KR102458710B1 - Photocatalytic Powder Performance Evaluation Device - Google Patents

Abstract

The present invention relates to a photocatalytic powder performance evaluation device configured to reuse a gas sampling bag in a performance evaluation test of photocatalytic powder. The photocatalytic powder performance evaluation device using a Teflon sampling bag comprises: a gas sampling bag made of a transparent synthetic resin; a sample holder accommodated in the gas sampling bag; and a gas inlet/outlet communicating with the gas sampling bag to introduce and discharge gas. The sample holder includes: a body unit; a placing unit indented from the upper surface of the body unit to accommodate a sample; a hinge coupling unit provided along one side of the upper surface of the body unit; a damper unit provided on the opposite side of the hinge coupling unit of the upper surface of the body unit; and a transparent sample cover plate of which one end is coupled to the hinge coupling unit to rotate around a hinge shaft to cover the placing unit. The lower surface of the other end of the sample cover plate is ground to the upper surface of the damper unit to form a separation space while being separated from the placing unit when the sample cover plate covers the placing unit. Gas injected through the gas inlet/outlet flows into the placing unit through the separation space.

Description

Photocatalytic Powder Performance Evaluation Device

The present invention relates to a photocatalyst powder performance evaluation device configured to reuse a gas sampling bag during a performance evaluation experiment of the photocatalyst powder.

Photocatalyst refers to a catalyst that can check the reaction state by accelerating the reaction rate in the existing photoreaction under the influence of light. One of the methods for evaluating the performance of the photocatalyst powder is a measurement method using a Teflon gas sampling bag. A part of the ready-made Teflon gas sampling bag is cut and a test plate distributed with photocatalyst powder is inserted into the incision, sealed to prevent gas leakage, and gas is injected through the gas inlet to conduct the experiment. After completing the experiment, remove the gas inside the Teflon sampling bag and then cut the sealing part again to take out the test plate. However, when removing gas from the Teflon gas sampling bag in the course of the experiment, the photocatalyst powder may scatter and adhere to the inside of the gas sampling bag, or the test plate may tilt and the photocatalyst powder may spill. It is difficult to get results.

For the same reason as above, in the process of testing and handling the photocatalyst powder, the photocatalyst powder does not touch the surface of the Teflon sampling bag to minimize contamination inside the gas sampling bag. The need for a performance evaluation device that can obtain

1. Registered Patent 10-0468617 "Photocatalyst performance evaluation device for volatile organic compound removal" 2. Laid-open Patent 10-2020-0113136 "Air purifying performance test apparatus for photocatalyst and test method therefor"

It is an object of the present invention to provide a photocatalyst powder performance evaluation device configured to improve the recyclability of a gas sampling bag while increasing the reliability of the experimental results during the performance evaluation test of the photocatalyst powder.

In order to solve the above problems, the present invention is "a photocatalyst powder performance evaluation device using a Teflon sampling bag, a gas sampling bag made of a light-transmitting synthetic resin, a sample holder accommodated in the gas sampling bag, and a gas in communication with the gas sampling bag and a gas inlet and outlet configured to enter and exit the body, wherein the sample holder includes a body portion, a seating portion for receiving a sample inside the upper surface of the body portion, a hinge coupling portion provided along one side of the upper surface of the body portion, and the upper surface of the body portion The damper part and one end provided opposite the hinge coupling part include a translucent sample cover plate coupled to the hinge coupling part and rotating about the hinge axis to cover the seating part, wherein the lower surface of the other end of the sample cover plate is the It is grounded on the upper surface of the damper part, and is configured to form a spaced space while being spaced apart from the seating part when the sample cover plate covers the seating part. It provides a "photocatalyst powder performance evaluation device configured to flow into the part".

The gas sampling bag may have an insertion hole formed at a lower portion thereof, and a body portion of the sample holder may be fitted to the insertion hole to be tightly fixed.

In addition, the sample holder may be formed to protrude along the sidewall of the body, and may further include a protruding sill having a soft layer coupled thereto to be in close contact with the periphery of the insertion hole.

In addition, the gas sampling bag may be configured to further include a reinforcing frame formed around the insertion hole.

In addition, it further comprises a plurality of fastening holes formed to correspond to each other along the circumference of the reinforcing frame and the protrusion, and inserting the body portion of the sample holder into the insertion hole in a state in which the reinforcing frame and the protrusion are in close contact with each other, the By inserting a fastener into the fastening hole and fastening it, the reinforcing frame and the clasp can be configured to be coupled to each other.

In addition, the sample holder, doedoe lifted up and down from the upper surface of the body portion, further comprising a blocking wall formed to be in close contact with an inner surface of the sample cover plate orthogonally orthogonally to the outer end of the plate when lifting, according to the elevation of the blocking wall It may be configured to open and close the separation space.

In addition, in a state in which the body portion of the sample holder is inserted into the insertion hole, it may further include a detachable blocking member for sealing the entire circumference of the insertion hole from the outer surface of the gas sampling bag.

According to the present invention, there are the following effects.

1. By using a sample holder equipped with a sample cover plate, photocatalyst powder is prevented from scattering inside the gas sampling bag during the experiment, thereby increasing the recyclability of the gas sampling bag.

2. A sill is formed in the body of the sample holder to prevent gas leakage when the sample holder is inserted in the lower part of the gas sampling bag, thereby minimizing the interference of external influences on the test results.

3. The sample holder is provided with a barrier to block the separation space, so that the photocatalyst powder is prevented from being dispersed into the Teflon sampling bag due to vibration when the sample holder is removed from the gas sampling bag.

1 is a cross-sectional view showing a state in which the photocatalyst powder performance evaluation device according to the present invention is inserted into the gas sampling bag.
[Figure 2] is an exploded perspective view showing an embodiment of the coupling structure of the photocatalyst powder performance evaluation device according to the present invention.
[FIG. 3] is an exploded perspective view showing the coupling structure of an embodiment in which a reinforcing frame and a rubber packing are formed in the gas sampling bag according to the present invention.
[Fig. 4] sequentially shows the coupling process of an embodiment in which a gasket is disposed between the reinforcing frame and the girders according to the present invention and a fastener is inserted to fix the body portion to the reinforcing frame.
[FIG. 5] is a cross-sectional view showing the structure of an embodiment configured to fasten the reinforcing frame and the sill according to the present invention using a fastener.
[Fig. 6] is a cross-sectional view illustrating a process in which gas is introduced into the sample holder through the spaced apart space according to the present invention.
[Fig. 7] is a cross-sectional view illustrating a state in which gas is introduced into a separation space when a barrier wall having a protrusion is lowered as an embodiment of the photocatalyst powder performance evaluation apparatus according to the present invention.
[Fig. 8] is a cross-sectional view illustrating a state in which the separation space is closed when the barrier wall having the protrusion is raised, as an embodiment of the photocatalyst powder performance evaluation apparatus according to the present invention.
[Fig. 9] to [Fig. 11] is an embodiment in which the removable blocking member is installed, and shows the installation process of the removable blocking member in the order of [FIG. 9] to [FIG. 11].

Hereinafter, the present invention will be described in more detail through examples. These examples are only for illustrating the present invention and should not be construed as limiting the scope of the present invention by these examples.

The present invention is "a photocatalyst powder performance evaluation device using a Teflon sampling bag, a gas sampling bag 10 made of a light-transmitting synthetic resin, a sample holder 20 accommodated in the gas sampling bag 10, and the gas sampling bag 10 ) in communication with the gas inlet and outlet 30 configured to allow gas to enter and exit, and the sample holder 20 has a body 21 and a seating portion 22 for receiving a sample by being introduced from the upper surface of the body 21 ) , a hinge coupling part 23 provided along one side of the upper surface of the body part 21, a damper part 24 provided opposite to the hinge coupling part 23 on the upper surface of the body part 21, and one end of the and a translucent sample cover plate 25 coupled to the hinge coupling part 23 and rotating about the hinge axis to cover the seating part 22, wherein the lower surface of the other end of the sample cover plate 25 is the damper part (24) is grounded on the upper surface, and is configured to form a spaced space (S) while being spaced apart from the seating part 22 when the sample cover plate 25 covers the seating part 22, A photocatalyst powder performance evaluation device configured so that the gas injected through the gas inlet and outlet 30 flows into the seating part 22 through the separation space S is provided.

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

1 is a cross-sectional view of the sample holder 20 inserted into the gas sampling bag 10 .

The gas sampling bag 10 is made of a film of a light-transmitting synthetic resin, and a reaction space blocked from the outside is formed therein. In more detail, light is transmitted into the inner space through the light-transmitting film, and a photocatalytic reaction is performed in the inner space, and the synthetic resin film made of an elastic material is formed airtight so that the injected gas does not leak, so that there is no change in the amount of gas before and after the reaction experiment is composed The reaction space is configured to be blocked from the outside, so that external factors that may affect the concentration of injected gas are removed, and light is stably transmitted to produce accurate experimental results. In this case, the synthetic resin forming the gas sampling bag 10 is preferably made of a Teflon material having good light transmittance and high chemical resistance, corrosion resistance and heat resistance.

The sample holder 20 includes the body part 21 , a seating part 22 inserted in the upper surface of the body part 21 , and a hinge coupling part 23 provided along one side of the upper surface of the body part 21 . ), the damper part 24 and one end provided opposite the hinge coupling part 23 of the upper surface of the body part 21 are coupled to the hinge coupling part 23 and rotated about the hinge axis to be seated. It is composed of a light-transmitting sample cover plate 25 that covers the part 22 and may be accommodated in the gas sampling bag 10 .

The body 21 is a member in which the sample is accommodated, and may be formed in a rectangular, circular or polygonal shape. The body 21 may be formed of a metal material (aluminum, stainless steel, etc.) or a plastic material (acrylic resin, etc.) that does not absorb or react with the gas injected into the gas sampling bag 10 . This is to remove as much as possible a factor that may affect the concentration of the gas injected into the gas sampling bag 10 other than the photocatalyst powder to be evaluated.

The seating portion 22 is formed by being inserted from the upper surface of the body portion 21, and can accommodate the photocatalyst powder. The seating part 22 may be configured with the same accommodation space as a test piece of 5 cm x 10 cm x 5 mm according to ISO 22197 series (ultraviolet light) or ISO 17168 series (indoor light), which is a standardized method for evaluating the air purification performance of a photocatalyst. have. The gas injected into the gas sampling bag 10 flows into the seating part 22 to react with the photocatalyst powder accommodated in the seating part 22 .

The hinge coupling part 23 is disposed to protrude along one side of the upper surface of the body part 21, and a hinge shaft is inserted into a pair of rotation actuator connecting parts so that one side of the rotation actuator is inserted around the hinge shaft. It is designed to rotate.

One side of the rotation actuator is provided along one side of the upper surface of the body part 21 , and the other side is connected to the sample cover plate 25 , and the sample cover plate 25 is centered on the hinge axis of the hinge coupling part 23 . ) can be rotated. In addition, the hinge coupling part 23 is configured to be able to open and close the sample cover plate 25 , so that it is possible to easily accommodate and remove the photocatalyst powder accommodated in the seating part 22 .

The damper part 24 may be provided opposite the hinge coupling part 23 on the upper surface of the body part 21 . In addition, the damper part 24 is formed to protrude from the upper surface of the body part 21, and when the sample cover plate 25 is closed, it absorbs the shock generated by contacting the body part 21 to absorb the sample. Damage to the cover plate 25 can be prevented. Therefore, it is preferable that the damper part 24 is formed of an elastic material such as rubber or silicone that can absorb shock.

In addition, a fixture (not shown) is provided in the damper part 24 , and when the sample cover plate 25 comes into contact with the damper part 24 , the fixture connects the sample cover plate 25 to the damper part 24 . ) can be configured to be fixed to. This is to prevent the sample cover plate 25 from being caught on the blocking wall 27 or from rotating due to friction when the blocking wall 27, which will be described later, moves up and down.

At this time, when the sample cover plate 25 coupled to the hinge coupling part 23 comes in contact with the damper part 24 , a spaced apart space between the upper surface of the body part 21 and the sample cover plate 25 . (S) is formed, so that gas can be smoothly introduced into and out of the seating portion 22 through the separation space (S).

In more detail, the sample cover plate 25 has one end coupled to the hinge coupling part 23 to rotate about the hinge axis, and the lower surface of the other end is grounded to the upper surface of the damper part 24, the sample cover plate (25) may be configured to form a spaced space (S) while forming a spaced state from the seating portion (22) when covering the seating portion (22).

In addition, the sample cover plate 25 is formed of a light-transmitting glass material, so that the performance evaluation of the photocatalyst powder under the light irradiated condition must be performed. It is preferable to make it of a glass material that can be minimized. At this time, the sample cover plate 25 serves to prevent the photocatalyst powder from scattering and adsorbing to the inner surface of the gas sampling bag 10 when gas is injected or recovered into the gas sampling bag 10 . , it is possible to increase the reuse rate of the gas sampling bag 10 .

The gas inlet and outlet 30 may communicate with the gas sampling bag 10 to allow gas to enter and exit. In addition, a valve is provided at the gas inlet and outlet 30 to control the inlet and outlet of gas.

The gas sampling bag 10 has an insertion hole 11 formed at the bottom, and the body portion 21 of the sample holder 20 is fitted into the insertion hole 11 to be closely fixed. may be

Hereinafter, as described above, the gas sampling bag 10 will be described with respect to an embodiment in which the insertion hole 11 is formed in the lower portion.

An insertion hole 11 may be formed in a lower portion of the gas sampling bag 10 .

The insertion hole 11 is formed to correspond to the body portion 21 of the sample holder 20 , and when the sample holder 20 is inserted, the sample holder 20 is formed around the insertion hole 11 . ) The sidewall of the body portion 21 is closely fixed, so that the separation space S is not formed between the insertion hole 11 and the sample holder 20 so that gas does not leak.

In addition, the insertion hole 11 is preferably configured to further include a reinforcing frame 12 in the peripheral portion.

When explaining the role of the reinforcing frame 12 in more detail, since the gas sampling bag 10 is formed of a thin film of synthetic resin material without rigidity, when inserting and fixing the sample holder 20 into the insertion hole 11 It is difficult to seal the inside of the gas sampling bag 10 due to insufficient support. Accordingly, in order to reinforce the supporting force, the reinforcing frame 12 having rigidity may be formed in the periphery of the insertion hole 11 . At this time, the reinforcing frame 12 may be formed of a thin plate, may be formed of a plate having a predetermined thickness, and the width or shape of the reinforcing frame 12 may be formed in various ways. The reinforcing frame 12 is formed to extend from a thin film of synthetic resin material of the gas sampling bag 10 , and is integrated with the gas sampling bag 10 to reinforce the periphery of the insertion hole 11 . .

In addition, it is preferable that the insertion hole 11 is formed with a soft rubber packing 13 along the periphery. The rubber packing 13 can minimize gas leakage by making the periphery of the insertion hole 11 and the sidewall of the body 21 of the sample holder 20 more closely contact.

Finally, the reinforcing frame 12 is formed around the insertion hole 11 to stably fix the sample holder 20 when the sample holder 20 is inserted into the gas sampling bag 10 . And, the rubber packing 13 is formed on the periphery of the insertion hole 11 to increase the sealing force. At this time, it is preferable that the rubber packing 13 is generated by being coupled to the reinforcing frame 12 .

In addition, the sample holder 20 has a protruding protrusion along the sidewall of the body portion 21 , and a protrusion 26 to which a soft layer capable of closely adhering to the periphery of the insertion hole 11 is coupled to the upper portion. It can be configured to further include.

The protrusion 26 is formed to protrude along the sidewall of the body 21 , and when the sample holder 20 is inserted into the insertion hole 11 , the clasp 26 is formed in the insertion hole 11 . It is spread over the outer periphery of the to prevent the sample holder 20 from flowing into the gas sampling bag 10 and is configured to cover the periphery of the insertion hole 11 to increase the blocking portion for gas leakage configured to do At this time, the clasp 26 may be formed to protrude from the body part 21 to be integrally formed with the body part 21 . When the body part 21 is formed by a mold injection method rather than formed by coupling the clasp 26 to the side surface of the body part 21 , the clasp 26 is formed with the body part 21 and When the mold is integrally injected, the strength of the connection part between the body part 21 and the clasp 26 is increased to prevent the clasp 26 from being separated from the body part 21 or from being damaged.

In addition, the protrusion 26 is formed on the upper portion of the soft layer that can be in close contact with the periphery of the insertion hole 11 to be in close contact with the periphery of the insertion hole 11 without a space to increase the gas blocking force. can

In addition, the upper portion of the protrusion 26 may further include a soft elastic wall (not shown) formed by spaced apart a predetermined distance upward from the protrusion 26 along the sidewall of the body 21 . can The soft elastic wall (not shown) may be formed of an elastic body, and may be forcedly fitted (elastic fit) into the insertion hole 11 to be in close contact with the inner wall of the periphery of the insertion hole 11 . Since the injected gas applies pressure from the inside of the gas sampling bag 10 to the outside, as the pressure of the injected gas increases, the elastic wall (not shown) is formed on the inner wall of the periphery of the insertion hole 11 . Since it is more closely attached, it is possible to prevent gas leakage more stably.

In addition, the photocatalyst powder performance evaluation apparatus of the present invention further comprises a plurality of fastening holes (H) formed to correspond to each other along the circumference of the reinforcing frame 12 and the protrusion 26, the sample holder 20 The reinforcement frame by inserting a fastener into the fastening hole (H) and fastening the body part 21 into the insertion hole 11 in a state in which the reinforcement frame 12 and the clasp 26 are in close contact. (12) and the protruding jaw 26 may be configured to be coupled to each other.

An embodiment of the present invention is an embodiment when the reinforcement frame 12 is formed to have a predetermined thickness, and the embodiment will be described in detail with reference to [Figs. do it with

[FIG. 4] is a coupling process of an embodiment in which a gasket (L) is disposed between the reinforcing frame 12 and the protrusion 26 according to the present invention and a fastener is inserted to fix the body portion to the reinforcing frame 12 according to the present invention. are shown in order.

[FIG. 5] is a cross-sectional view showing the structure of an embodiment configured to fasten the reinforcement frame 12 and the girders 26 according to the present invention using a fastener.

The reinforcing frame 12 is configured to have a predetermined thickness, and a plurality of fastening holes H may be formed along the edge of the reinforcing frame 12 . At this time, it is preferable that the fastening hole (H) formed in the reinforcing frame 12 does not penetrate to the upper end of the reinforcing frame 12 . This is because, when the fastening hole H penetrates to the upper end of the reinforcing frame 12 , the gas G may leak through the gap between the fastener and the fastening hole H when the fastener is fastened. Therefore, it is preferable that the fastening hole H formed in the reinforcing frame 12 is formed only from the lower end to the central portion of the reinforcing frame 12 .

In addition, fastening holes (H) are formed at positions corresponding to the fastening holes (H) formed in the reinforcing frame 12 also in the clasp 26, and the fastening holes (H) of the clasp 26 are vertically is formed to penetrate.

The fastener is detachable, and it is preferable to use a bolt so that it can be disassembled and reused after the experiment is completed.

As shown in [Fig. 4], in a state in which the body portion 21 of the sample holder 20 is inserted into the insertion hole 11 to bring the reinforcement frame 12 and the clasp 26 into close contact with each other, By inserting and fastening fasteners from the bottom to the upper side in the fastening hole (H), the reinforcing frame 12 and the clasp 26 may be configured to be coupled to each other. At this time, it is possible to prevent the leakage of the gas (G) by arranging the gasket (L) between the reinforcement frame (12) and the protrusion (26). At this time, it is preferable to use a rubber material having elasticity for the gasket (L) because it is possible to increase airtightness and prevent damage due to pressure when the reinforcing frame 12 and the clasp 26 are fastened.

As shown in [Fig. 5], as the reinforcement frame 12 and the clasp 26 that are airtightly coupled to the gas sampling bag 10 are fastened with fasteners and combined, the gas sampling bag 10 is Even when the pressure of the introduced gas G increases, it is possible to stably fix the body 21 to the gas sampling bag 10 and prevent gas leakage.

In addition, the sample holder 20 is lifted up and down from the upper surface of the body part 21 , and the blocking wall 27 is formed so that the inner surface thereof is perpendicular to the outer end of the sample cover plate 25 and in close contact with the outer end of the sample cover plate 25 when the sample holder 20 is raised. ), and may be configured to open and close the separation space S according to the elevation of the blocking wall 27 .

The blocking wall 27 is raised and lowered from the upper surface of the body 21 in the vertical direction, and the inner surface thereof is formed to be in close contact with the outer end of the sample cover plate 25 orthogonally when ascending, and the gas is not absorbed. It is preferably formed of a material.

This will be described in detail with reference to FIG. 6 .

6 shows a state in which the separation space S is opened and closed according to the elevation of the blocking wall 27 .

When the blocking wall 27 descends, the injected gas G may be smoothly introduced from the outside of the sample holder 20 to the seating portion 22 through the separation space S.

When the blocking wall 27 rises, by blocking the seating portion 22 and the outside, when the sample holder 20 is inserted into or removed from the gas sampling bag 10, the fine photocatalyst powder is moved by movement. This scattering can be prevented. If the scattered photocatalyst powder is attached to the surface of the gas sampling bag 10 , it may be difficult to recycle the gas sampling bag 10 because it affects the results of the next experiment.

Therefore, the barrier wall 27 can minimize the error of the test result by maintaining a constant amount of the photocatalyst powder, so that the reliability of the analysis technique can be improved.

In addition, the blocking wall 27 may be configured to further include a protrusion 28 formed to protrude along the inner side of the upper periphery.

The protrusion 28 is formed to protrude inward along the inner side of the upper periphery of the blocking wall 27, and is preferably formed in a thin plate shape having a predetermined width.

This will be described in detail with reference to [Fig. 7] to [Fig. 8].

7 and 8 show an embodiment in which the protrusion 28 of the blocking wall 27 is formed to protrude inward of the blocking wall 27 .

7 shows a state in which the blocking wall 27 descends and the protrusion 28 comes into close contact with the upper surface of the body 21, and the gas injected through the separation space S (G) may be smoothly introduced from the outside of the sample holder 20 to the seating portion 22 .

In addition, [Fig. 8] shows a state in which the blocking wall 27 is raised and the protrusion 28 is in close contact with the lower surface of the sample cover plate 25, and the separation space S is blocked. Thus, it is possible to prevent the photocatalyst powder from being dispersed to the outside.

In a state in which the body portion 21 of the sample holder 20 is inserted into the insertion hole 11 , the entire circumference of the insertion hole 11 is covered and sealed from the outer surface of the gas sampling bag 10 . The member 40 may be further included.

The removable blocking member 40 may be formed of a thin elastic member having a predetermined length and width, and a coupling hole 14 is formed on the inner surface to be coupled to the outer surface of the reinforcing frame 12 . . In this case, a coupling groove 15 may be formed on the outer surface of the reinforcing frame 12 to correspond to the coupling hole 14 and fastened thereto.

The process of installing the detachable blocking member 40 will be described in detail with reference to FIGS. 9 to 11 .

[Fig. 9] shows a process of inserting the sample holder 20 into the gas sampling bag 10 according to an embodiment of the present invention.

The sample holder 20 is inserted into the insertion hole 11, and at this time, the rubber packing 13 is formed on the edge of the insertion hole 11 to minimize leakage of contaminant gas.

10 shows the sample holder 20 and the detachable blocking member 40 inserted into the gas sampling bag 10 . The removable blocking member 40 may be sized to cover the outer side of the inserted sample holder 20 . In addition, a coupling groove 15 is formed on the outer surface of the reinforcing frame 12 to combine with the coupling hole 14 of the removable blocking member 40 to minimize leakage of polluting gas.

[Fig. 11] shows a state in which the removable blocking member 40 is covered and sealed on the lower part of the sample holder 20 inserted into the gas sampling bag 10. Referring to FIG. In addition, when the removable blocking member 40 is installed, adhesive tape, silicone adhesive, etc. can be used together along the edge to further increase the sealing property of the reaction space, thereby further improving the sealing force.

In the above, the present invention has been described in detail along with specific examples. However, the present invention is not limited by the above embodiments and may be modified and modified without departing from the gist of the present invention. Accordingly, the claims of the present invention cover such modifications and variations.

10: gas sampling bag
11: insertion hole 12: reinforcement frame
13: rubber packing 14: coupler
15: coupling groove
20: sample holder
21: body part 22: seating part
23: hinge coupling part 24: damper part
25: sample cover plate 26: protruding jaw
27: barrier wall 28: protrusion
30: gas inlet
40: removable blocking member
S : separation space G : gas
H : Fastener L : Gasket

Claims (7)

A photocatalyst powder performance evaluation device using a Teflon sampling bag, comprising:
a gas sampling bag 10 made of a light-transmitting synthetic resin;
a sample holder 20 accommodated in the gas sampling bag 10; and
a gas inlet and outlet configured to communicate with the gas sampling bag 10 to allow gas to enter and exit; includes,
The sample holder 20,
body portion 21;
a seating part 22 which is inserted from the upper surface of the body part 21 to receive a sample;
a hinge coupling part 23 provided along one side of the upper surface of the body part 21;
a damper part 24 provided opposite to the hinge coupling part 23 on the upper surface of the body part 21; and
a light-transmitting sample cover plate 25 having one end coupled to the hinge coupling part 23 and rotating about the hinge axis to cover the seating part 22; including,
When the lower surface of the other end of the sample cover plate 25 is grounded on the upper surface of the damper part 24 , when the sample cover plate 25 covers the seating part 22 , it is spaced apart from the seating part 22 . It is configured to form a spaced space (S) while forming a state,
A photocatalyst powder performance evaluation device (1) configured such that the gas (G) injected through the gas inlet and outlet (30) flows into the seating part (22) through the separation space (S).
In claim 1,
The gas sampling bag 10 has an insertion hole 11 formed in the lower portion,
The photocatalyst powder performance evaluation device, characterized in that the body portion 21 of the sample holder 20 is fitted in the insertion hole 11 to be closely fixed.
In claim 2,
The sample holder 20,
a protruding protrusion along the sidewall of the body 21, and a protrusion 26 to which a soft layer capable of being in close contact with the periphery of the insertion hole 11 is combined; Photocatalyst powder performance evaluation device, characterized in that it further comprises a.
In claim 3,
Gas sampling bag 10,
a reinforcing frame 12 formed in the periphery of the insertion hole 11; Photocatalyst powder performance evaluation device, characterized in that it further comprises a.



In claim 4,
A plurality of fastening holes (H) formed to correspond to each other along the circumference of the reinforcing frame 12 and the protrusion 26; further comprising,
In a state in which the body portion 21 of the sample holder 20 is inserted into the insertion hole 11 and the reinforcing frame 12 and the clasp 26 are in close contact with each other,
Photocatalyst powder performance evaluation device, characterized in that the reinforcement frame (12) and the protrusion (26) are configured to be coupled to each other by inserting and fastening a fastener into the fastening hole (H).
According to any one of claims 2 to 5,
The sample holder 20,
a blocking wall 27 that is raised and lowered from the upper surface of the body 21 in the vertical direction, and an inner surface thereof is formed to be in close contact with the outer end of the sample cover plate 25 orthogonally when ascending; further comprising,
The photocatalyst powder performance evaluation device, characterized in that the separation space (S) is opened and closed according to the elevation of the blocking wall (27).
In claim 6,
In a state in which the body portion 21 of the sample holder 20 is inserted into the insertion hole 11 , the entire circumference of the insertion hole 11 is covered and sealed from the outer surface of the gas sampling bag 10 . member 40; Photocatalyst powder performance evaluation device, characterized in that it further comprises a.

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