KR20150140552A - All-in-one test apparatus for calculating fire-property of matter - Google Patents

Abstract

Disclosed is an all-in-one test device to calculate a fire property comprising: a main body having a base unit; a cone-shaped heat flux application device covering a large area installed in the main body which generates and provides radiant heat to a sample for combustion; a mass reduction measurement device installed in a base unit which measures reduction of mass while a sample is combusted; a temperature measurement device for the sample installed in a heat flux application device covering a large area which measures a temperature of the sample; and a sample holder installed in an upper part of the mass reduction measurement device to accommodate and combust the sample.

Description

{ALL-IN-ONE TEST APPARATUS FOR CALCULATING FIRE-PROPERTY OF MATTER}

The present invention relates to an all-in-one test apparatus for calculating fire physical properties, and more particularly to an all-in-one fire test apparatus for measuring fire physical properties such as building / life materials.

The change of residence to the skyscraper and underground space caused by the rapid urbanization in the modern society is increasing the damage of the fire accidents that have occurred recently. The economic loss and the casualties caused by this are increasing day by day.

In order to reduce the damage to the fire, researches can be divided into real fire research, miniature model experiment and fire simulation study through computer simulation.

The best way to assess the dangers of real fire is to simulate or implement real-life fire conditions. However, it has disadvantages of cost and time and second environmental pollution problem caused by experiment.

Therefore, cone calorimeter method is used as a method to substitute real-time fire by burning the unit material firstly as a method for replacing such time and cost. First, a small 100 × 100 mm material is used for heat release rate and smoke production rate (SPR).

However, accurate results can not be obtained unless the environmental and structural interpretations of real fire occur.

Second, a fire numerical analysis program has been developed, and there is the Fire Dynamics Simulator (FDS) of NIST in USA. Using the fire simulation, you can freely change the environment and the parameters without causing any environmental problems. However, it is not possible to input accurate values for the material and the environment, or the result of the experiment may be different due to the problem of the program itself.

Third, the NIST FDS model requires material properties such as fuel ratios, heat of combustion, heat of reaction, conductivity, specific heat, and thermal decomposition rate constants for each material . However, in the case of actual materials, the properties obtained in the literature are extremely limited, so it is very difficult to input appropriate physical properties in the simulation of fire. In addition, there is no information on the thermal properties of synthetic materials and new materials. In order to solve these problems, researches have been actively conducted to inversely estimate the thermal properties through inverse problem analysis based on the results of laboratory scale cone calorimeter experiments.

In the present invention, in performing the pyrolysis fire simulation based on the above three studies, it is possible to obtain the material properties and the like of the necessary materials through the reduction experiments, and a new concept test apparatus .

Korean Patent No. 10-0686374 Korean Patent No. 10-0629150

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a method and apparatus for measuring new data such as heat release rate, smoke generation rate and temperature data obtained through a cone calorimeter test on a laboratory scale, The purpose of this study is to provide an all-in-one fire test system which can extract the input data required for fire simulation. It will contribute to the improvement of reliability by making it possible to apply cost reduction and reliability of fire simulation in various fields such as designing fire safety performance of buildings, numerical analysis of fire vehicle growth of railway vehicles, fire detection field and railway fire safety design. do.

In order to accomplish the above object, according to the present invention, there is provided a fire physical property all-in-one testing apparatus comprising: a main body having a base; A large-area heat flux applying device installed in the apparatus main body and generating and supplying radiant heat to the specimen to be burned, and having a cone shape; A mass reduction rate measuring device installed in the base and measuring a mass of the specimen during combustion; A specimen temperature measuring device installed in the large area heat flux application device and measuring a specimen temperature during the combustion of the specimen; And a specimen holder installed on the upper portion of the mass reduction rate measuring device to receive and burn the specimen.

As a result, the heat of the large-area heat flux applying device and the heat of the combustion of the specimen can be prevented from being transmitted to the mass-reduction rate measuring device, thereby reducing the error in mass measurement.

Here, the apparatus main body includes: a base portion having a plate shape; A plurality of support frames installed on the base portion to support the large area heat flux application device so as to be positioned above the base; And a leg portion supporting the base portion with respect to the ground.

Also, the large-area heat flux applying device may include: a cone-shaped body installed on the plurality of support frames to be positioned at an upper portion of the base, And a heater installed on the inner surface of the cone-shaped body in a coil shape.

In addition, the specimen temperature measuring device may be installed at an angle of 45 degrees to the cone-shaped body.

The mass reduction rate measuring apparatus may further include: a cell housing positioned above the base; A load cell installed on an inner bottom of the cell housing; A cover block installed to cover an upper portion of the load cell; And a specimen elevation unit installed on the cover block and extending vertically to the upper portion of the cell housing.

It is preferable that the mass reduction rate measuring apparatus further includes an internal heat insulating material disposed between the lower portion of the specimen lifting unit and the cover block.

The mass reduction rate measuring apparatus may further include an external heat insulating material installed to cover the entire upper portion of the cell housing.

The mass reduction rate measuring apparatus may further include an anti-vibration member disposed at a lower portion of the cell housing and formed of a silicon material.

Preferably, the inner heat insulator is made of Teflon, and the outer heat insulator includes a heat insulating board.

The cover block may be provided so as to cover an area of at least 2/3 of the outside of the load cell.

The sample lifting unit may be disposed at a central portion of the load cell.

It is also preferable that one or more through holes are formed in the side surface of the cell housing.

Further, it is preferable to further include a specimen holder mounted on the specimen lifting unit.

In addition, the specimen holder includes a box-shaped holder main body having an opened upper surface; And a heat insulating cover which is installed on the outer side of the holder body and surrounds the outside of the holder body to block heat transmission.

In addition, a plurality of cover supporting pieces, which are formed to protrude outward and support the lower end of the heat insulating cover, may be provided at the lower end of the holder main body.

According to the fire physical property all-in-one testing apparatus of the present invention, the heat of the large-area heat flux application device and the heat of the combustion of the specimen can be prevented from being transmitted to the mass reduction rate measuring device, thereby reducing the error in mass measurement.

In addition, a cover block is provided to secure a large contact area with the load cell, thereby preventing shaking in mass measurement and allowing a load to spread widely without focusing on a specific position, thereby reducing a mass measurement error.

In addition, by installing the specimen temperature measuring device on the cone type body, the specimen temperature measuring device can be installed at an angle of 45 degrees without being installed perpendicular to the specimen, thereby minimizing the direct transfer of the heat of the specimen to the specimen temperature measuring device It is possible to accurately measure the heat of combustion.

1 is a perspective view showing an all-in-one fire test apparatus for fire properties according to an embodiment of the present invention.
Fig. 2 is a partial cross-sectional view of Fig. 1. Fig.
3 is a side view of the mass reduction rate measuring apparatus shown in FIG.
4 is a sectional view taken along the line I-I in Fig.
5 is a sectional view taken along the line II-II in Fig.
6 is a perspective view of the mass reduction rate measuring apparatus shown in Fig.
FIG. 7 is a cross-sectional view showing an essential portion of the large-area heat flux application device shown in FIG. 1. FIG.
8 is a sectional view showing a specimen holder of a fire physical property all-in-one testing apparatus according to an embodiment of the present invention.
9 is a plan view of the holder body shown in Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a fire physical property calculation all-in-one testing apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 9, a fire physical property all-in-one testing apparatus 10 according to an embodiment of the present invention includes an apparatus main body 100 having a base portion 110, An area heat flux applying device 200, a mass reduction rate measuring device 300 installed in the base 110, a sample temperature measuring device 400, and a sample holder 500.

The apparatus main body 100 includes a base 110, a plurality of support frames 120 mounted on the base 110, and a leg 130 supporting the base 110 with respect to the ground Respectively. A mass reduction rate measuring device 300 is installed on the base 110. The plurality of support frames 120 are rod-shaped and vertically fixed to the upper portion of the base portion 110.

The large-area heat flux applying device 200 is installed on the support frame 120 so as to be positioned above the base 110. The large-area heat flux applying device 200 includes a cone-shaped body 210 having a cone shape for collecting combustion smoke and a cone-shaped body 210 for generating and radiating heat energy according to an electric signal, A heater 121 is installed. A discharge duct (not shown) through which the combustion gas is discharged is connected to the opened upper portion of the cone type body 210, and a shutter (not shown) can be installed on the cone type body 210 to be automatically or manually operated. When the cone-shaped body 210 is large in size, the heater 121 may have a structure in which a plurality of heaters are stacked and assembled up and down. The large-area heat flux applying device 200 having such a configuration generates radiant heat to the specimen using the heater 220, thereby burning the specimen.

3 to 6, the mass-reduction rate measuring apparatus 300 is disposed at an upper portion of the base 110 and directly below the large-area heat flux applying apparatus 200. The mass reduction rate measuring apparatus 300 includes a cell housing 310 installed at an upper portion of a base 110, a load cell 320 installed at an inner bottom of the cell housing 310, A specimen elevation unit 340 installed on the upper part of the cover block 330 and extending vertically to the upper portion of the cell housing 310 and a lower part of the specimen elevation unit 340 And an external heat insulator 360 installed to cover the upper portion of the cell housing 310. The external heat insulator 350 may be formed of an insulating material.

The cell housing 310 has a square box structure and is supported at the lower portion of the base portion 110 by the vibration preventing member 370 formed of a soft silicone material . Accordingly, vibration transmitted to the cell housing 310 through the base 110 is blocked. A through hole 311 is formed in the side surface of the cell housing 310 to allow air to flow into and out of the cell housing 310 so that heat inside the cell housing 310 is discharged to the outside through the through hole 311 .

The load cell 320 is installed on the inner bottom of the cell housing 310 and is located above the specimen elevation unit 340 to measure the change in the mass of the specimen buried thereby to accurately measure the specimen mass reduction rate . The load cell 320 is installed in a central portion of the interior of the cell housing 310.

The cover block 330 is installed to cover the upper surface and both side surfaces of the load cell 320. The cover block 330 is formed of a metal material and covers the area of at least 2/3 of the upper surface of the load cell 320. The cover block 330 is installed to cover at least half of both sides of the long side. As described above, the cover block 330 is installed to be in contact with a large area of the load cell 320, and the specimen lifting unit 340 is installed on the cover block 330, The load distribution can be made wide by the cover block 330, and the load can be prevented from concentrating at a specific position. Since the load is applied to the large area of the load cell 320 by the cover block 330, the load can be measured more accurately, and the specimen elevation unit 340 can be prevented from shaking, The mass reduction rate can be more accurately measured. That is, since the sample lifting unit 340 is supported by the large area and the load is transmitted, the vibration is not concentrated to a specific point of the load cell 320 due to the vibration occurring in the combustion process of the sample, The reliability of the measured value of the load cell 320 can be increased.

The specimen lifting unit 340 includes a fixing member 341 coupled to an upper portion of the cover block 330, a lifting member 343 lifted and coupled to the upper portion of the fixing member 341, And a guide tube 347 installed on the upper side of the cell housing 310. The guide tube 347 is provided on the outer side of the fixing member 341. [ The fixing member 341 is installed on the upper portion of the cover block 330 and the upper portion thereof is installed in a bar shape so as to protrude to the outside of the cell housing 310. An elevating member 343 is vertically and slidably coupled to the outside of the fixing member 341 protruding outside the cell housing 310. The elevating member 343 has a pipe structure and has an enlarged portion 343a whose inner diameter is extended at the lower end. A guide slit 343b for guiding the movement of the projection 341a protruding from the outer surface of the fixing member 341 is formed in the elevation member 343 in a vertically long manner. The elevating member 343 is provided with a fixing bolt 344 so that the height of the elevating member 343 can be adjusted and fixed by selectively tightening or loosening.

A sample supporting stage 345 is installed at the upper end of the elevating member 343 in a horizontal posture. A specimen holder 400 to be described later is installed on the specimen supporting stage 345.

The guide pipe 347 is located outside the fixing member 341 and is preferably positioned above the cell housing 310 and has a pipe structure having an outer diameter larger than that of the fixing member 341. An extension portion 343a of the elevating member 343 is coupled to the outside of the guide pipe 347 so as to be elevated from the outside. By providing the guide tube 347 and the extending portion 343a in this way to guide the mutual up and down movement, the outside of the fixing member 341 having a relatively small diameter can be reinforced, As shown in Fig.

An inner heat insulating material 350 is installed between the fixing member 343 and the cover block 330 to block heat transfer to the cover block 330 through the specimen elevating unit 300 so that the load cell 320 can be measured It is possible to prevent an error from occurring in the value. The inner heat insulating material 350 has a plate structure having a predetermined thickness and is made of Teflon so that heat transfer through direct contact between the fixing member 343 and the cover block 330 can be minimized and also indirect heat radiation can be blocked .

The outer heat insulating material 360 is installed to surround the upper portion of the outer side of the cell housing 310 and has a plate structure having a predetermined thickness. The outer heat insulating material 360 preferably includes a heat insulating board (ceramic board) having an excellent heat shielding effect. Therefore, it is possible to prevent the cell housing 310 from being heated by the heat of combustion of the specimen burnt at the upper end of the specimen elevating unit 340.

In the mass reduction rate measuring apparatus 300 having the above configuration, the specimen elevation unit 340 is installed at the central portion of the load cell 320, so that the load of the specimen acts on the central portion of the load cell 320, Can be measured. Particularly, a cover block 330 is provided on the upper part of the load cell 320 to allow a load to act on a large area of the load cell 320 to prevent tremor and accurately measure the mass of the specimen. And the outer heat insulating material 360 may be installed to effectively block the heat generated when the specimen is burned by the load cell 320. Therefore, the reliability of the mass reduction rate measurement data in the load cell 320 can be improved.

The specimen temperature measuring apparatus 400 is for measuring the temperature of the specimen and is installed in the cone-shaped body 210 of the large-area heat flux applying apparatus 200 as shown in FIG. Preferably, the specimen temperature measuring apparatus 400 is an infrared temperature sensor for measuring the temperature of the specimen. The specimen temperature measuring apparatus 400 may be installed to be supported by the heater 220 when attached. Preferably, 220 can be used to secure an installation space. When the specimen temperature measuring apparatus 400 is installed on the cone-shaped body 210, the specimen temperature measuring apparatus 400 is inclined at an angle of 45 degrees by the cone-shaped body 210 formed at an angle of about 45 degrees The temperature of the specimen can be easily measured.

8 and 9, the specimen holder 500 is installed on the specimen support stage 345 on the upper part of the specimen elevation unit 340 to receive and combust the specimen. The specimen holder 500 includes a holder body 510 having a box structure and a heat insulating cover 520 covering the outside of the holder body 510. The holder main body 510 has a substantially rectangular top shape and has a structure in which the upper surface is opened to accommodate the specimen. A plurality of cover supporting pieces 512 are provided so as to protrude outside the lower portion of the holder main body 510. Preferably, the cover supporting pieces 512 are disposed on each of the four sides of the holder main body 510, 520) at four points. The holder body 510 may be made of a hard ceramic board having a low thermal conductivity to reduce weight.

The heat insulating cover 520 has a box shape with upper and lower openings and is installed to cover and protect the outer side of the holder main body 510 in a state of being separated from the holder main body 510. Such a heat insulating cover 520 is formed of a heat insulating board, and is preferably made of a rumi board. By the heat insulating cover 520, the heat of combustion of the specimen received and burned in the holder body 510 is transferred to the upper part, so that the large-area heat flux test can be effectively performed.

According to the fire physical property calculation all-in-one testing apparatus 10 according to the embodiment of the present invention having the above configuration, the heat generated during the combustion of the specimen, as well as the large-area heat flux application apparatus 100, The error of the mass measurement can be reduced. Further, by providing the cover block 330 so as to secure a large contact area with the load cell 320, it is possible to prevent the trembling at the time of mass measurement, to spread the load without being concentrated at a specific position, .

By providing the specimen temperature measuring apparatus 400 on the cone-shaped body 210, the specimen temperature measuring apparatus 400 can be installed at an angle of 45 degrees without being installed perpendicularly to the specimen, It is possible to accurately measure the heat of combustion while minimizing the direct transmission to the measuring device 400. [

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 exemplary embodiments. Those skilled in the art will readily appreciate that many modifications and variations of the present invention are possible without departing from the spirit and scope of the appended claims.

10 .. Fire property calculation All-in-one test equipment
100.
200 .. Large area heat flux applying device
300 .. Mass reduction rate measuring device
400 .. Specimen temperature measuring device
500 .. Specimen holder (500)

Claims (18)

An apparatus main body having a base portion;
A large-area heat flux applying device installed in the apparatus main body and generating and supplying radiant heat to the specimen to be burned, and having a cone shape;
A mass reduction rate measuring device installed in the base and measuring a mass of the specimen during combustion;
A specimen temperature measuring device installed in the large area heat flux application device and measuring a specimen temperature during the combustion of the specimen; And
And a specimen holder installed on the upper portion of the mass reduction rate measuring device and accommodating and burning the specimen. The apparatus according to claim 1,
A base portion having a plate shape;
A plurality of support frames installed on the base portion to support the large area heat flux application device so as to be positioned above the base;
And a leg part for supporting the base part with respect to a ground surface. The apparatus as claimed in claim 2, wherein the large-
A cone-shaped body provided on the plurality of support frames so as to be positioned above the base, the cone-shaped body having a lower portion and an upper portion opened;
And a heater installed on the inner surface of the cone-shaped body in a coil shape. The method of claim 3,
Wherein the specimen temperature measuring device is installed at an angle of 45 degrees to the cone-shaped body. An apparatus main body having a base portion;
A large-area heat flux applying device installed in the apparatus main body and generating and supplying radiant heat to the specimen to be burned, and having a cone shape;
A mass reduction rate measuring device installed in the base and measuring a mass of the specimen during combustion;
A specimen temperature measuring device installed in the large area heat flux application device and measuring a specimen temperature during the combustion of the specimen; And
And a specimen holder installed at an upper portion of the mass reduction rate measuring device to receive and burn an ordinary plate,
In the large-area heat flux applying device,
A cone-shaped body provided at an upper portion of the apparatus main body and having a lower portion and an upper portion opened; and a heater installed in a coil shape on the inner surface of the cone-shaped body. Device. An apparatus main body having a base portion;
A large-area heat flux applying device installed in the apparatus main body and generating and supplying radiant heat to the specimen to be burned, and having a cone shape;
A mass reduction rate measuring device installed in the base and measuring a mass of the specimen during combustion;
A specimen temperature measuring device installed in the large area heat flux application device and measuring a specimen temperature during the combustion of the specimen; And
And a specimen holder installed at an upper portion of the mass reduction rate measuring device to receive and burn an ordinary plate,
Wherein the specimen temperature measuring device is installed at an angle of 45 degrees to the large-area heat flux applying device. 7. The method according to any one of claims 1 to 6,
Wherein the mass reduction rate measuring device comprises:
A cell housing positioned above the base;
A load cell installed on an inner bottom of the cell housing;
A cover block installed to cover an upper portion of the load cell; And
And a specimen elevation unit installed at an upper portion of the cover block and extending vertically to an upper portion of the cell housing. The apparatus according to claim 7, wherein the mass-
Further comprising an internal heat insulating material disposed between the lower portion of the specimen elevating unit and the cover block. The apparatus according to claim 8, wherein the mass-
And an external heat insulating material installed to cover the entire upper portion of the cell housing. The apparatus according to claim 7, wherein the mass-
Further comprising an anti-vibration member formed at a lower portion of the cell housing and made of a silicon material. 11. The method of claim 10,
Wherein the inner heat insulating material is made of Teflon, and the external heat insulating material comprises a heat insulating board. 8. The method of claim 7,
Wherein the cover block is installed so as to cover an area of at least 2/3 of the outer side of the load cell. 8. The method of claim 7,
Wherein the specimen lifting unit is disposed at a central portion of the load cell. 8. The method of claim 7,
Wherein the cell housing is provided with one or more through-holes on the side surface thereof. 8. The method of claim 7,
And a specimen holder mounted on an upper portion of the specimen elevation unit. 16. The apparatus of claim 15, wherein the specimen holder comprises:
A holder main body in the form of a box whose upper surface is opened;
And a heat insulating cover which is installed on the outer side of the holder body and surrounds the outside of the holder body to block heat transfer. 17. The method of claim 16,
And a plurality of cover supporting pieces protruding outwardly and supporting the lower end of the heat insulating cover are provided at the lower end of the holder main body. An apparatus main body having a base portion;
A large-area heat flux applying device installed in the apparatus main body and generating and supplying radiant heat to the specimen to be burned, and having a cone shape;
A mass reduction rate measuring device installed in the base and measuring a mass of the specimen during combustion;
A specimen temperature measuring device installed in the large area heat flux application device and measuring a specimen temperature during the combustion of the specimen; And
And a specimen holder installed on the upper portion of the mass reduction rate measuring apparatus to receive and burn the specimen,
Wherein the mass reduction rate measuring device comprises:
A load cell installed on an upper portion of the base portion;
A cover block installed to cover an upper portion of the load cell; And
And a specimen elevation unit mounted on an upper portion of the cover block.

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