KR101721835B1 - Apparatus for dust scattering test - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a non-acidic evaluation apparatus for crushing a material, and more particularly, to a non-acidic evaluation apparatus for crushing after applying a stabilizer for preventing asbestos fibers and the like from scattering on various building materials such as fireproofing material, ceiling material, And to provide a non-acidic evaluation device which can be used to accurately and objectively evaluate the presence or absence of scattering of asbestos fibers and the like. In order to achieve the above-mentioned object, there is provided a chamber comprising: a chamber having a sealable inner space; A specimen holder which is installed at a lower portion of the inner space of the chamber and on which the specimen of the specimen to be tested is mounted; A dropping device installed on the upper space of the chamber for dropping the falling weight on a test body mounted on a test stand, and crushing the test body; An electric fan for scattering the scattering material contained in the test sample when blowing the test piece through the air in the chamber; And a collecting device for collecting the flying acid scattered in the air by sucking the air inside the chamber.

Description

[0001] Apparatus for dust scattering test [

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a non-acidic evaluation apparatus, and more particularly, to a non-acidic evaluation apparatus for evaluating asbestos- The present invention relates to a non-acidic evaluation device that can be used to accurately and objectively evaluate the presence or absence of scattering of fibers and the like.

In general, asbestos has characteristics of being excellent in fire resistance, anticorrosion, insulation, insulating property, flammability, high tensile strength, flexibility, etc., and it is required to use such a fire resistance material for construction, heat insulating material, cement composite fiber reinforcing material, Construction materials, packing materials, and friction materials.

In addition, asbestos has been used as a fire-resistant coating material for a long period of time until the early 1990s, and asbestos-containing building materials have been widely used in various fields such as ceilings, interior materials, exterior materials, and roofing materials.

However, recent harmful effects of asbestos are known. In other words, when asbestos is scattered into the air and these substances are continuously inhaled into the human body, it causes various diseases such as lung cancer and mesothelioma. Especially, the building materials using asbestos are at the center of the controversy.

Asbestos is a fibrous aggregate of silk-like special luster among the minerals produced by natural stone. It is a harmful substance to asbestos fibers due to its floating property easily in the atmosphere. Especially, when asbestos dust is scattered in the air and is exposed to human body, Contact dermatitis and lung cancer), and recently, the use of asbestos has been regulated for environmental health reasons.

Since as many public facilities and education facilities as there are many floating population, there are many facilities built before the regulation on the use of asbestos-containing building materials and they are still in use so far, it is urgently necessary to prevent the scattering of asbestos in such facilities, (Asbestos stabilizer) for the prevention of asbestos scattering is applied by a method of preventing scattering of asbestos.

In addition, even in the case of dismantling or removing asbestos containing materials, it is permitted only to a very limited number of operators, and a chemical solution for preventing asbestos scattering, that is, an asbestos stabilizing agent, is used to prevent harm to workers' health.

In addition, a stabilizing agent is applied to building materials such as fireproofing material and ceiling material containing asbestos and roofing material to prevent the material contained in the material from being scattered such as asbestos, It is necessary to evaluate the degree of solidification and stabilization, and the evaluation method is not yet clearly presented.

Conventionally, the degree of solidification and stabilization has been evaluated only by visual observation. When the stabilizer is applied to the surface of a material and then crushed after a certain period of time, whether or not the asbestos fibers are scattered is simply observed Alternatively, it may be evaluated by a sensory measurement method, or a non-acidity may be measured using a volumetric tester capable of imparting vibration.

However, since the above method observes scattering only visually, it is difficult to obtain a good evaluation result in terms of accuracy, reliability, and objectivity, and it is difficult to evaluate the degree of stabilization with a quantitative value.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a fire-retardant fire- The object of the present invention is to provide a non-acidic evaluation device that can be used for objectively evaluating a target.

In order to accomplish the above object, according to an embodiment of the present invention, there is provided a chamber comprising: a chamber having a sealable inner space; A specimen holder which is installed at a lower portion of the inner space of the chamber and on which the specimen of the specimen to be tested is mounted; A dropping device installed on the upper space of the chamber for dropping the falling weight on a test body mounted on a test stand, and crushing the test body; An electric fan for scattering the scattering material contained in the test sample when blowing the test piece through the air in the chamber; And a collecting device for collecting the flying acid scattered in the air by sucking the air inside the chamber.

Here, the test stand comprises a support for holding the test specimen separated from the bottom surface of the specimen when the specimen is lifted so that the specimen provided in the form of a plate when the drop is further dropped and impacted.

Further, the dropping device is characterized in that the dropping weight is provided so as to drop to the center portion of the test body.

The electric fan further includes: a stationary electric fan fixedly mounted in a space inside the chamber; And a movable electric fan that is positionally adjustable in a space inside the chamber.

Here, the stationary electric fan is fixedly installed on the rear side of the chamber above the space inside the chamber to circulate the air inside the chamber.

In addition, a bar-shaped support member, which is long in the left and right direction, is fixedly installed on the upper part of the space inside the chamber, and the movable electric fan is supported on a fan holder which can be moved along the longitudinal direction of the support member to adjust the position thereof do.

In addition, a mounting bracket is coupled to the movable electric fan, and a support rod installed to be vertically inclined to the mounting bracket is coupled and fixed to the fan holder.

The fan holder is rotatable around the support body on the outer circumference of the support body. The fan-holder rotates about the support body to adjust the blowing direction of the movable electric fan upward and downward, .

Further, the movable electric fan is characterized in that the air blowing direction is set so that air is blown toward the test body mounted on the test object holder at the time of evaluation.

In addition, the non-acidity evaluating apparatus of the present invention may further include an external air injecting apparatus capable of injecting external air into the internal space of the chamber. The external air injecting apparatus includes an air injecting unit ; And an air supply unit for supplying air to the air injection unit.

Here, the air injecting unit may include an external inflow pipe arranged horizontally long on the upper side of the test object holder in the chamber interior, and injecting the air supplied into the chamber by the air supply unit through the discharge hole formed in the longitudinal direction .

In addition, the collecting device is characterized by having a filtration filter for passing and filtering the air in the chamber to collect the fugitive material contained in the air inside the chamber.

The collecting device may further include: a filter cassette in which a filtering filter is detachably installed; A filter holder for holding and fixing the filter cassette at a predetermined height in a space inside the chamber; And a suction pump connected to the outlet of the filter cassette through a hose so as to perform forced suction of the air inside the chamber through the inlet of the filter cassette.

Here, the filter holder may include a pole installed upright in the chamber interior space; And a filter holder installed on the pawl and fixed to the filter cassette by being coupled thereto. The filter holder is installed in a height adjustable structure that can be moved along the longitudinal direction of the pawl to be fixed to a desired height.

The filter holder may be rotatable about a pole on the outer circumference of the pole so that the air suction direction of the filter cassette can be adjusted by rotation about the pole, do.

In addition, the drop device includes a drop weight rest assembly to which a drop weight is additionally mounted. The drop weight rest is fixed to the fall weight rest by a magnetic force generated when a current is applied, And an electromagnet incorporated therein.

Here, the ball is a ball having a predetermined weight and diameter, and a circular groove is formed on a lower surface of the fall weight rest which can insert a part of the ball fixed by the electromagnet.

Further, the test object is an asbestos-containing material, and the scattered material is asbestos contained in the material.

Further, the test piece is a material coated with a stabilizer for preventing asbestos from scattering.

Thus, according to the non-acidic evaluation apparatus of the present invention, it is possible to accurately and objectively determine the presence or absence of scattering of harmful substances such as asbestos fibers at the time of disintegration after the application of the stabilizer for various building materials such as fireproofing material, ceiling material, And the like.

1 and 2 are views showing a non-acidic evaluation apparatus according to an embodiment of the present invention, wherein FIG. 1 is a sectional view seen from the front, and FIG. 2 is a sectional view seen from a side view.
3 is a perspective view showing a movable electric fan and its installed state in a non-acidic evaluation apparatus according to an embodiment of the present invention.
4 is a perspective view showing a filter cassette and its installed state in a non-acidic evaluation apparatus according to an embodiment of the present invention.
5 is a perspective view showing a fall weight and a fall weight rest in a non-acidic evaluation apparatus according to an embodiment of the present invention.
FIG. 6 is a view showing a state in which a fall weight drop and a specimen are crushed in the non-acidic evaluation apparatus according to the embodiment of the present invention. FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains.

The present invention accurately and objectively evaluates the presence or absence of scattering of asbestos fibers when a stabilizing agent is applied to various materials such as fire-proofing material, ceiling material, and roofing material to prevent scattering of asbestos fiber- And to provide a non-acidic evaluation device that can be used for the evaluation.

Building materials containing asbestos fibers, such as ceilings or roofing materials, should not be scattered when the stabilizer is broken and then crushed by external factors, for example when the ceiling material is falling and crushed, and thus, asbestos fibers, It is necessary to evaluate the scattering of harmful substances when grinding condition is applied to the material containing the substance.

The apparatus of the present invention can be used for such evaluation, and the apparatus of the present invention can be applied to a crushing condition for dropping a falling weight on a test object (a plate-shaped material specimen treated with a scattering-resistant stabilizer) And then sucking the air inside the chamber and collecting the substances scattered in the air by a filtration method using a membrane filter.

During the evaluation, the degree of scattering or scattering is evaluated by analyzing the membrane filter using a phase-contrast microscope (PCM) or a transmission electron microscope (TEM) after a predetermined pretreatment process .

1 and 2 are views showing a non-acidic evaluation apparatus according to an embodiment of the present invention. In the non-acidic evaluation apparatus 100 of the present invention, the chamber 110 is a closed structure, The chamber 110 is shown in cross-section.

Fig. 1 is a sectional view seen from the front, and Fig. 2 is a sectional view seen from a side view.

As shown in the figure, the non-acidic evaluation apparatus 100 of the present invention includes a chamber 110 having a closed internal space, and a door 110 is provided on the front surface of the chamber 110, Respectively.

That is, it is possible to open the front door and open the inner space of the chamber 110, and then to clean the inner space of the chamber through the front space opened by the door, or to install the test body 101 in the inner space of the chamber.

As the door on the front surface of the chamber 110, a door made of a transparent material can be used so that the inside situation can be seen from the outside.

Further, it is preferable to apply a door actuating structure (a door hinge and a door lock device) that can easily open and close the door between the chamber 110 and the door, but basically, a negative pressure acts on the space inside the chamber It is possible to completely seal the chamber interior space so that external air does not enter the chamber through the gap between the chamber and the door or leaks the air inside the chamber to the outside even if a high pressure is applied, that is, the gap between the chamber and the door It is preferable to use a packing material such as rubber or a sealing material which can completely block it.

The chamber 110 is a part where the components of the apparatus are installed or supported, and the closed internal space is provided to the space where fracture and scattering induction of the test body 101, inhalation and trapping of scattering materials are performed.

The non-acidity evaluating apparatus 100 of the present invention includes a test object holder 120 on which a material to be tested, that is, a test object 101 cut to a predetermined size is mounted, 100) inner space, for example, at the center of the bottom surface of the chamber interior space.

The test piece holder 120 is installed to be able to receive and fix the test piece 101 provided with a plate having a predetermined thickness. The test piece holder 120 is manufactured in the form of an enclosure having a predetermined height, .

In the embodiment, the test stand 120 is provided with a rectangular parallelepiped enclosure to accommodate the test specimen 101 provided in the inner space as a rectangular plate.

The test specimen 101 is installed at a predetermined height from the inner bottom surface of the specimen holder 120 so that the specimen 101 can be crushed when the drop weight 163 falling from the upper side comes into contact with the specimen 101, desirable.

For this purpose, a support portion (not shown) having a predetermined height from the inner bottom surface of the test piece holder 120 is provided in the inner space of the test piece holder 120 so as to be able to support the test piece 101 from the inner bottom surface of the test piece holder 120 when the test piece 101 is lifted 121 and a test body 101 is mounted on the support 121 for crushing in the internal space of the test stand 120 and stored.

The non-acidity evaluating apparatus 100 of the present invention includes electric fans 131 and 132 installed in a chamber 110. The electric fan blows asbestos For scattering harmful substances (scattering materials) such as fibers and the like, and may be installed on the upper part of the chamber interior space.

The fixed electric fan 131 and the movable electric fan 132 may be installed as the electric fan and the fixed electric fan 131 may be fixed to the rear side of the chamber at the upper part of the space inside the chamber 110.

A support body 111 having a plate shape is provided on the rear surface of the chamber 110 for fixing the fixed electric fan 131 and a fixed electric fan 131 is fixedly mounted on the support body 111. In the illustrated embodiment A total of two fixed electric fans 131 are installed on the upper part of the inner space of the chamber. However, the number of the fixed electric fans can be changed to a single number or three or more.

The stationary electric fan 131 is mainly used for circulating the air inside the chamber (operating in the circulation mode), and an air circulation in which the air moves upward, downward, .

The movable electric fan 132 is an electric fan installed to adjust the left and right positions in the upper part of the space inside the chamber, and it is preferable that the electric fan can be adjusted to the installation position as well as the air blowing direction.

To this end, a bar-shaped support 112 is fixedly installed on the upper part of the inner space of the chamber 110, and a fan holder 135 is installed on the support 112 to adjust its position along the longitudinal direction. So that the movable electric fan 132 is supported.

Of course, not only the fixed electric fan 131 but also the movable electric fan 132 also have a fan and a motor. The movable electric fan 132 is prepared in the form of an assembly of a fan, a motor, and a shroud, .

3 is a perspective view illustrating a movable electric fan 132 and shows a method of installing the movable electric fan 132. After the mounting bracket 133 is coupled to the movable electric fan 132 provided in the form of an assembly, A support rod 134 is fixedly mounted on the mounting bracket 133 in the up and down direction and the end of the support rod 134 is fixed to the fan holder 135.

When the knob 136 of one side is rotated in the tightening direction after the axial position of the support rod 134 is adjusted, the handle shaft assembled in the form of a fastening bolt to the fan holder 135 is guided to the outer peripheral surface of the support rod 134 The support rod 134 and the movable electric fan 132 are fixed.

When the position of the fan holder 135 in the axial direction of the support body 112 is adjusted while the fan holder 135 is coupled to the outer periphery of the bar support member 112 and then the knob 137 on the other side is rotated in the fastening direction, The left and right horizontal positions of the fan holder 135 are fixed while the handle shaft assembled to the holder 135 in the form of a fastening bolt presses the outer peripheral surface of the support body 112. [

At this time, after the fan holder 135 is rotated and adjusted in the circumferential direction on the outer circumference of the support body 112 (the support rod is rotated and adjusted in the vertical direction), the blowing direction of the movable electric fan 132, Lt; / RTI >

As a result, the position of the fan holder 135 and the movable electric fan 132 is moved and fixed in the axial direction (longitudinal direction) of the supporting body 112, thereby moving the movable electric fan 132 in the inner space of the chamber 110 And the fan holder 135 and the movable electric fan 132 are rotated in the circumferential direction about the support body 112 on the outer periphery of the support body 112 (the support rod and the electric fan rotate in the vertical direction The wind direction of the movable electric fan 132 can be adjusted.

The wind direction of the movable electric fan 132 can be adjusted so as to face the specimen 101 positioned at the lower side during the evaluation and the movable electric fan 132 can be controlled by the external air inflow pipe 142, (Operated in the dilution mode) for mixing the external air introduced into the internal space of the chamber 110 with the air in the existing chamber.

In the illustrated embodiment, a total of two movable electric fans 132 are disposed on the left and right sides. However, the number of movable electric fans may be changed to a single number or three or more.

The non-acidity evaluating apparatus 100 of the present invention further includes an external air injecting device capable of injecting external air into the internal space of the chamber 110. The external air injecting device includes a circulating mode And a new mode is used in the dilution mode in which new external air is injected into the chamber 110 to perform evaluation.

The external air injecting apparatus includes an air injecting unit 141 for injecting air in a space inside the chamber 110 and an air supplying unit (not shown) for supplying air to the air injecting unit 141.

Here, the air injecting unit 141 may be configured to inject outside air using a pipe installed in the internal space of the chamber, similar to the air diffusing pipe. The external air inlet pipe 142 installed in the chamber internal space, .

The external air inflow pipe 142 may be installed at a lower portion of the internal space of the chamber 110 so as to be positioned on the upper side of the test object holder 120. In this case, have.

The external air inflow pipe 142 has a discharge hole 143 disposed at a predetermined interval along the longitudinal direction and is connected to the air supply unit outside the chamber 110 through the hose 144.

That is, air supplied through the air supply unit is supplied into the outside air inflow pipe 142 inside the chamber 110 through the hose 144, and air flowing along the outside air inflow pipe 142 is supplied to the outside (Not shown).

The air supply unit supplies air having a predetermined pressure to the external air inlet pipe 142 in the chamber 110 through the hose 144. The air is compressed and charged to a predetermined pressure, A regulator can be attached to the bomb.

Next, the non-acidity evaluating apparatus 100 of the present invention further includes a collecting device 150 for collecting substances scattered in the air inside the chamber 110, for example, scattered asbestos fibers through a filtering method .

The collecting device 150 includes a filter cassette 151 in which a filter filter (not shown), that is, a membrane filter is detachably installed, and a filter cassette 151, And a suction pump 153 connected via a hose 154 to the filter cassette 151 so that forced air in the chamber through the filter cassette 151 is forced to be sucked.

The filter cassette 151 is configured to filter the ash in the air while filtering the air through the filter cassette 151. The filter for collecting asbestos fibers in the air has a circular shape (for example, a diameter of 25 mm) Of the filter paper.

The filter cassette 151 is installed so as to be able to install and detach a filter installed therein. The filter cassette 151 has a cylindrical main body 151a forming an air passage, and a main body 151a detachably attached to the front and rear portions of the main body 151a Front and rear caps 151b and 151c having an inlet and an outlet, respectively, and a filtration filter installed detachably so as to cross the air passage in the transverse direction.

In this configuration, the main body 151a, the front cap 151b or the rear cap 151c are disassembled and a filter is installed inside. After the filter is installed, the filter is assembled and used for evaluation. After that, it is disassembled again to separate the filter.

The outlet of the rear cap 151c to which the air is sucked is connected to the suction pump 153 through the hose 154 and the front cap 151b is connected to the suction port And an intake port for sucking air contained in the chamber.

Accordingly, at the time of evaluation, the filter cassette 151 in which the filter is installed is fixed to the filter holder 152, and then the suction pump 153 is driven to suck the air in the chamber into the filter cassette, So that the material can be filtered and trapped by the internal filtration filter.

At this time, only the air from which the scattering material has been separated moves from the filter cassette 151 to the suction pump 153 side through the hose 154.

The filtration filter may have various pore sizes (pore size), and the pore size of the filtration filter may vary depending on the analyzer.

For example, a filtration filter having a pore size of 0.45 mu m can be used for transmission electron microscopy (TEM) analysis, and a filtration filter having a pore size of 0.8 mu m can be used for a phase difference microscope analysis.

The air in the chamber 110 is forcedly sucked by using the filter cassette 151 and the suction pump 153 and the air is filtered using the filter filter of the filter cassette 151, And the filtration filter from which the scattering material is collected is separated, subjected to a predetermined pretreatment process, and then analyzed through a microscope to obtain the evaluation result.

The filter holder 152 is a component for holding the filter cassette 151 at a predetermined height in the chamber 110. The filter holder 152 includes a pole 155 installed upright in the chamber 110, And a filter holder 156 installed on the filter cassette 155 and coupled and fixed to the filter cassette 151.

In this case, it is preferable that the filter holder 156 for fixing the filter cassette 151 is installed in a height adjustable structure in the pawl 155. To this end, the pawl 155 is provided with a scale 155a indicating its height along its length direction, And the filter holder 156 is moved along the scale 155a in the pawl 155 so as to be fixed at a desired height.

4 is a perspective view showing the filter cassette 151 and the filter holder 156 and the pawl 155. The filter holder 156 is fixedly coupled to the outer circumference of the pawl 155 as shown.

At this time, the filter holder 156 is moved up and down in the pawl 155 to adjust the height to a desired height, and then the handle 157 on one side is rotated in the tightening direction. As a result, The vertical position (height) of the filter holder 156 is fixed while pressing the outer peripheral surface of the pole 155.

When the knob 158 of the other side is rotated in the tightening direction so that the handle shaft attached to the filter holder 156 in the form of a fastening bolt presses the outer circumferential surface of the filter cassette 151, 156, respectively.

In this case, when the filter holder 156 is rotated around the pawl 155 to adjust the direction and then fix the filter holder 156, the suction port direction (air suction direction) of the filter cassette 151 that sucks air in the chamber can be adjusted do.

The linearity evaluating apparatus 100 according to the present invention further includes a dropping device 160. The dropping device 160 drops the dropping weight 163 toward the specimen 101 mounted on the test piece holder 120, A predetermined weight (for example, 530 g) and a diameter (for example, 50.8 mm) may be used as the drop weight 163.

5 is a perspective view showing the dropping device 160. As shown in the figure, the dropping device 160 includes a fall weight rest 161 on which a fall weight 163 is mounted, An electromagnet (not shown) is incorporated to fix the weight 163 using magnetic force.

The drop weight rest unit 161 is fixed to the upper portion of the inner space of the chamber 110. A circular groove 162 into which a part of the drop weight 163 can be inserted is provided on the lower surface of the fall weight rest unit 161 The drop weight 163 is fixed by an electromagnet at a predetermined height (for example, 1 m) in a state where the drop weight 163 is inserted into the groove 162. Then, And the specimen 101 is crushed.

That is, when the drop weight 163 is placed in the groove 162 of the fall weight rest unit 161 in a state where a current is applied to the electromagnet to generate a magnetic force, the fall weight 163 is fixed by the magnetic force, When the current is cut off, the magnetic force is removed, and the falling weight 163 falls freely as shown in FIGS. 5 and 6, and the test body 101 is crushed.

Reference numeral 170 denotes an intake and exhaust device which is installed in the chamber 110 to allow air to be sucked and exhausted when an excessive internal pressure is applied to the internal space of the chamber or when a high pressure is applied. It is a kind of safety device that prevents it from being caught.

The intake and exhaust device 170 may be configured to allow external air to flow into the internal space of the chamber when excessively negative pressure is applied to the internal space of the chamber during forced aspiration and filtration of the air in the chamber for trapping scattered material, When the pressure inside the chamber excessively increases due to excessive external air inflow, the air in the chamber is discharged to the outside.

The intake and exhaust device 170 may have an air passage for communicating the inner and outer spaces of the chamber 110 and a valve for opening and closing the air passage in accordance with the internal pressure of the chamber 110. In addition, A filter capable of filtering particles such as asbestos fibers can be incorporated.

Reference numeral 180 denotes a control box for operating and controlling the apparatus. The control box 180 is provided with a main power switch 181, a stationary and movable electric fan power switch 182, an electric fan speed control switch 183 A mode selection switch 184, a drop weight 163 drop switch 185, an in-chamber lamp switch 186 (when a lamp is installed in the chamber), a flow rate regulator for adjusting the flow rate of external air in the dilution mode (187) or the like may be installed.

When the electric fan power switch 182 is turned on after the main power switch 181 is turned on in the control box 180 and then the electric fan speed control switch 183 is operated, And the speed of the wind by the electric fan is adjusted.

When the mode selection switch 184 is operated to select the dilution mode, external air flows into the chamber interior space by the air supply unit and the air injection unit 141, and the movable electric fan 132 operates.

When the circulation mode is selected, the stationary electric fan 131 operates without the inflow of outside air.

When the main power switch 181 is turned on, a current is applied to the electromagnet built in the fall weight rest unit 161. When the fall switch 185 is operated in the dilution mode or the selection mode, the current is applied to the electromagnet So that the falling weight 163 falls freely.

Also, when the flow rate regulator 187 is adjusted in the dilution mode, the flow rate of the external air supplied from the air supply unit to the air injection unit 141 is adjusted.

As described above, the construction and operating state of the non-acidic evaluation apparatus according to the embodiment of the present invention have been described. Hereinafter, a method of using the non-acidic evaluation apparatus of the embodiment will be described.

 First, the interior of the chamber 110 is cleaned by opening the door to prevent contamination.

The filter cassette 151 is fixed to the filter holder 152. The height and direction of the filter holder 156 are adjusted at the pawl 155 and then the filter holder 156 fixed to the pawl 155 (151).

The prepared test body 101 is mounted on the test stand 120 and the horizontal position of the movable power fan 132 is adjusted in the support body 112 and the wind direction of the movable power fan 132 is adjusted Occation).

At this time, the wind direction of the movable electric fan 132 is adjusted so as to face the test body 101 mounted on the test stand base 120.

The door is closed and the external air inflow flow rate is adjusted through the flow rate controller 187 of the control box 180 so that the desired external air can be introduced (in the case of the dilution mode), and the electric fan speed control switch 183 is operated Thereby setting the speed of the electric fans 131 and 132.

In addition, the main power switch 181 and the electric fan power switch 182 of the control box 180 are turned on, and the mode selection switch 184 is operated to select the evaluation mode, that is, the dilution mode or the circulation mode.

At this time, when the dilution mode is selected, external air having a flow rate determined by the air supply unit and the air injection unit 141 flows into the internal space of the chamber 110 as described above, and the movable electric fan 132 operates .

In addition, when the circulation mode is selected, the fixed electric fan 131 operates without influx of external air.

The suction pump 153 is operated by operating a flow rate regulator 153a provided in the suction pump to set a suction flow rate (for example, 10 L / min) and operating the suction pump 153, The fall weight 163 (for example, 530 g of steel ball) is dropped to a central portion of the test body 101 at a predetermined height (for example, 1 m) as shown in FIG.

Subsequently, the air in the chamber 110 is forcibly sucked and filtered through the filter cassette 151 for a predetermined period of time (for example, 60 minutes or 120 minutes) so as to collect the fly ash in the filtration filter. Thereafter, Then, the filter cassette 151 is disassembled to separate the filter.

After the filter filter is pretreated, it is analyzed using a phase difference microscope (PCM) or a transmission electron microscope (TEM) according to the indoor air quality process test standards of the Ministry of Environment.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. Forms are also included within the scope of the present invention.

100: Non-acidity evaluation apparatus 101:
110: chamber 111: support
112: support 120: specimen holder
121: Support part 131: Fixed electric fan
132: Movable electric fan 133: Mounting bracket
134: support rod 136: handle
137: handle 141: air injection part
142: External air inlet pipe 143: Exhaust hole
144: Hose 150: Collecting device
151: filter cassette 151a:
151b: front cap 151c: rear cap
152: filter holder 153: suction pump
154: Hose 155: Paul
155a: scale 156: filter holder
157: handle 158: handle
160: Drop device 161: Drop weight holder
162: groove 163: drop weight
170: intake / exhaust device 180: control box

Claims (19)

A chamber having a sealable inner space;
A specimen holder which is installed at a lower portion of the inner space of the chamber and on which the specimen of the specimen to be tested is mounted;
A structure for dropping a drop weight on a test body mounted on a test object holder mounted on an upper portion of a chamber interior to dismantle the drop weight by a fall weight and a magnetic force generated when a current is applied, A falling device comprising a drop weight rest unit having an electromagnet installed in an upper portion of a space inside a chamber so that a free fall of the weight is achieved;
An external air injecting device for injecting external air into the internal space of the chamber, comprising: an air injecting part injecting air in a chamber interior; and an air supplying part supplying air to the air injecting part;
A structure for scattering the scattering material contained in the test specimen during blowing of the test specimen through the air in the chamber is provided with a blowing direction so as to blow air toward the specimen mounted on the specimen holder, A movable electric fan driven in a dilution mode in which external air supplied from the external air injection device to the internal space of the chamber is diluted by mixing with air in the chamber; A fixed electric fan driven in a circulation mode for circulating the electric fan;
And a filter cassette in which a filter is detachably installed, and a filter cassette in which the filter cassette is detachably attached to the filter cassette, And a suction pump connected to the outlet of the filter cassette through a hose so as to perform forced suction of the air in the chamber through the inlet of the filter cassette;
A valve installed in the chamber and configured to open and close the air passage in accordance with the internal pressure of the chamber; and a valve that opens and closes the air passage in the chamber, An intake and exhaust device having a filter for filtering asbestos fiber particles;
And a non-acidic evaluation device.
The method according to claim 1,
Characterized in that the test piece holder has a support portion for holding the test piece separated from the bottom surface of the test piece when the test piece is lifted so that the test piece provided in the form of a plate when the drop is further dropped and impacted, Device.
delete delete delete The method according to claim 1,
Wherein the movable type fan is supported by a fan holder fixedly installed on the upper portion of the space inside the chamber so as to be movable along the longitudinal direction and adjustable in position in the support body, Non-acidic evaluation device during fracturing.
The method of claim 6,
Wherein a mounting bracket is coupled to the movable electric fan and a support rod installed to the mounting bracket so as to be disposed in an up and down direction is fixedly coupled to the fan holder.
The method according to claim 6 or 7,
Wherein the fan holder comprises:
Wherein the movable fan is rotatable around a support on an outer circumference of the support body so that the moving direction of the movable electric fan can be adjusted up and down by rotation about the support body, Non-acidic evaluation device.
delete delete The method according to claim 1,
The air-
And an external inflow pipe arranged horizontally long on the upper side of the test object holder in the chamber interior and injecting the air supplied into the inside of the chamber through the discharge hole formed along the longitudinal direction by the air supply unit Non - acidic evaluation device during material shredding.
delete delete The method according to claim 1,
The filter holder includes:
A pole installed upright in the chamber interior space; And
And a filter holder installed on the pole and to which the filter cassette is fixedly coupled,
Wherein the filter holder is installed in a height adjustable structure capable of moving along the length direction of the pawl and fixing the filter holder to a desired height.
15. The method of claim 14,
The filter holder includes:
Wherein the air suction direction of the filter cassette is adjusted by rotation about the pawl so that the filter can be fixed after the air suction direction of the filter cassette is adjusted. Device.
delete The method according to claim 1,
The steel ball having a predetermined weight and diameter,
And a circular groove into which a part of a steel ball fixed by an electromagnet can be inserted is formed on a lower surface of the fall weight rest.
The method according to claim 1,
Wherein the test object is an asbestos-containing material, and the scattering material is asbestos contained in the material.
19. The method of claim 18,
Wherein the test piece is a material coated with a stabilizer for preventing asbestos from scattering.

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