problems due to several tests are not only troublesome but also low in reliability, and have a high possibility of a safety accident due to high temperature.

In addition, the concrete specimen 10 has been pointed out a problem that a uniform test is not possible due to the difference in heat transfer rate between the portion in contact with the hot wire 20 and the non-contact portion.

The present invention has been made to solve the above problems, and provides an apparatus and method for testing the thermal physics of concrete made to test the thermal physics, such as the thermal conductivity of the concrete by transferring heat to the concrete specimen using hot water. The purpose.

In order to solve the above problems, the present invention provides a curing space 111 is a concrete specimen 100 is cured, the chamber 110 for transferring heat by hot water to the cured concrete specimen (100); Thermal physics of the concrete comprising a; measuring unit 120 is fixed to the concrete specimen 100, which is cured in the chamber 110, and measures the thermal physics of the concrete specimen 100 to which heat is transferred after curing. Test equipment can be presented.

The chamber 110 may be formed of a metal material, and may include a main body part 110a formed in a rectangular box shape so that the upper surface thereof has an open curing space 111.

The chamber 110 may further include a cover part 110b covering the open upper surface of the main body part 110a so that the curing space 111 may be sealed, or the chamber 110 may be sealed. It may further include an outer case 130 formed with a space.

The chamber 110 may have a hot water circulation space 114 in which hot water is circulated so as to transfer heat to the concrete specimen 100 in portions along two directions of the concrete specimen 100.

The chamber 110 may have a cold / hot water circulation space 116 in which hot water or cold water is circulated in a portion opposite to a portion where the hot water circulation space 114 is formed around the concrete specimen 100.

The chamber 110 may include a protrusion 112 protruding from the curing space to be embedded in the concrete specimen 100 in a portion where the hot water circulation space 114 is formed.

The chamber 110 may include a protrusion 112 protruding from the curing space to be embedded in the concrete specimen 100.

The chamber 110 may include a plurality of chamber members that are coupled to be separated from each other to form the curing space 111.

The measuring unit 120 includes a sensor 122 for measuring the thermal physics of the concrete specimen 100; It may include a sensor support 124 is formed over the chamber 110, the sensor mounting portion 124a is formed so that the sensor 122 is installed so that the sensor 122 can be fixed to the concrete specimen (100) have.

The sensor support part 124 may have a plurality of sensor installation parts 124a formed along the heat transfer direction.

The measuring instrument 120 may include a sensor 122 that measures a thermal physics amount of the concrete specimen 100, and the sensor 122 may include a heat probe.

The heat probe may include a thermoster.

The sensor 122 may further include a thermocouple.

In addition, the present invention provides a specimen preparation step of curing the concrete specimen 100, and fixing the sensor 122 for measuring the thermal physics of the concrete specimen 100 on the concrete specimen 100; After the specimen preparation step, by measuring the heat physical quantity of the concrete specimen 100 through the sensor 122 by transferring heat to the concrete specimen 100 using hot water; concrete comprising a The thermal physics test method can be suggested.

Curing of the concrete specimen 100 may be made by a chamber 110 capable of transferring heat to the concrete specimen 100.

In the measuring step, the medium for heat transfer may be made of hot water circulation.

The present invention can provide a thermal physical quantity test apparatus for concrete that can test the thermal physical quantity, such as the thermal conductivity of the concrete. In particular, according to the present invention, as the hot water is used to transfer heat to the concrete, the thermal physics of the concrete can be tested at room temperature conditions of the actual concrete structure without being affected by surface dryness, moisture content, etc. of the concrete specimen. The reliability of the test evaluation and verification is excellent. In addition, the present invention enables the empirical test because it controls the temperature of both concrete specimens individually.

1 is a schematic diagram of a thermal physics test method for concrete specimens according to the prior art.
2 or less relates to a thermal physics test apparatus for concrete specimens according to the present invention,
2 is a side view.
3 is a perspective view of a main body of the chamber;
4 is a plan view of a combined state of a chamber and a measuring instrument.
5 is an exploded perspective view of the sensor support;

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

In the following description of the present invention, a detailed description of known functions and configurations will be omitted so as not to obscure the gist of the present invention.

As shown in Figure 2, the thermal physics test method of concrete of the present invention, the thermal physics, such as thermal conductivity, temperature of the concrete specimen 100 to the concrete specimen 100 cured for the test for the thermal physics test basically Fixing the sensor 122 to measure the, transfer the heat to the cured concrete specimen 100 and measures the thermal physics of the concrete specimen 100 through the sensor 122.

In particular, the present invention may be characterized in that the sensor 122 when curing the concrete specimen 100 is inserted into the concrete specimen 100 to be cured. Therefore, since the bonding property between the concrete specimen 100 and the sensor 122 is excellent, the heat physics of the concrete specimen 100 may be accurately measured through the sensor 122. In addition, as the sensor 122 is settled in the curing process of the concrete specimen 100, it is not necessary to perform a separate operation (for example, drilling work) for fixing the sensor 122 can be easily made.

In addition, the present invention can provide a heat physical quantity test device of the following concrete so that the heat physical quantity test of the above-described concrete can be easily made. The thermal physical quantity test apparatus of the concrete is a curing space 111 is the curing of the concrete specimen 100 is formed, the chamber 110 for transferring heat to the cured concrete specimen 100; It may be settled in the concrete specimen 100, which is cured in the chamber 110, the measuring unit 120 for measuring the heat physics of the concrete specimen 100, the heat transfer after curing.

That is, since the chamber 110 can serve as a form for curing the concrete specimen 100 and a heat transfer medium for transferring heat to the concrete specimen 100, in order to cure the concrete specimen 100 and transfer heat. There is no need to move the concrete specimen 100, so the overall configuration and testing of the test apparatus is simplified. In addition, since the heat transfer through the chamber 110 can be made face-to-face, heat transfer to the concrete specimen 100 can be made uniformly and quickly as a whole. In addition, the meter 120 can be easily and stably supported by the chamber 110 during concrete curing and thermal physics measurement.

In particular, the chamber 110 may be formed of a metal material such as aluminum or steel to facilitate heat transfer.

Since the chamber 110 is formed of a metal material, shear is easily generated between the concrete specimen 100 and the curing space so that the chamber 110 may be buried in the concrete specimen 100 to strengthen the binding force with the concrete specimen 100. It may include a protrusion 112 protruding in.

In particular, the protrusion 112 is formed in a portion where the hot water circulation space 114 of the chamber 110 is formed, as will be described later, and heat transfer to the concrete specimen 100 also through the protrusion 112 embedded in the concrete specimen 100. This can be made, and thus heat transfer by the protrusion 112 can be made easier and faster.

The chamber 110 may be configured to include a plurality of chamber members that are coupled to be separated from each other to form the curing space 111, thereby taking advantage of the assembly type, and also only a part of the chamber 110 That is, the hot water circulation space 114 may be formed only in some chamber members of the plurality of chamber members. The chamber 110 may have a hot water valve 114a for hot water in and out of the hot water circulation space 114.

The chamber 110 may include a body portion 110a formed in a box shape so as to have a curing space 111 having an upper surface open so that the concrete placing and the fixing of the meter 120 are stable and simple as will be described later. The body part 110a of the chamber 110 may be formed in a rectangular box shape so that the concrete specimen 100 may be cured in a wall-like shape in consideration of being generally used as a wall in the case of insulating concrete.

In addition, the chamber 110 may further include a cover part 110b covering the open upper surface of the main body part 110a so that the curing space 111 may be sealed, or the sealed space into which the chamber 110 is inserted is provided. It may be sealed by the outer case 130 formed. In addition, the chamber 110 may minimize the influence of external temperature by using urethane foam.

The chamber 110 is a hot water circulation in which hot water is circulated by a hot water pump to transfer heat to the concrete specimen 100 in a portion along the circumferential direction of the concrete specimen 100 for the thermal physics test of the concrete specimen 100. Space 114 may be formed. Therefore, since the heat transfer by the hot water is uniformly made on the front surface of the hot water circulation space 114, heat can be uniformly transferred to the concrete specimen 100 as in the field, so that excellent test reliability can be expected. In addition, since the measured value does not vary depending on the surface dryness, moisture content, etc. of the concrete specimen 100 as the test is performed in a space enclosed by the chamber 110 using hot water, the test can be performed at one time. The reliability is very good. In addition, since it is not necessary to consider the effects of surface dryness, moisture content, etc. of the concrete specimen 100, it is possible to use hot water at room temperature (for example, approximately 50 ℃), thereby allowing the heat transfer at room temperature as in the field Empirical testing can be expected and the risk of safety accidents can be avoided. In addition, by using hot water of approximately 50 ℃, it is an easily accessible medium and easy to handle it may be advantageous in terms of manufacturing and maintenance costs, usability and the like.

In addition, the chamber 110 may further include a cold / hot water circulation space 116 in which hot water or cold water is circulated in a portion opposite to a portion where the hot water circulation space 114 is formed around the concrete specimen 100. The chamber 110 may have a cold / hot water valve 116a for cold / hot water in and out of the cold / hot water circulation space 116.

That is, heat transfer may be made at both sides of the concrete specimen 100. Therefore, both sides of the concrete specimen 100 is heat transfer by hot water, but the hot water temperature of both sides can be the same or different. In addition, the thermal insulation concrete will be used a lot in the indoor and outdoor temperature difference, such as winter, bar one side of the concrete specimen 100 transfers the heat by the hot water to the indoor conditions, the other side of the concrete specimen 100 is the outdoor conditions By cooling with cold water, the same empirical test can be expected.

Measuring instrument 120 is a sensor 122 for measuring the thermal physics of the concrete specimen 100, the sensor 122 is installed on the chamber 110, so that the sensor 122 can be fixed to the concrete specimen 100 It may include a sensor support 124 is formed sensor mounting portion 124a. The sensor 122 may include a heat probe 122a for measuring thermal conductivity and a thermocouple 122b for measuring temperature. The heat probe 122a includes a thermistor capable of measuring resistance and temperature for heat generation, particularly inside a stainless steel probe, and may have a resin-filled configuration.

The sensor installation unit 124a may only be spanned over the chamber 110 because the sensor 122 may be fixed and fixed to the concrete specimen 100, or may be attached or detached to the chamber 110 by fastening bolts or pins. Can be combined as much as possible.

The sensor installation unit 124a may have any structure as long as it can support the sensor 122. Preferably, the sensor installation unit 124a may be separated in two so that the sensor 122 may be easily installed in the sensor installation unit 124a. It can be made of a separate structure that can be integrally bound to each other by). The sensor installation unit 124a may be formed of a groove penetrated vertically so that the tip of the sensor 122 may be embedded in the concrete specimen 100.

 In particular, the sensor supporter 124 may be formed in a plurality of sensor installation units 124a along the heat transfer direction such that at least a plurality of thermocouples 122b may be installed along the heat transfer direction. Therefore, by installing a plurality of sensors 122 along the heat transfer direction in the sensor support 124, the heat conduction pattern according to the heat transfer direction can be represented by a graph, etc., the type, thickness, sensor 122 of the concrete specimen 100 The position where the sensor 122 is installed among the plurality of sensor installation units 124a can be changed according to the type.

Only one type of sensor 122 may be installed in one sensor support 124, or a plurality of types of sensors 122 may be installed together. Only one sensor support 124 may be configured on the chamber 110, or two or more sensors may be configured.

Referring to the test process of the present invention in more detail as follows.

The method of measuring the thermal conductivity is to measure the energy in which a constant heat source supplied is conducted inside the material, and there are a probe method in which the sensor is inserted into the material and a surface method in which the sensor is attached to the surface. In the case of the surface method, the contact between the material surface and the sensor should be good, and the external temperature and material flatness affect the measured value. The probe method has an advantage of minimizing external influence factors because the sensor is inserted inside the material and the heat source and the temperature measuring point are in the same position. The method of measuring probes generally follows the ASTM D5344-00 Standard test method fordetermination of thermal conductivity of soil and soft rock by thermal needle probe procedure. The resistance is generated by supplying a constant current, and the temperature value changing accordingly is measured over time to obtain a temperature rise curve over time as shown in the graphs of FIGS. 6 and 7.

The time-temperature gradient obtained in FIGS. 6 and 7 is converted into the following thermal conductivity (k) equation.

Thermal conductivity formula

Here, Q is determined by the current I measured by the energy applied to the resistance and the standard resistance Rm value (about 1050 ohms) inside the probe. t is the time and T is the temperature at that time t. In the temperature curve over time, the initial value is required to heat the probe, and the point where the temperature converges is affected by the boundary conditions, so the linear part in the middle is taken as the slope. The total measurement time is about 2-3 minutes, and the slope can be calculated collectively using the temperature varied from 15 to 55 seconds.

As described above, the test principle of the present invention using the heat probe 122a is as follows.

The method by the heat probe 122a is a method of conducting heat from a linear heat source to a surrounding material and measuring thermal conductivity based on the measured temperature value. In the case of concrete material, it may be assumed that the continuum is macroscopically, but since the size of the aggregate used is in cm, the conductivity value obtained by the method by the heat probe 122a indicates the characteristics of the local material. Therefore, the thermal conductivity at the continuum scale can be calculated using the planar heat source method.

In the hot plate experiment as described above, a temperature rise occurs from a point close to the heat source, and the time-temperature curve at each thermocouple 122b position shows a specific aspect depending on the material used for the measurement. When the temperature increases sequentially as the heat energy propagates and there is no heat loss, the temperature at all the thermocouples 122b positions converge to the same point as the temperature of the hot plate. In addition, since the time-temperature pattern propagated differently for each measurement position depends on the thermal diffusion property of the material, the thermal energy generation and the thermal property evaluation by the time-temperature profile are the same as described above. According to this method, it is possible to observe the temperature increase pattern according to the actual wall depth, and the aggregate size is considerably smaller than the mold size, which is useful for acquiring thermal conductivity from a macroscopic perspective without affecting the aggregate size and spatial position arrangement.

Specific test methods may be made as follows.

After pre-heating the temperature control fluid circulator to a certain temperature (for example, 60 degrees in this experiment), it is circulated inside the hot plate to maintain a constant temperature, and then the hot plate is heated for about three days per specimen to supply a constant energy. Temperature values are recorded every 10 seconds in the sequentially arranged thermocouple 122b. 8 and 9 show the temperature increase pattern with time for each thermocouple position.

Referring to FIGS. 8 and 9, when the time is viewed linearly, the initial temperature increase time is not clear according to the position of the thermocouple 122b, whereas the temperature value converged according to the thermocouple position after a long time is different. Can be. This is a phenomenon in which the heat loss accumulates as the distance from the hot plate increases and does not converge to the same temperature as the hot plate. When the time is converted into a log, the initial temperature rise time increases differently depending on the position of the thermocouple 122b. . In other words, it can be seen that the minimum temperature increase time varies depending on the thermal properties of the material.

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.

100; Concrete specimen 110; chamber
110a; Main body 110b; The lid portion
112; Protrusion 114; Hot water circulation space
120; Meter 122; sensor
124; Sensor support

Claims (16)

A curing space 111 in which the concrete specimen 100 is cured is formed, and the chamber 110 transfers heat to the cured concrete specimen 100 by hot water;
A meter 120 that is fixed to the concrete specimen 100 cured in the chamber 110 and measures the thermal physics of the concrete specimen 100 to which heat is transferred after curing;
Heat physical quantity test apparatus for concrete, comprising a. The method according to claim 1,
The chamber 110 is formed of a metal material, the thermal physical quantity test apparatus of the concrete, characterized in that it comprises a main body portion (110a) formed in a rectangular box shape so as to have an open curing space (111). The method according to claim 2,
The chamber 110 may further include a cover part 110b covering the open upper surface of the main body part 110a so that the curing space 111 may be sealed, or the chamber 110 may be sealed. Heat physical quantity test device for concrete, characterized in that it further comprises a space formed outer case (130). The method according to claim 1,
The chamber 110 of the concrete, characterized in that the hot water circulation space 114 is formed in a portion along the two directions of the concrete specimen 100, the hot water is circulated so as to transfer heat to the concrete specimen 100 Heat physical quantity test device. The method of claim 4,
The chamber 110 of the concrete, characterized in that the hot and cold water circulation space 116 is formed on the opposite side of the hot water circulation space 114 is formed around the concrete specimen 100, the hot water or cold water is circulated Heat physical quantity test device. The method of claim 4,
The chamber 110 is a thermal physical quantity test apparatus for the concrete, characterized in that it comprises a protrusion 112 protruding in the curing space to be embedded in the concrete specimen 100 in a portion where the hot water circulation space 114 is formed . The method according to claim 1,
The chamber 110 is a thermal physical quantity test apparatus of the concrete, characterized in that it comprises a protrusion 112 protruding in the curing space to be embedded in the concrete specimen (100). The method according to claim 1,
The chamber 110 is a thermal physical quantity test apparatus for concrete, characterized in that it comprises a plurality of chamber members are coupled to be separated from each other to form the curing space (111). The method according to any one of claims 1 to 8,
The measuring unit 120 includes a sensor 122 for measuring the thermal physics of the concrete specimen 100;
It includes a sensor support 124 is formed over the chamber 110, the sensor mounting portion 124a is formed is installed so that the sensor 122 is fixed to the concrete specimen (100) Heat physical quantity test device for concrete. The method according to claim 9,
The sensor support part 124 is a heat physical quantity test device for concrete, characterized in that a plurality of the sensor installation portion (124a) is formed along the heat transfer direction. The method according to any one of claims 1 to 8,
The measuring device 120 includes a sensor 122 for measuring the thermal physics of the concrete specimen 100, the sensor 122 is a thermal physics test device of the concrete, characterized in that it comprises a heat probe (122a) . The method of claim 11,
The thermal probe (122a) is a thermal physical quantity test apparatus for concrete, characterized in that it comprises a thermoster. The method of claim 11,
The sensor 122 is a thermophysical amount test device of the concrete, characterized in that it further comprises a thermocouple (122b). A specimen preparation step of curing the concrete specimen 100 and fixing the sensor 122 to measure the heat physical quantity of the concrete specimen 100 on the concrete specimen 100;
A measurement step of measuring heat physical quantity of the concrete specimen 100 through the sensor 122 by transferring heat to the concrete specimen 100 after the specimen preparation step;
Heat physical quantity test method of concrete, characterized in that it comprises a. The method according to claim 14,
Curing of the concrete specimen 100 is a heat physical quantity test method of the concrete, characterized in that made by the chamber 110 to transfer heat to the concrete specimen (100). The method according to claim 14,
In the measuring step, the medium for heat transfer is a heat physics test method of concrete, characterized in that made of hot water circulation.

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