KR102185040B1 - Method for Measuring Dust Eliminating Performance of Range Hood - Google Patents

Abstract

The present invention relates to a device and a method for measuring the fine dust removal performance of a range hood which objectively and quantitatively measures the fine dust removal performance of a range hood to be measured to enable fair evaluation using standardized indicators. The device and the method for measuring the fine dust removal performance of a range hood objectively and quantitatively measures the fine dust removal performance of the range hood to be measured to allow fair evaluation using the standardized indicators by having an artificial fine dust emission module for forming an objective test environment in which artificial fine dust is artificially generated and spread to simulate a situation of generating pollutants when food is cooked in a kitchen, and a residual concentration sensor for accurately measuring a residual concentration of the artificial fine dust remaining indoors after the artificial fine dust is removed by the operation of the range hood to be measured.

Description

Method for Measuring Dust Eliminating Performance of Range Hood}

The present invention objectively tests the ability to inhale and remove fine dust ("fine dust removal performance") exerted by a range hood in the kitchen in relation to the removal of contaminants and other fine dust existing in the room when cooking food. It relates to devices and methods that can be evaluated.

Specifically, the present invention is designed to create an objective test environment in which artificial fine dust is artificially generated and diffused so as to simulate a situation in which contaminants are generated when food is cooked in a kitchen, and to the operation of a range hood as a test target. By having a configuration that can accurately measure the concentration of artificial fine dust remaining indoors after the artificial fine dust is removed, the range hood to be tested ("range hood to be tested") It relates to "a range hood's fine dust removal performance test apparatus and test method" that enables the objective and quantitative measurement of dust removal performance to be evaluated fairly by standardized indicators.

In addition to outdoor sources such as yellow dust, indoor fine dust concentration is greatly influenced by cooking of foods corresponding to indoor sources according to resident behavior. According to a survey by the Ministry of Environment, it is reported that the concentration of fine dust inside food cooks increases from at least 2 times to up to 60 times. Therefore, in order to improve indoor air quality by reducing the concentration of indoor fine dust, it is necessary to remove pollutants corresponding to fine dust such as odors and smoke generated during food cooking. 1 is a schematic diagram of a conventional kitchen ventilation structure disclosed in Republic of Korea Utility Model No. 20-0267257, etc., in general, as shown in FIG. 1, a counter 200 in which food cooking utensils called "range" are installed. A range hood 201 is installed above the range hood 201 and an exhaust fan 202 disposed in the range hood is operated to discharge various odors and smoke generated when cooking food to the outside. In FIG. 1, reference numeral 203 denotes a ceiling surface 203 of a kitchen.

In order for the user to select the range hood 201 that suits his or her needs, the range hood 201 removes fine dust, that is, the range hood 201 removes fine dust existing indoors including pollutants generated when cooking food. It is necessary to accurately grasp the ability to reduce the concentration of fine dust in the room by inhaling and discharging it to the outside, and for this, an objective and standard test of the fine dust removal performance of the range hood 201 is required. However, until now, there are virtually no techniques or proposals for objectively testing and testing the fine dust removal performance of the range hood 201.

Republic of Korea Utility Model Publication No. 20-0267257 (2002.03.12. Announcement).

The present invention relates to a device and a method capable of quantitatively and objectively testing and evaluating the fine dust removal performance exerted by a kitchen range hood in relation to the removal of contaminants generated during cooking and other fine dust existing indoors. It was developed to present.

In particular, the present invention can simulate the occurrence of fine dust that occurs in an actual kitchen when food is cooked so that the performance of removing fine dust of the range hood can be objectively evaluated. As the range hood to be tested is operated in, it is possible to accurately measure the removal situation of fine dust and the change in the concentration of fine dust in the kitchen interior, so that the performance of removing fine dust of the range hood can be objectively and quantitatively evaluated. It aims to provide a method.

In order to achieve the above object, in the present invention, an artificial fine dust emission module that generates and diffuses artificial fine dust that simulates contaminants generated during cooking in a kitchen, and artificial fine dust remaining in the kitchen And a residual concentration measuring sensor 120 capable of measuring the residual concentration; The artificial fine dust emission module generates a particle ejection member (1) that injects a test fluid in which artificial fine dust particles are mixed with pressurized air into the air in a heated state, and a test fluid in which an aqueous particle solution and pressurized air are mixed. An aerosol test fluid generating device (2) supplied to the particle ejection member (1), and a particle aqueous solution supply device (3) supplying a particle aqueous solution obtained by mixing artificial fine dust particles and water to the aerosol test fluid generating device (2), and , It is configured to include a pressurized air supply device 4 that supplies pressurized air to the aerosol test fluid generating device 2, and the artificial fine dust particles through the movement of the range hood 301 to be tested and the particle ejection member 1 A range hood's fine dust removal performance test apparatus is provided, characterized in that it measures the residual concentration of artificial fine dust when a normal state of the kitchen interior is made by spraying.

In the above-described testing apparatus of the present invention, the aerosol test fluid generating apparatus 2 is made of a chamber member having an internal space for mixing; The chamber member is provided with a micro atomizer 21 for spraying the aqueous particle solution supplied from the aqueous particle solution supply device 3 into the inner space; The chamber member has a supply port 22 through which pressurized air is supplied from the pressurized air supply device 4, so that the aqueous particle solution sprayed through the micro atomizer 21 and the pressurized supply through the supply port 22 are formed. Air may be evenly mixed in the chamber member to form a test fluid in an aerosol state.

In the present invention, in order to achieve the above object, as a method of testing the fine dust removal performance of a range hood to be tested, the test apparatus according to the present invention is installed in the kitchen room, but the particles are placed on the countertop 200. The ejection member 1 is disposed, and a range hood 301 to be tested is installed vertically above the particle ejection member 1; Operating the range hood 301 under test in a state where the kitchen interior is closed; Driving the artificial fine dust emission module 110 to generate artificial fine dust and injecting it into the kitchen interior; Making the interior of the kitchen in a normal state by making the sprayed artificial fine dust particles evenly diffuse into the interior of the kitchen; And measuring the residual concentration of artificial fine dust when the kitchen interior reaches a normal state. A method for testing the fine dust removal performance of a range hood is provided.

In the present invention, artificial fine dust is generated to have a standard physical quantity determined by circumstances through an artificial fine dust discharge module configured including a particle ejection member, an aerosol test fluid generating device, a particle aqueous solution supply device) and a pressurized air supply device, After creating an objective test environment by simulating the situation where contaminants are generated in the kitchen when cooking food, the residual concentration is accurately measured by the residual concentration sensor after the artificial fine dust is removed by the operation of the range hood to be tested. As a result of the measurement, the effect of objectively and quantitatively measuring the fine dust removal performance exerted by the range hood under test can be evaluated fairly by standardized indicators.

1 is a schematic diagram of a conventional kitchen ventilation structure.
2 is a block diagram for explaining the overall configuration of a test apparatus according to the present invention.
3 is a schematic diagram showing the configuration of an artificial fine dust emission module according to the present invention.
4 is a schematic plan view of a particle ejection member.
5 is a schematic diagram of a kitchen ventilation structure corresponding to FIG. 1 in which a test apparatus of the present invention is installed in order to perform a fine dust removal performance test of a range hood according to the present invention.
6 is a schematic flowchart showing specific method steps of the test apparatus according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The present invention has been described with reference to the embodiment shown in the drawings, but this is described as an embodiment, by which the technical idea of the present invention and its core configuration and operation are not limited. In particular, specific values for various physical quantities, sizes, etc. are presented when describing the present invention, but all of these values correspond to an example, and the present invention is not limited thereto.

Figure 2 is a block diagram for explaining the overall configuration of the test apparatus according to the present invention, the test apparatus 100 according to the present invention, when cooking food, smoke, smell, other pollutants, etc. An artificial fine dust emission module 110 that generates and diffuses artificial fine dust artificially made to form the same test conditions as the environment, and a kitchen after the artificial fine dust is discharged to the outside by the range hood to be tested. It is configured to include a residual concentration measurement sensor 120 capable of measuring the concentration of artificial fine dust remaining in the room ("residual concentration"). In addition, an emission concentration measurement sensor 130 capable of measuring the concentration of artificial fine dust discharged to the outside by the range hood ("emission concentration"), and the concentration of fine dust existing in the kitchen before the test is performed can be measured. A fine dust measurement sensor 140 may be further provided.

3 is a schematic diagram showing the configuration of the artificial fine dust emission module 110. As mentioned above, the artificial fine dust emission module 110 generates artificial fine dust in the interior of the test kitchen to form the same test conditions as the environment in which smoke, odor, and other contaminants are generated when cooking food. It has a function of diffusing, and includes a particle ejection member 1, an aerosol test fluid generating device 2, a particle aqueous solution supply device 3, and a pressurized air supply device 4 as illustrated in FIG. 3.

Specifically, the particle ejection member (1) is a kitchen container used at home and is a member that simulates a situation in which fine dust is generated and rises when food is cooked in a frying pan, and a plurality of injection holes (11) are formed on the upper surface. It consists of a plate-shaped member. Therefore, when the test fluid in the aerosol state in which artificial fine dust particles are mixed with pressurized air is supplied to the particle ejection member (1), the test fluid is ejected into the air through the injection port (11) and is included in the test fluid accordingly. Artificial fine dust particles are sprayed. 4 is a schematic plan view of the particle ejection member 1, as shown in the drawing, the particle ejection member 1 may have a circular plate shape, taking into account the average size of a frying pan generally used at home. Therefore, the diameter of the circular plate can be set to about 300mm, which can be used as the standard for the test. The injection hole 11 may have a diameter of about 3 mm in consideration of the general size of fine dust generated when food is cooked as a test standard.

The particle ejection member 1 is provided with a heater so as to simulate the heating of the frying pan when cooking food. Therefore, when testing the fine dust removal performance of the range hood as described later, the particle ejection member 1 is heated to the temperature specified in the test by the operation of the heater, and the test fluid is sprayed into the air in a heated state. The heating temperature of the particle ejection member 1 may be set so that the temperature of the center surface is about 250 degrees Celsius in consideration of a general temperature when cooking food, and this can be used as a test standard.

The aerosol test fluid generating device 2 is a device that mixes a particle aqueous solution and pressurized air to produce an aerosol-like test fluid containing artificial fine dust in the air, and supplies it to the particle ejection member 1. The aerosol test fluid generating device 2 may be formed of a chamber member having an inner space for mixing. The chamber member constituting the aerosol test fluid generating device 2 may be provided with a micro atomizer 21 for spraying a particle aqueous solution into the inner space, and a supply port 22 for pressurized air is formed. Therefore, the aqueous particle solution is supplied while being sprayed into the inner space of the aerosol test fluid generating device 2 through the micro atomizer 21, and pressurized air through the supply port 22 is also supplied to the inner space of the aerosol test fluid generating device 2 As supplied, the sprayed aqueous particle solution and pressurized air are evenly mixed in the inner space of the aerosol test fluid generating device 2. When the aqueous particle solution is sprayed into the inner space of the aerosol test fluid generating device (2), the size of the sprayed particle aqueous solution is set so that the "Count Mode of Particles" is 0.3 ~ 0.6㎛, which is the standard of the test. I can take it. The mixture of the aqueous particle solution and pressurized air is supplied to the particle ejection member 1 in the form of an aerosol as described above.

The aqueous particle solution supply device 3 may be in the form of a storage tank that can contain an aqueous solution, and contains a particle aqueous solution having a predetermined concentration, that is, a particle aqueous solution that is a mixture of artificial fine dust particles and water. The aqueous particle solution is supplied to the aerosol test fluid generator (2). In the drawing, member number 4 is a pressurized air supply device 4 that supplies pressurized air having a predetermined pressure to the aerosol test fluid generating device 2, and in the drawing, member number 41 indicates the supply amount and supply pressure of pressurized air. It is a regulator 41 to adjust. Particles corresponding to artificial fine dust, that is, particles that are mixed with pure water or distilled water to make a particle aqueous solution, can be KCl (potassium chloride) particles, but other substances other than KCl are used for the formation of artificial fine dust. Can also be used as.

FIG. 5 is a schematic diagram of a kitchen ventilation structure corresponding to FIG. 1 in which the testing apparatus of the present invention is installed in order to perform a fine dust removal performance test of a range hood according to the present invention. As shown in the drawing, a particle ejection member 1 is disposed on the counter 200 in place of cooking supplies such as a frying pan, and a range hood 301 to be tested is installed vertically above the particle ejection member 1. At this time, the vertical length between the lowest part of the range hood 301 and the particle ejection member 1 to be tested may be set to 600 mm, and this may be used as a test standard.

As described above, the test apparatus of the present invention includes a residual concentration measurement sensor capable of measuring the concentration of artificial fine dust remaining in the kitchen interior after the artificial fine dust is released to the outside by the range hood to be tested ( 120) is included, and the residual concentration measurement sensor 120 is spaced a predetermined distance in the horizontal direction from the particle ejection member 1 as shown in FIG. 5, and the particle ejection member 1 and the range hood 301 are tested. It is installed at a point located in the middle between the entrances. As illustrated in the drawing, the residual concentration is spaced approximately 1.5m from the particle ejection member 1 in the horizontal direction, and at a position at a vertical height corresponding to the middle between the particle ejection member 1 and the inlet of the range hood 301 to be tested. It is preferable that the measurement sensor 120 is installed.

In addition to the residual concentration measuring sensor 120, a discharge concentration measuring sensor 130 may be further provided. An emission concentration measurement sensor 130 capable of measuring an emission concentration corresponding to the concentration of artificial fine dust that is sucked by the range hood 301 to be tested and discharged to the outside may be further provided. The emission concentration measurement sensor 130 is installed in a discharge pipe 302 that is connected to the range hood 301 to be tested and exhausted to the outside. In addition, the apparatus of the present invention may be further provided with a fine dust measuring sensor 140 that can simply measure the concentration of fine dust existing indoors. The fine dust measurement sensor 140 may be installed on the ceiling surface 203 of the kitchen.

6 is a schematic flowchart showing specific method steps of the test apparatus according to the present invention. As shown in Fig. 6, after sealing the interior of the kitchen in which the test apparatus of the present invention and the test target range hood 301 equipped with an exhaust fan are installed, the test target range hood 301 is operated (step S1). In this way, after the range hood 301 to be tested is operated, the artificial fine dust emission module 110 is driven to generate artificial fine dust and sprayed into the kitchen interior (step S2). That is, the aerosol test fluid generating device 2 generates a test fluid in an aerosol state in which artificial fine dust is contained in the air, and supplies the test fluid to the particle ejection member 1, and the injection port 11 of the particle ejection member 1 ), the artificial fine dust particles contained in the test fluid are sprayed into the air. At this time, the speed at which the artificial fine dust particles are sprayed into the air is about 0.3 m/s, and this can be used as a test standard. Of course, as described above, such artificial fine dust particles are sprayed while the particle ejection member 1 is heated to a predetermined temperature.

When the range hood 301 to be tested is operated and the artificial fine dust particles are sprayed through the particle ejection member 1, the injected artificial fine dust particles are discharged to the outside and artificial fine dust particles remaining in the kitchen The concentration of artificial fine dust in the kitchen is measured by using the residual concentration sensor 120 to be spread evenly in the kitchen room, and the measured concentration is made to be in a steady state (step S3). That is, the range hood 301 to be tested and the artificial fine dust emission module 110 are continuously operated until a "normal state of the kitchen room" is established.

When the kitchen interior reaches a normal state, the residual concentration of artificial fine dust is measured, and the fine dust removal performance is evaluated based on this (step S4). The range hood's ability to remove fine dust refers to the efficiency of removing contaminants generated during food cooking through the range hood without spreading it indoors, as measured by the residual concentration measurement sensor 120 The artificial fine dust residual concentration value in the normal state of may be used as an indicator of the fine dust removal performance of the range hood 301 to be tested. Of course, in this case, it is preferable to use the average of the results obtained by measuring the residual concentration of artificial fine dust multiple times (for example, 3 or more) when the kitchen room reaches a normal state.

)를 산출하여 이를 시험대상 레인지후드(301)의 미세먼지 제거성능 지표로 삼을 수도 있다. However, when the emission concentration measurement sensor 130 and the fine dust measurement sensor 140 are further provided, the rate of change of the artificial fine dust concentration in the kitchen interior by the calculation of Equation 1 below (

) May be calculated and used as an index of the fine dust removal performance of the range hood 301 to be tested.

[Equation 1]

는 시험대상 레인지후드(302)에 의해 외부로 배기되는 인공 미세먼지의 배출농도 즉, 배출농도 측정센서(130)에 의해 측정된 배출농도이고,

는 시험대상 레인지후드(302)가 작동되어 시험이 이루어지고 있는 상태에서 잔류농도 측정센서(120)에 의해 측정된 인공 미세먼지의 잔류농도이며,

는 시험대상 레인지후드(302)가 아직 작동되지 않아서 시험이 이루어지지 않는 상태에서 주방 실내에 존재하는 미세먼지의 농도 즉, 미세먼지 측정센서(140)에 의해 측정된 미세먼지의 농도이다. In Equation 1 above

Is the emission concentration of artificial fine dust exhausted to the outside by the range hood 302 to be tested, that is, the emission concentration measured by the emission concentration measurement sensor 130,

Is the residual concentration of artificial fine dust measured by the residual concentration measurement sensor 120 while the test target range hood 302 is operated and the test is being performed,

Is the concentration of fine dust existing in the kitchen interior, that is, the concentration of fine dust measured by the fine dust measurement sensor 140 in a state in which the test target range hood 302 has not been operated yet.

를 미세먼지 측정센서(140)에 의해 측정하게 된다. 그리고 주방 실내가 정상상태에 도달한 후에는 배출농도 측정센서(130)를 이용하여 시험대상 레인지후드(301)에 의해 외부로 배기되는 인공 미세먼지의 배출농도

를 측정한다. 측정된

값과

값, 그리고 시험대상 레인지후드가 작동되어 시험이 이루어지고 있는 상태에서 잔류농도 측정센서(120)에 의해 측정된 인공 미세먼지의 잔류농도

를 수학식 1에 대입하여 연산함으로써, 주방 실내의 인공 미세먼지 농도 변화율

를 산출하여, 산출된

를 시험대상 레인지후드(301)의 미세먼지 제거성능 지표로 삼을 수 있는 것이다. When the emission concentration measurement sensor 130 and the fine dust measurement sensor 140 are further provided in the test apparatus of the present invention, the test is started by the fine dust measurement sensor before operating the range hood 301 to be tested. The concentration of fine dust present in the kitchen interior in the state before becoming

Is measured by the fine dust measurement sensor 140. And after the kitchen interior reaches the normal state, the emission concentration of artificial fine dust exhausted to the outside by the range hood 301 to be tested using the emission concentration measurement sensor 130

Measure Measured

Value and

Value, and the residual concentration of artificial fine dust measured by the residual concentration measurement sensor 120 while the test target range hood is operating and the test is being performed

By substituting in Equation 1 and calculating, the rate of change in the concentration of artificial fine dust in the kitchen

By calculating

Can be used as an index of the fine dust removal performance of the range hood 301 to be tested.

As described above, in the present invention, an artificial fine dust emission module 110 comprising a particle ejection member (1), an aerosol test fluid generation device (2), a particle aqueous solution supply device (3), and a pressurized air supply device (4) By generating artificial fine dust so that it has a standard physical quantity determined by circumstances, an objective test environment is created by simulating the situation in which contaminants are generated in the kitchen when cooking food, and then the operation of the range hood under test After the artificial fine dust is removed, the residual concentration is accurately measured by the residual concentration measurement sensor 120. The process by standardized indicators by objectively and quantitatively measuring the fine dust removal performance exerted by the range hood to be tested. The effect of being able to be evaluated is exhibited.

1: Particle ejection member
2: Aerosol test fluid generating device
3: Aqueous particle solution supply device
4: Pressurized air supply device
110: artificial fine dust emission module
120: residual concentration measurement sensor

Claims (4)

delete delete delete As a method of testing the fine dust removal performance of the range hood to be tested using the range hood's fine dust removal performance test device,
The range hood's fine dust removal performance test device generates and diffuses artificial fine dust that simulates pollutants generated during cooking, and measures the residual concentration of artificial fine dust remaining indoors. A sensor for measuring the residual concentration, a sensor for measuring the emission concentration corresponding to the concentration of artificial fine dust discharged to the outside by the range hood under test, and a sensor for measuring the concentration of fine dust present in the room. Includes;
The artificial fine dust emission module generates a particle ejection member that injects a test fluid mixed with artificial fine dust particles into the air in a heated state, and a test fluid mixed with a particle aqueous solution and pressurized air. An aerosol test fluid generator to be supplied, a particle aqueous solution supply device that supplies a particle aqueous solution of artificial fine dust particles and water to the aerosol test fluid generator, and a pressurized air supply device that supplies pressurized air to the aerosol test fluid generator. Includes;
When the range hood to be tested is installed vertically above the particle ejection member and the room is sealed, the concentration of fine dust present in the room

Measuring by the fine dust measuring sensor and then operating the range hood to be tested;
Driving the artificial fine dust emission module to generate artificial fine dust and spraying it into the room so that the artificial fine dust particles are evenly diffused into the room, so that the artificial fine dust concentration is kept in a normal state;
After the room reaches the normal state, the concentration of artificial fine dust in the room

Is measured by the residual concentration sensor, and the concentration of artificial fine dust exhausted to the outside by the range hood to be tested

Measuring by an emission concentration measurement sensor; And
The concentration of fine dust in the room measured before the operation of the range hood under test

, And the residual concentration of artificial fine dust measured after the room reaches a steady state

And emission concentration

Using Equation 1, the rate of change in the concentration of artificial fine dust in the room

Calculating a; Method for testing the fine dust removal performance of the range hood comprising a.
(Equation 1)

Images