KR100709755B1 - A smoke test device - Google Patents

Abstract

The present invention relates to a smoke test apparatus, comprising a combustion chamber having an upper vent and a lower vent, an upper damper for opening and closing an upper vent, a lower damper for opening and closing a lower vent, an upper cylinder mechanism for operating an upper damper, and operating a lower damper. A lower cylinder mechanism, a radiating furnace for radiating heat to the specimen, a radiating furnace support tube for supporting the radiating furnace at a predetermined distance from the inner wall of the combustion chamber, and a radiating furnace in the direction of crossing the radiating furnace in front of the radiating furnace. A guide rod, a specimen holder slidably coupled along the guide rod, a specimen holder drive unit for moving the specimen holder, a radiometer for measuring the radiant heat applied to the specimen from the heat radiating furnace, and a transmission amount of light in the combustion chamber It includes an optical system for measuring the smoke density. According to the present invention, the air inlet and the smoke outlet of the combustion chamber can be easily opened and closed, and the radiant heat applied to the specimen can be easily controlled.

Combustion, smoke, smoke density, radiant heat, furnace, damper, cylinder

Description

A smoke test device

1 is a configuration diagram showing an example of a smoke testing apparatus according to the prior art,

2 is a block diagram showing a smoke test apparatus according to an embodiment of the present invention,

Figure 3 is a side view showing a smoke test apparatus according to an embodiment of the present invention,

4 is a right side view of FIG. 3;

5 is a perspective view showing the heat radiation furnace shown in FIGS. 3 and 4;

6 is an enlarged view showing the heat radiation furnace shown in FIG. 4;

7 is a side cross-sectional view showing a heat radiation furnace shown in FIG. 6;

8 is a perspective view showing the specimen holder shown in FIG.

9 is a schematic side cross-sectional view showing a coupling state of the specimen holder shown in FIG.

10 is a side view of the burner viewed along the line A-A of FIG.

11 is a schematic plan view showing an operating state of a specimen holder driving unit shown in FIG. 4;

12 is a screen illustrating an example of the interface illustrated in FIG. 3.

Explanation of symbols on the main parts of the drawings

10: combustion chamber 11: upper vent

12: upper damper 13: upper cylinder mechanism

15: lower vent 16: lower damper

17: lower cylinder mechanism 20: side cabinet

30: base cabinet 40: heat dissipation furnace

41 housing 42 insulator

43 heater 45 radiant furnace support tube

46: fixing bolt 47: guide rod

48: tube support 51: specimen holder

52: upper conveying bracket 53: lower conveying bracket

54: tray 60: specimen holder drive unit

61: cylinder body 62: cylinder rod

63: holder support member 70: burner

80: radiometer 90: interface

LIGHT: Light source PMT: Photo sensor

The present invention relates to a smoke testing apparatus, and more particularly to a smoke testing apparatus for measuring the density of smoke according to the fire generated by the simulation of the fire.

In general, fire is a phenomenon in which various physical and chemical phenomena are intricately intertwined, and it is fundamentally impossible to simulate all aspects of fire at the laboratory level at once.

After ignition, the development into a fire can occur through several different routes, depending on the physical location of the combustible material, as well as other environmental conditions. However, the form of a typical fire development stage can be organized into three stages represented by a typical temperature-time curve.

The composition of the combustion cracking products at each stage is different, which affects the smoke density at each stage. Moreover, in fire scenarios, in particular, information is required on the flow of heat, the supply of oxygen, the release of combustion gases, and the like.

Evaluation of the actual fire performance of the product can be obtained with specimens of actual size and many factors affect the generation of smoke and the characteristics of the smoke produced. Therefore, it is possible to evaluate the effect on the development of a fire by understanding the characteristics of the smoke of a particular material.

The density of smoke, one of the characteristics of smoke, can be measured by measuring the percent light transmittance using an optical system.

The transmission of light is measured by exposing the test piece to a heat radiating furnace for a predetermined time. Through this, it is possible to calculate the specific optical density (mass loss rate), such as (Specific Optical Density).

As described above, the smoke test apparatus generates smoke through the smoke generating unit in an enclosed space and measures the density of the smoke by measuring the light transmittance of the smoke through an optical system.

As shown in FIG. 1, one example of a conventional smoke generator includes a combustion chamber 110 having an upper vent and a lower vent, an upper damper and a lower damper for opening and closing the upper vent and the lower vent, and a specimen to be burned. A radiating furnace 140 for radiating heat, a specimen holder provided in front of the radiating furnace 140, a burner 170 for igniting the specimens accommodated in the specimen holder, and a fuel supply unit supplying fuel to the burner 170 ( 175, an air supply unit 176 for supplying air to the burner 170, and a radiometer 180 for measuring the amount of heat applied to the specimen from the heat radiating furnace 140.

Conventionally, the damper was manually opened and closed to allow air to enter and exit the air through the upper and lower vents of the combustion chamber 110. Therefore, there is a problem that the accuracy of the test is lowered and the risk is accompanied.

The specimen holder is located on the front of the radiating furnace 140 to expose the specimen to the radiant heat, and by positioning it out of the front of the radiating furnace 140 so that radiant heat is not applied to the specimen, the operation of moving the specimen holder is manually Because of this, the accuracy of the test was lowered and there was a problem with risk.

Therefore, the present invention was created to improve the problems of the conventional smoke test apparatus as described above, and can easily open and close the air inlet and the smoke outlet of the combustion chamber and can easily control the radiant heat applied to the specimen. The purpose is to provide an apparatus for testing smoke.

In order to achieve the above object, the smoke test apparatus according to the present invention comprises: a combustion chamber having an upper vent and a lower vent; An upper damper for opening and closing the upper vent; A lower damper for opening and closing the lower vent; An upper cylinder mechanism for operating the upper damper; A lower cylinder mechanism for operating the lower damper; A heat dissipation furnace provided inside the combustion chamber, having a cylindrical housing, having an insulator in the housing, having a heater on one side of the insulator, and applying radiant heat to a specimen to be burned; A heat dissipation furnace support tube for supporting the heat dissipation furnace at a predetermined distance from an inner wall of the combustion chamber; A guide rod provided in a direction crossing the radiation furnace in front of the radiation furnace; A specimen holder slidably coupled along the guide rod and accommodating the specimen; A specimen holder driver for moving the specimen holder; A radiometer for measuring radiant heat applied to the specimen from the heat radiating furnace; It includes an optical system for measuring the smoke density by measuring the transmission amount of light in the combustion chamber.

The present invention may further include a burner for igniting the specimen contained in the specimen holder, a fuel supply unit supplying fuel to the burner, and an air supply unit supplying air to the burner.

The present invention preferably further comprises a cooling mechanism for cooling the radiometer by air cooling. At this time, the cooling mechanism is preferably supplied with air from the air supply.

The upper cylinder mechanism and the lower cylinder mechanism is preferably supplied with air pressure from the air supply.

Preferably, the specimen holder drive unit is a cylinder mechanism that receives air pressure from the air supply unit.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the smoke test apparatus according to the present invention.

2 and 3, the smoke test apparatus according to an embodiment of the present invention, the combustion chamber 10 having the upper vent 11 and the lower vent 15, opening and closing the upper vent 11 The upper damper 12, the lower damper 16 for opening and closing the lower vent 15, the upper cylinder mechanism 13 for operating the upper damper 12, the lower cylinder mechanism for operating the lower damper 16 (17), a heat radiation furnace (40) for applying radiant heat to the specimen to be burned, a heat radiation furnace support tube (45) for supporting the heat radiation furnace (40), and a heat radiation furnace (40) in front of the heat radiation furnace (40). A guide rod 47 provided in a direction traversing the), a specimen holder 51 slidably coupled along the guide rod 47, a specimen holder drive unit 60 for moving the specimen holder 51, the A burner 70 for igniting the specimen contained in the specimen holder 51, a fuel supply unit 75 for supplying fuel to the burner 70, and the burner An air supply unit (76) for supplying air to the air (70), a radiometer (80) for measuring the radiant heat applied to the specimen from the heat radiating furnace (40), and the transmission amount of light in the combustion chamber (10) is measured It includes an optical system for measuring the smoke density.

The combustion chamber 10 is formed in a rectangular cylinder shape, has an upper vent 11 and a lower vent 15, the heat radiation furnace 40, the specimen holder 51, the burner 70 and the radiometer (radiometer) 80, an optical system is provided.

The optical system includes a light source LIGHT and a photo sensor PMT that senses light of the light source. The light source LIGHT is provided at the bottom of the combustion chamber 10, and the photo sensor PMT is provided at the ceiling of the combustion chamber 10. Therefore, the photo sensor PMT senses the light emitted from the light source LIGHT to measure the light transmittance, thereby measuring the density of the smoke.

The lower vent 15 is a passage through which the smoke in the combustion chamber 10 is forcedly discharged, and the upper vent 11 is a passage through which external air flows into the combustion chamber 10. Through the opening and closing operations of the lower vent 15 and the upper vent 11 can adjust the pressure in the combustion chamber 10, it is possible to discharge the smoke.

The lower vent 15 and the upper vent 11 are opened and closed by the lower damper 16 and the upper damper 12, respectively, and the lower damper 16 and the upper damper 12 are the upper cylinder mechanism 13 and It is operated by the lower cylinder mechanism 17, respectively.

That is, the upper cylinder mechanism 13 and the lower cylinder mechanism 17 are supplied with air pressure from the air supply unit 76 to linearly move the lower damper 16 and the upper damper 12 to lower the vent 15 and the upper portion. Each vent 11 is opened and closed.

As shown in Figure 3 and 4, the lower side of the combustion chamber 10 is provided with a rectangular cylindrical base cabinet 30, the side of the combustion chamber 10 and the base cabinet 30, a rectangular cylinder The side cabinet 20 of the shape is provided. The combustion chamber 10, the base cabinet 30, and the side cabinet 20 form a rectangular cylindrical shape as a whole.

5 to 7, the heat radiating furnace 40 is provided inside the combustion chamber 10, has a cylindrical housing 41, and an insulator 42 inside the housing 41. And a heater 43 on one side of the insulator 42.

The housing 41 has an opening formed at one side to radiate the heat of the heater 43 to the outside. The housing 41 is inserted into the heat radiation furnace support tube 45 and is supported by a plurality of fixing bolts 46.

The heat radiating furnace support tube 45 is supported by a tube support 48 at a predetermined height with respect to the bottom of the combustion chamber 10. The tube support 48 is fixed to the bottom of the combustion chamber 10 and is supported by the heat radiating furnace support tube 45 to support the heat radiating furnace 40.

The heater 43 is formed in a coil shape and generates heat by receiving power from the outside.

A pair of guide rods 47 are provided in front of the heat dissipation furnace 40 in a direction crossing the heat dissipation furnace 40. Both ends of the guide rod 47 are provided to be fixed to the tube support 48, and a pair of the guide rods 47 is provided in parallel with a predetermined interval therebetween.

A specimen holder 51 is slidably coupled to the guide rod 47. That is, referring to FIGS. 8 and 9, an upper transfer bracket 52 is coupled to an upper portion of the specimen holder 51 to slidably support the upper guide rod 47 of the pair of guide rods 47. The lower transfer bracket 53 is coupled to the bottom of the specimen holder 51 to be slidably supported by the lower guide rod 47.

The specimen holder 51 is formed in a rectangular frame shape and accommodates the specimen therein, and has an open portion so that heat of the heat radiating furnace 40 or the burner 70 can be applied to the specimen.

A tray 54 is coupled to the lower portion of the specimen holder 51 to collect debris falling from the specimen.

The specimen holder 51 is forcibly moved along the guide rod 47 by the specimen holder driver 60.

5 and 11, the specimen holder driving unit 60 includes a cylinder body 61 and a cylinder rod 62 as a cylinder mechanism, and operates by receiving air from the air supply unit 76.

The cylinder body 61 of the specimen holder drive unit 60 is fixedly coupled to one side of the combustion chamber 10, the cylinder rod 62 is provided to extend to the specimen holder 51, the cylinder rod 62 On one side of the holder supporting member 63 for supporting the specimen holder 51 is coupled.

The holder supporting member 63 is provided with a pair at predetermined intervals along the longitudinal direction of the cylinder rod 62 to grab and move the specimen holder 51. Here, the holder support member 63 may be fixedly coupled to the specimen holder 51, but the specimen holder 51 is easily detachable from the guide rod 47 by only supporting and moving the specimen holder 51. do. One of the pair of holder support members 63 supports the specimen holder 51 away from the cylinder body 61, and the other supports the specimen holder 51 toward the cylinder body 61.

The burner 70 is for a flame exposure test, and is supplied with propane gas from the fuel supply unit 75 and air is supplied from the air supply unit 76 to ignite the specimen. Propane gas supplied from the fuel supply unit 75 and air supplied from the air supply unit 76 are mixed through one line and supplied to the burner 70. The burners 70 are divided into six branches to disperse and spray the mixed gas introduced into one line.

The radiometer 80 measures the radiant heat applied to the specimen from the heat radiating furnace 40 and is cooled by a cooling mechanism.

The cooling mechanism receives air from the air supply unit 76 and circulates the radiometer 80 to cool the radiometer 80 by air cooling. The cooling mechanism supplies air to the radiometer 80 when the temperature of the radiometer 80 rises above a predetermined value, and the radiometer 80 is equipped with a thermometer measuring temperature.

The side cabinet 20 is provided with an interface 90 for control.

As shown in FIG. 12, the interface 90 is configured as a touch panel to control equipment through a control unit. The control unit includes a computer for inputting and outputting electrical signals from the equipment.

The base cabinet 30 accommodates equipment including an optical system and a lower cylinder mechanism 17.

As mentioned above, although the preferred embodiment for illustrating the principle of this invention was shown and demonstrated, this invention is not limited to the structure and operation as it was shown and described. Without departing from the gist of the invention claimed in the claims, any person having ordinary skill in the art to which the present invention pertains can make various changes and modifications, as well as such changes and modifications It is in the range of a range description.

As described above, according to the smoke test apparatus according to the present invention, the air inlet and the smoke outlet of the combustion chamber can be easily opened and closed, and the radiation heat applied to the specimen can be easily controlled to perform an accurate experiment. There is.

Claims (5)

A combustion chamber having an upper vent and a lower vent; An upper damper for opening and closing the upper vent; A lower damper for opening and closing the lower vent; An upper cylinder mechanism for operating the upper damper; A lower cylinder mechanism for operating the lower damper; A heat dissipation furnace provided inside the combustion chamber, having a cylindrical housing, having an insulator in the housing, having a heater on one side of the insulator, and applying radiant heat to a specimen to be burned; A heat dissipation furnace support tube for supporting the heat dissipation furnace at a predetermined distance from an inner wall of the combustion chamber; A guide rod provided in a direction crossing the radiation furnace in front of the radiation furnace; A specimen holder slidably coupled along the guide rod and accommodating the specimen; A specimen holder driver for moving the specimen holder; A radiometer for measuring radiant heat applied to the specimen from the heat radiating furnace; And an optical system for measuring a smoke density by measuring a transmission amount of light in the combustion chamber. According to claim 1, Burner for igniting the specimen accommodated in the specimen holder; A fuel supply unit supplying fuel to the burner; And an air supply unit for supplying air to the burner. The smoke testing apparatus according to claim 2, further comprising a cooling mechanism for receiving air from the air supply and cooling the radiometer. The method according to claim 2 or 3, The upper cylinder mechanism and the lower cylinder mechanism smoke tester, characterized in that the pneumatic supply from the air supply. The method of claim 4, wherein the specimen holder driving unit, Smoke test device, characterized in that the cylinder mechanism receives the air pressure from the air supply.

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