KR20150092563A - Apparatus and method for testing weather resistance and arrangement method of the apparatus - Google Patents

Abstract

Disclosed are an apparatus and a method for testing weather resistance, and a method for arranging the apparatus. The apparatus for testing weather resistance efficiently collects ultraviolet light having a small amount of direct light unlike visible light or near-infrared light, with respect to an assisted weather resistance for evaluating light-induced deterioration by solar light and weather resistance of chemical materials such as plastic or the like. The apparatus for testing weather resistance according to the present invention, which estimates the lifespan of light-induced deterioration of a product in a predetermined area, comprises: a square-shaped specimen light receiving unit; and a reflective plate unit having a plurality of reflective plates which are connected to each side of the specimen light receiving unit and are tilted toward the outer side of the specimen light receiving unit as much as a predetermined angle with respect to a normal surface of the specimen light receiving unit. In addition, each side portion of the reflective plates is arranged to be spaced apart from each other.

Description

TECHNICAL FIELD [0001] The present invention relates to a weather resistance test apparatus, a weather resistance test apparatus, a weather resistance test apparatus,

The present invention relates to an apparatus and a method for testing weatherability, and a method of arranging the apparatus. More specifically, the present invention relates to a weathering test apparatus for efficiently collecting ultraviolet rays, which are different from visible light or near-infrared light, in ultraviolet light, which is useful for accelerating weathering test for evaluating light- And a method of arranging the apparatus.

Various chemical products such as plastics, rubbers, films, coatings, paints, and adhesives often contain a polymer material in which organic elements such as carbon, hydrogen, oxygen, and nitrogen are covalently bonded. Therefore, in the chemical products of the present invention, progressive deterioration reaction proceeds by light and heat such as ultraviolet rays.

The rate of the degradation reaction is a major factor in determining the lifetime of a product or material to its failure state. Therefore, understanding the exposure and exposure frequency of ultraviolet and thermal energy, which determine the rate of the degradation reaction, is a basic design factor for product life.

A variety of industrial products in which chemical degradation proceeds by exposure to sunlight outdoors, such as automobiles, ships, rail vehicles, military materials, building materials, civil engineering materials, road and marine installations, electrical and radio facilities, , Solar cell, wind power generation facilities, agricultural products, etc., outdoor and indoor weathering resistance tests are performed by various types of artificial light sources.

The weathering test of the product against the light-induced thermal degradation under daylight exposure environment is carried out by the accelerated weathering tester equipped with the artificial light source with excellent solar simulatedness. However, since the test conditions and the actual conditions of use of the accelerated weathering tester are not the same, it is technically difficult to predict the photothermal life in the actual use environment through the accelerated test results.

One of the most challenging of these technical difficulties is the condensation of ultraviolet light from sunlight that causes photodegradation of polymeric materials.

It is known that ultraviolet rays of sunlight, which cause photodegradation of polymer materials, have different atmospheric penetration and reflection characteristics than visible or near infrared rays, which are used as energy sources in the solar energy field.

Because of this characteristic of ultraviolet ray, ultraviolet ray of sunlight has a characteristic that scattering characteristic during the process of passing through the atmosphere is large, so that the direct light component is relatively less than visible light and the reflection light is not well converged as a general reflector which collects visible light.

In the case of the prior art related to the accelerated weathering test equipment for outdoor use, the light-emitting test sample does not directly face the sun and only the sunlight reflected by the sunlight is used. In the cloudy weather or cloudy weather, There is a problem that it is difficult to expect a light-condensing efficiency.

In the case of the conventional technology, since it is the remote targeting method of concentrating the direct rays of several reflectors using one of the ten reflectors into one sample, the condensing efficiency is largely lowered due to the shaking of the target when the wind is strong, And the specimen is hanging upside down toward the ground, resulting in poor wetting effect.

Also, in the case of the prior art, desert climatic regions in Phoenix, Arizona, USA, reported that cloud glazing could not be used for accelerators on the 76th day of 2004 due to clouds of cloudiness. In cloudy climatic regions such as Florida and central Europe, It is not appropriate to use this device for at least 3,500 hours per year of cleanliness per year.

In addition, since only direct light is condensed, it is difficult to condense ultraviolet light, which is much larger in scattering than visible light or near infrared light, and ultraviolet light (300 to 400 nm) has a specific gravity of about 6% The specific gravity of the ultraviolet ray to the total solar irradiance was only about 3.5%, so that the light collecting ratio of 320 nm ultraviolet ray was only 2 even if the light collecting ratio was 4.

As a problem of the temperature control of the sample accompanied therewith, in the case of the apparatus according to the prior art, the surface temperature of the black panel reaches 90 DEG C even by intensive cooling by the blower attached at the time of condensing, It is possible to cause heat damage and thermal deformation of the general purpose chemical materials and to test the specimens under extreme drying conditions, which is an important cause of the lack of reproducibility of the accelerated weathering test using this device. It is also pointed out that thermal shock problems arise from sudden temperature changes.

That is, according to the prior art, not only a desiccant climate having a high specific gravity of daylight but also an ultraviolet condensation degree capable of achieving substantial accelerating acceleration can not be obtained. In addition, temperature rise and extreme drying conditions of the sample surface, And thermal shocks caused by the above-mentioned problems, and it is not widely used except in some desert areas.

Further, in the conventional concentrating apparatus using the inverted pyramid type reflector, which is attempted in the field of solar energy application, the edge portion of the inverted pyramidal reflector having no substantial converging effect on the sample surface of the light receiving portion can not be removed, There is a problem that the heat collecting part accumulates heat due to condensation and there is no separate cooling device, so that the light converging part is excessively overheated, and the light irradiation of the light receiving part sample surface is not uniform due to the reflection overlapping effect at the corner part, There is a problem that required test reproducibility can not be secured.

Among the solar concentrators using inverted pyramidal reflectors, conical or curved surfaces are not uniformly focused on the entire light receiving portion but focused on the center of the light receiving portion. That is, in the case of a solar concentrator using a conventional inverted pyramid type reflector, a structure optimized for accelerated weathering test for chemical materials such as plastics is not known.

In addition, since the conventional solar reflector has a low reflectance of an ultraviolet ray component compared to a visible ray, only a visible ray and infrared rays are condensed in a state in which the ultraviolet ray condensing efficiency is insufficient, and therefore, the desired ultraviolet ray condensation is insufficient. There is a problem that it can not be applied.

Therefore, in order to solve the above problems, in an accelerated weathering test for evaluating light-induced thermal degradation and weatherability of chemical materials such as plastics, ultraviolet light having a small amount of direct light, unlike visible light or near-infrared light, A weathering test apparatus and method, and a method of arranging the apparatus are required.

In this regard, Korean Patent Laid-Open No. 10-2012-0079705 discloses a technique related to "photothermal acceleration system ".

SUMMARY OF THE INVENTION The object of the present invention is to solve the above-mentioned problems, and it is an object of the present invention to provide a light source device capable of realizing a direct exposure of sunlight by mounting a sample in a position directly facing sunlight, It is possible to efficiently condense the scattered light or the scattered light that is incident on the light source.

It is another object of the present invention to provide an apparatus and a method for preventing light reflected by the specimen light receiving unit from being shaken by the wind and minimizing the influence on the deterioration of the reflector, It is possible.

It is also an object of the present invention to provide a high concentrating ultraviolet light concentrating device capable of eliminating condensing unevenness and obtaining a high degree of ultraviolet condensation in a uniform condensing state as the condensing light is collected through the reflection plate portion with the corners removed.

It is another object of the present invention to provide a reflector having a rectangular shape by defining the relationship between the length of one side of a specimen light receiving part and the length of a side of a plurality of reflectors and the installation angle, It is possible to prevent the sample from overheating due to the heat.

It is also an object of the present invention to improve the specific gravity of ultraviolet rays relative to the total irradiation amount and to suppress the temperature rise due to the condensation of visible and near infrared rays components, by adopting the material of the reflector plate having a high ultraviolet light collecting rate.

It is another object of the present invention to provide a fan capable of directly blowing outside air on one side of a specimen light receiving part based on the surface temperature of a specimen, thereby maintaining a constant black panel surface temperature.

The object of the present invention is to provide a water spray nozzle for spraying water in a mist spraying manner in correspondence with an electronically controlled adjusting device or a solenoid valve on one side of a specimen light receiving part, .

It is another object of the present invention to provide a method and apparatus for controlling a position of a specimen photodetector in accordance with at least one control command among a GPS (Global Positioning System) based program control apparatus and an optical sensor based sun position tracking apparatus, Lt; / RTI >

In order to attain the above object, the present invention provides an apparatus for testing weatherability of a product in a predetermined region, the apparatus comprising: a square specimen light receiving unit and a specimen light receiving unit, And a reflector portion formed of a plurality of reflector plates that are inclined to the outside of the specimen light receiving portion by a predetermined angle with reference to the normal surface of the specimen light receiving portion so that the sides of the plurality of reflector plates are spaced apart from each other .

At this time, the light incident on the first reflector of the plurality of reflectors is reflected first, reaches the second reflector facing the first reflector, and the light reaching the second reflector is reflected second, As the specimen light receiving portion is irradiated, the sun ultraviolet light can be uniformly condensed and irradiated on the entire region of the specimen light receiving portion.

In this case, the predetermined angle is 10 to 20 degrees, and the ratio of the length of each side of the reflector plate to the length of each side of the specimen light receiver may be 8 or less.

을 통하여 정해지며, 상기 L은 상기 복수개의 반사판 각각의 측부의 길이이며, 상기 X는 상기 복수개의 반사판 각각을 상기 수광부의 법선면의 방향으로 입사되는 태양 직사광을 투영한 길이이며, 상기

은 상기 복수개의 반사판 각각의 설치 각도로서 90도에서 상기 소정의 각도를 뺀 값일 수 있다.At this time, the predetermined angle is 10 to 20 degrees, and the length of the side portions of each of the plurality of reflection plates,

L is the length of each side of the plurality of reflectors, X is the length of each of the plurality of reflectors projecting the sun's direct rays incident in the direction of the normal surface of the light receiver,

May be a value obtained by subtracting the predetermined angle from 90 degrees as an installation angle of each of the plurality of reflection plates.

At this time, the specimen light receiving part keeps the temperature of the surface of the black panel constant by blowing the outside air through a blowing fan installed at one side of the specimen light receiving part, and the blowing fan senses the temperature of the black panel in real time Contact type black panel thermometer or non-contact type surface thermometer.

In this case, the water injection nozzle is located at one corner of the specimen light receiving part and performs water spraying in a near mist spraying mode. The water spray nozzle controls the water spraying cycle in accordance with the electronically controlled adjusting device or the solenoid valve can do.

At this time, the surface material of the plurality of reflection plates may be an aluminum plate or an aluminum evaporation film coated with an inorganic thin film layer formed of any one of SiO ₂ , Al ₂ O ₃ and TiO ₂ , An aluminum plate or an aluminum deposited film coated with an organic thin film layer or an aluminum plate or an aluminum deposited film coated with a film layer formed of any one of the fluorine resin and the silicone resin.

At this time, the specimen light receiving unit may be disposed in parallel with the normal plane of the sun as it moves in response to the control command of the sun position tracking apparatus.

According to another aspect of the present invention, there is provided a weather resistance test method for predicting a light-degradation lifetime of a product in a predetermined area, the method comprising: a GPS (Global Positioning System) as it based on the position of the sun-tracking device at least one corresponding movement to the control command of which of the specimen light receiving portion preparation step of preparing a sample light receiving portion is arranged in parallel with the normal plane of the _{sun, SiO 2, Al 2 O 3} , TiO 2 An aluminum plate or an aluminum evaporation film coated with an inorganic thin film layer formed in one layer or an aluminum plate or an aluminum evaporation film coated with an organic thin film layer through any one of a fluorine resin and a silicone resin or formed by any one of the fluorine resin and the silicone resin An aluminum plate or an aluminum evaporated film coated with a film layer as a surface material A coupling step of coupling the plurality of reflection plates to each side of the specimen light receiving part so as to be tilted to the outside of the light receiving part by a predetermined angle with reference to the normal surface of the specimen light receiving part, The light incident on the first reflector of the plurality of reflectors is reflected first and reaches the second reflector facing the first reflector, and as the light reaching the second reflector is reflected a second time, And a weathering test step of testing the weather resistance of the product based on the irradiated solar ultraviolet light uniformly collected in the area.

According to another aspect of the present invention, there is provided a method of arranging weather resistance testing apparatuses according to the present invention, comprising the steps of: The centers of the plurality of reflectors of the second weathering test apparatus located nearest to the first weathering test apparatus are positioned so that the coordinate values of the X and Y axes in the two dimensional coordinate space are different from each other And a center of a specimen light receiving section of the first weathering test apparatus and a center of a specimen light receiving section of the second weathering test apparatus are arranged such that a coordinate value of any one of an X axis and a Y axis Are arranged to be equal to each other.

According to the present invention, scattered light or scattered light incident at various angles on a cloudy day can be efficiently obtained by using a rectangular trumpet-type light collecting device which is subjected to a direct exposure effect of sunlight by placing a sample directly at a position facing the sunlight, .

In addition, according to the present invention, since the light entering the entrance of the reflection plate portion with the edges removed is reflected by the adjacent specimen light receiving portion and is designed to be uniformly irradiated, it is possible to prevent the condensation focus from being shaken by the wind, It is effective.

Further, according to the present invention, there is an effect that a light condensing unevenness is removed as a result of condensing through a corner portion of the reflection plate portion, and a high condensation degree of ultraviolet light can be obtained in a uniform condensed state.

According to the present invention, since the rectangular reflector is defined by defining the relationship between the length of one side of the specimen light receiving portion, the length of the side portions of the plurality of reflectors and the installation angle, it is easy to manufacture and replace the reflector, It is possible to prevent the sample from overheating due to the heat.

Further, according to the present invention, by adopting the material of the reflector having a high ultraviolet light collection ratio, there is an effect that the specific gravity of the ultraviolet ray relative to the total irradiation amount is improved and the temperature rise due to the condensation of the visible ray and the near infrared ray component is suppressed.

In addition, according to the present invention, the temperature of the surface of the black panel can be maintained constant by providing a fan capable of directly blowing the outside air on one side of the specimen light receiving part based on the surface temperature of the specimen.

In addition, according to the present invention, water spray nozzles for spraying water in accordance with the electronically controlled adjusting device or the solenoid valve are installed on one side of the specimen light receiving part, It is effective.

In addition, according to the present invention, as the specimen light receiving unit is moved in response to at least one control command among a GPS (Global Positioning System) -based program control apparatus and an optical sensor-based sun position tracking apparatus, There is an effect that it is disposed against.

1 is a view for explaining an embodiment of the weather resistance test apparatus according to the present invention.
2 is an enlarged view of an apparatus for testing weatherability according to the present invention.
3 is a graph for explaining the optimal ratio of the length of each side of the reflector plate to the length of each side of the specimen light receiving unit in the weathering test apparatus according to the present invention.
4 is a view for explaining a relationship in which multiple reflections are performed in the weathering test apparatus according to the present invention.
5 is a graph for explaining the relationship between the light collection ratio and the space efficiency according to the inclination angle of the reflector in the one-reflection type model.
Fig. 6 is a view for explaining a method of manufacturing the weather resistance test apparatus according to the present invention.
FIGS. 7 to 9 are views for explaining how the reflector length is adjusted in accordance with the inclination angle of the specimen light receiving portion in the weathering test apparatus according to the present invention.
10 is a view for explaining the light collection ratio according to the side angle and the reflector length ratio in the case of the one-reflection type model in the weather resistance test apparatus according to the present invention.
11 is a view for explaining the relationship between the angle of inclination and the length of the reflection plate.
12 is a graph for explaining the relationship between the light collection ratio and the spatial efficiency according to the inclination angle of the reflection plate in the multiple reflection type model.
13 is a view for explaining the optimum inclination angle of the specimen light receiving part according to the number of reflection times.
Figs. 14 to 17 are views for explaining a case where the reflector length is longer than the reference length.
18 is a view for explaining a production example of the weather resistance test apparatus according to the present invention.
Fig. 19 is a view for confirming the effect of the uniformity of the light collection ratio of the portion of the specimen light receiving portion of the weather resistance test apparatus according to the present invention.
20 is a view showing a state in which the weather resistance test apparatus according to the present invention is installed in multiple.
21 is a graph comparing the performance of the weather resistance test apparatus according to the present invention with the prior art.
FIG. 22 is a graph showing cumulative ultraviolet radiation dose for one year through the weathering test apparatus according to the present invention. FIG.
23 and 24 are graphs showing the performance of the weather resistance test apparatus according to the present invention.
Fig. 25 is a view for explaining a first embodiment of a method of arranging multiple weather resistance test apparatuses according to the present invention.
26 is a view for explaining a second embodiment of a method of arranging the weather resistance test apparatus according to the present invention in multiple.
Fig. 27 is a flowchart of a weathering test method according to the present invention.
28 is a flowchart of a method of arranging the weather resistance test apparatus according to the present invention.

The present invention will now be described in detail with reference to the accompanying drawings. Hereinafter, a repeated description, a known function that may obscure the gist of the present invention, and a detailed description of the configuration will be omitted.

Embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shapes and sizes of the elements in the drawings and the like can be exaggerated for clarity.

In describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements.

The ultraviolet rays of sunlight are known to have an atmospheric transmission and reflection characteristic different from that of visible light or near-infrared light, which is used as an energy source in the solar energy field.

Because of this characteristic of ultraviolet ray, ultraviolet ray of sunlight has a characteristic that scattering characteristic during the process of passing through the atmosphere is large, so that the direct light component is relatively less than visible light and the reflection light is not well converged as a general reflector which collects visible light.

According to reports, the optimal inclination angle with the highest solar radiation in the year as the south-facing reference for the stationary system is close to the latitude of the area, for example about 33 ° in Seoul or Daejeon and 24 ° in Jeju Island. In addition, as for the power generation efficiency of the solar cell, it is possible to increase the power generation efficiency by about 20% compared with the fixed type in the case of the short tracking type, and increase the power generation efficiency by up to 50% It is known to be able.

However, since they are based on the entire solar energy or generation amount, in order to develop the outdoor exposure device of chemical materials and products, it is required to be invented differently by the condensation of ultraviolet ray which causes the photo-thermal degradation of the chemical material rather than the condensation of solar energy.

According to the Rayleigh scatter law that the intensity of the scattered light is inversely proportional to the square of the wavelength of the ultraviolet radiation characteristic of the atmospheric transmission characteristic of the ultraviolet ray, Due to the climate characteristics of the region, the effective convergence of ultraviolet scattering light becomes the technical key to the development of all weather weathering test equipment.

In order to provide an accelerated weathering test apparatus with improved acceleration and reproducibility in the field of outdoor weathering test for chemical materials and products such as plastics, which is the object of the present invention, a condensing ratio of 10 times or more is not required, In order to ensure the deterioration reproducibility with respect to exposure, the convergence of about 2 to 5 times is the optimum range.

The reason for this is that in order to ensure reproducibility by accelerating the effects of ultraviolet rays, temperature, and water, which are the three elements of weathering test, to the field environment, it is necessary to balance the influence of temperature and water in accordance with the change of acceleration due to increase of ultraviolet condensation ratio However, when a high intensity ultraviolet radiation intensity exceeding a certain level is used, there is a problem that the corresponding optimum test temperature exceeds 85 ° C, which is a temperature at which thermal damage or thermal deformation of the general-purpose plastic material may occur.

In addition, unlike solar heat condensation, the present invention is limited in that unlike the solar heat condensation, it is necessary to uniformly irradiate all the test piece areas of the specimen light receiving part, the condensing focus should be formed at a specific portion of the light receiving part, or nonuniform condensation unevenness should not be formed.

Therefore, the present invention uses natural sunlight as a light source for performing light-degradation test of chemical materials and products, and facilitates accelerated photo-thermal acceleration test by ultraviolet rays through control of sample temperature and water injection cycle test As for the weathering test equipment, there is a big difference from the technology related to solar energy. That is, the general light collecting device utilized in the solar energy field is not applicable to the outdoor light-gathering facilitated weathering device of the present invention.

Hereinafter, an embodiment of the weather resistance test apparatus according to the present invention will be described with reference to the drawings.

1 is a view for explaining an embodiment of the weather resistance test apparatus according to the present invention. 2 is an enlarged view of an apparatus for testing weatherability according to the present invention.

1 and 2, the weather resistance test apparatus 100 according to the present invention is installed in a frame 200 serving as a support for coupling a plurality of the weather resistance test apparatuses 100. A concrete arrangement method of combining a plurality of the weather-resistance test apparatuses will be described in detail later.

1 and 2, the weather resistance test apparatus 100 according to the present invention includes a specimen light receiving unit 120 and a reflection plate unit 110.

More specifically, the weather resistance testing apparatus 100 according to the present invention is a weather resistance testing apparatus for predicting the light-radiating lifetime of a product in a predetermined area. The weather resistance testing apparatus 100 includes a square specimen light receiving unit 120, A reflection plate 110 formed of a plurality of reflection plates 111, 112, 113, and 114 inclined to the outside of the specimen light receiving unit 120 by a predetermined angle with respect to the normal surface of the specimen light receiving unit, And the side portions (112a, 113a) of each of the plurality of reflection plates are disposed apart from each other.

The plurality of reflectors 111, 112, 113 and 114 are inclined to the outside of the specimen light receiving unit 120 by a predetermined angle with reference to the normal surface of the specimen light receiving unit, When the weather resistance test apparatus 100 is designed in a true shape, the plurality of reflectors 111, 112, 113 and 114 are inevitably rectangular. Here, the normal surface of the specimen light receiving part means a surface arranged perpendicular to the plane of the specimen light receiving part.

That is, as shown in FIG. 1, the four rectangular reflectors are formed in a square horn shape at a specific angle and length.

If the plurality of reflectors 111, 112, 113, and 114 are designed to have a rectangular shape, the apparatus can be easily manufactured and managed in comparison with the prior art, and the weathering test apparatus designed in the shape of the present invention can collect ultraviolet Ultraviolet rays can be uniformly irradiated to the entire area of the specimen light receiving unit 120.

Since the accelerated weathering test method should comprehensively reflect the deterioration effect of environmental factors such as heat and moisture in addition to the effect of light-induced heat by the sun's ultraviolet ray, it is necessary to precisely control the temperature, humidity and water injection effect besides ultraviolet radiation intensity have.

The basic of the photothermal acceleration test method is a method of shortening the test period in which the ultraviolet ray irradiation intensity is increased to reach the cumulative light amount required in the test. However, as the time is shortened, the deterioration effect due to heat, There arises a problem that inconsistency with the deterioration phenomenon given in the above-mentioned Patent Document 1 occurs.

Therefore, there is a high possibility that the reproducibility of the field deterioration becomes insufficient as the ultraviolet radiation intensity is excessively used, and it is necessary to design a test condition capable of achieving a balanced deterioration effect due to heat deterioration due to photo-thermal degradation and moisture invasion.

According to the present invention, as shown in FIG. 1, in order to manufacture a rectangular trumpet-type condensing device without corner portions, a rectangular reflector is fixed at 15 ° ± 5 ° (predetermined angle) to the normal surface of the specimen light- And when the light reflected from the first incident point of the upper edge of the reflector reaches the lower edge of the reflector of the specimen light receiving unit finally, the light entering the entrance of the square horn-type condensing apparatus is reflected through the reflector facing one to three times, It is possible to optimize space utilization and ultraviolet condensation efficiency because it is uniformly irradiated to the entire specimen light receiving part, and it is possible to obtain a high and uniform light collection ratio of up to 6 times of the ultraviolet ray condensation degree Under the conditions of maintaining the test temperature, the maximum ultraviolet condensation ratio of the accelerated weathering test can be obtained The structure was designed to be optimized.

Here, with reference to the specific angle and length, it will be described specifically with reference to the drawings

3 is a graph for explaining the optimal ratio of the length of each side of the reflector plate to the length of each side of the specimen light receiving unit in the weathering test apparatus according to the present invention. 4 is a view for explaining a relationship in which multiple reflections are performed in the weathering test apparatus according to the present invention. 5 is a graph for explaining the relationship between the light collection ratio and the space efficiency according to the inclination angle of the reflector in the one-reflection type model. Fig. 6 is a view for explaining a method of manufacturing the weather resistance test apparatus according to the present invention. FIGS. 7 to 9 are views for explaining how the reflector length is adjusted in accordance with the inclination angle of the specimen light receiving portion in the weathering test apparatus according to the present invention. 10 is a view for explaining the light collection ratio according to the side angle and the reflector length ratio in the case of the one-reflection type model in the weather resistance test apparatus according to the present invention. 11 is a view for explaining the relationship between the angle of inclination and the length of the reflection plate. 12 is a graph for explaining the relationship between the light collection ratio and the spatial efficiency according to the inclination angle of the reflection plate in the multiple reflection type model. 13 is a view for explaining the optimum inclination angle of the specimen light receiving part according to the number of reflection times.

3 and 10, the predetermined angle (specific angle) is 10 to 20 degrees, and the ratio of the length of the sides of each of the plurality of reflector plates to the length of each side of the specimen light receiver is 8 or less Lt; / RTI >

Further, the predetermined angle is 10 to 20 degrees, and the length of the side portions of each of the plurality of reflectors may be determined through the following expression (1).

은 상기 복수개의 반사판 각각의 설치 각도로서 90도에서 상기 소정의 각도를 뺀 값을 의미한다.Wherein X is a length of a projection of sunlight incident on each of the plurality of reflectors in a direction of a normal surface of the specimen light receiving portion,

Means a value obtained by subtracting the predetermined angle from 90 degrees as an installation angle of each of the plurality of reflection plates.

과 상기 복수개의 반사판 각각에 상기 시편 수광부의 법선면의 방향으로 입사되는 태양 직사광을 투영한 길이 X를 통하여 얻어질 수 있는 것이다. 여기서

는, 상기 소정의 각도를 의미한다.More specifically, referring to FIG. 3, H is given as the height of the normal plane of the rectangular reflector, and the length L of the rectangular reflector (i.e., the length of each side of each of the plurality of reflectors) Installation angle

And a length X projecting sunlight incident on each of the plurality of reflector plates in the direction of the normal surface of the specimen light receiving portion. here

Means the predetermined angle.

At this time, the H can be calculated by the following equation (2).

은 상기 복수개의 반사판 각각의 설치 각도로서 90도에서 상기 소정의 각도

를 뺀 값을 의미한다. 상기 소정의 각도

가 10도 내지 20도에 해당하는 것으로 상기 설명한 바와 같이, 상기

은 70도 내지 80도가 바람직하다.In Equation (2), X represents a length of a projection of sunlight incident on each of the plurality of reflectors in the direction of the normal surface of the specimen light receiving portion, and R represents a length of each side of the specimen light receiving portion. In addition,

Is set at 90 degrees as the installation angle of each of the plurality of reflection plates

. The predetermined angle

Is in the range of 10 to 20 degrees. As described above,

Is preferably from 70 to 80 degrees.

Further, the above X can be calculated by the following equation (3).

은 상기 복수개의 반사판 각각의 설치 각도로서 90도에서 상기 소정의 각도

를 뺀 값을 의미한다. 상기 소정의 각도

가 10도 내지 20도에 해당하는 것으로 상기 설명한 바와 같이, 상기

은 70도 내지 80도가 바람직하다.In Equation (3), R denotes the length of each side of the specimen light receiving portion. In addition,

Is set at 90 degrees as the installation angle of each of the plurality of reflection plates

. The predetermined angle

Is in the range of 10 to 20 degrees. As described above,

Is preferably from 70 to 80 degrees.

The equations (1) to (3) are summarized by a plurality of reflection times, as shown in Equation (4).

In order to satisfy the uniform irradiation of the specimen light receiving part as a whole, it is necessary to 1) in the range where the additional reflected light is directed downward, 2) finally, the specimen light receiving part It is necessary to touch the edge of the additional reflection layer. Therefore, as shown in FIG. 3, the additional reflection layer is formed according to the relational expressions of Equations 1 to 4. In this case, since the additional incident angle is changed, The argument is introduced.

의 조건에서 추가 반사광이 아래로 향하므로 다중반사가 가능하고, 시편 수광부 전체의 균일한 조사를 위해서는 i는 2이상의 정수여야 하며 상기 도 3을 참조하여 설명한 1회 반사형 모델의 관계식이 확장된 상기 수학식 4를 만족하여야 한다.
In Equation (4), i denotes the number of multiple reflections. Also,

, I is an integer equal to or greater than 2 in order to uniformly irradiate the entire specimen light receiving part, and the relationship of the one-reflection type model described with reference to Fig. Equation 4 should be satisfied.

5 is a graph for explaining the relationship between the light collection ratio and the space efficiency according to the inclination angle of the reflector in the one-reflection type model.

Referring to FIG. 5, it can be seen that when the inclination angle is 75 degrees, the light-collecting plate length ratio is 3.3 and the theoretical light-collecting ratio is 4.5.

Referring to FIG. 6, the production example of the weathering test apparatus according to the present invention for performing the multiple reflection described with reference to FIG. 4 and FIG.

In addition, referring to FIG. 7 to FIG. 9, when the weather resistance test apparatus according to the present invention is manufactured as shown in FIG. 6, it is preferable that 1) the additional reflected light is directed downward, 2) The reflector length can be adjusted for each inclination angle.

범위에서는 1회 반사형 집광판 모델이외에 집광판 길이를 조정함으로써 2회 반사형 집광판 모델을 선택할 수 있고,

범위에서는 1회 내지 3회 반사형 집광판 모델을 선택할 수 있다. 경사각 75도 일 때 1회 반사형 집광판 모델의 경우 집광판 길이비 3.3, 집광비 4.5의 성능을 갖는데 2회 반사형 집광판 모델의 경우 집광판 길이비는 5.3으로 증가되었지만 이론 집광비 6.5를 얻을 수 있음을 확인할 수 있다.Referring to FIG. 11, in the weather resistance test apparatus according to the present invention, light incident on the first reflector of the plurality of reflectors is first reflected to reach a second reflector facing the first reflector, Light reaching the reflection plate is reflected secondarily and irradiated to the specimen light receiving portion, it can be confirmed that the entire region of the specimen light receiving portion is irradiated with the sun ultraviolet light. 11 and 12 together,

It is possible to select the two-fold reflection type condensing plate model by adjusting the length of the condensing plate in addition to the one-time reflection type condensing plate model,

The reflection type condensing plate model can be selected one to three times. In the case of the one-time reflection type light-condensing plate model at the inclination angle of 75 degrees, the light-collecting plate length ratio is 3.3 and the light-collecting ratio is 4.5. In the case of the two-reflection type light-collecting plate model, the length ratio of the light- Can be confirmed.

범위에서 상기 조건을 만족하도록 제조되었을 경우에는 제 1 반사판의 하단부에 직달 입사한 빛은 제 1 반사되어 바로 수광부로 향하고, 제 1 반사판의 중단부에 직달 입사한 빛은 마주한 제 2 반사판을 거쳐서 수광부로 향하며, 제 1 반사판의 상단부에 직달 입사한 빛은 제 2 반사판과 다시 제 1 반사판을 거쳐서 수광부로 향하므로써 직사광 성분이 3회까지 반사되어 시편 수광부에 균일하게 중복 조사되게 된다.
The multi-reflection type light-collecting plate model basically includes the one-time reflection type light-collecting plate model, and it is possible that the double light-collecting is further performed. For example,

The light directly incident on the lower end of the first reflector is first reflected and directly directed to the light receiving portion and the light directly incident on the intermediate portion of the first reflector passes through the second reflector facing the light receiving portion, And the light directly incident on the upper end of the first reflector is directed to the light receiving unit through the second reflector and the first reflector so that the direct light component is reflected up to three times and uniformly overlapped with the test sample light receiving unit.

12, the rectangular reflection plate is tilted at an angle of 15 ° ± 5 ° with respect to the normal surface of the specimen light receiving portion (at the predetermined angle), and light reflected from the first incident point of the upper edge of the reflection plate The light incident on the entrance of the rectangular trumpet-type light concentrator (weather resistance test apparatus according to the present invention) having the corners removed is reflected through the reflector facing one to three times, and then the specimen The light is refracted to the light receiving part and uniformly irradiated to the entire specimen holder, so that the space use and the light condensing efficiency can be optimized.

In this case, the theoretical condensation ratio can be obtained up to 8 times in terms of solar radiation on the first day of the day, and the accumulated cumulative ultraviolet ray condensing roads observed in the Republic of Korea, which has a lot of cloudy weather, can obtain a high and uniform light collection ratio of about 3 times have.

13 is a view for explaining the optimum inclination angle of the specimen light receiving part according to the number of reflection times. Referring to FIG. 13, it can be seen that various reflection number models can be selected in the range of the inclination angle of 70 to 80 degrees.

Referring to FIG. 10, in the weather resistance test apparatus according to the present invention, in the case of the one-time reflection type model, the shape of the weather resistance test apparatus is most effective in the shape of a truncated cone.

)는 70도 내지 80도의 경우에 가장 이상적인 집광비를 획득할 수 있는 것을 확인할 수 있다.In addition, the side angle (the angle of installation of the rectangular reflector with respect to the specimen light receiving surface

) Can obtain the ideal light collection ratio in the case of 70 degrees to 80 degrees.

More specifically, the performance of the weather-resistant test apparatus with a square-shaped bifurcated shape in which edges are removed (the sides of a plurality of reflectors are spaced apart from each other) will be described. The shape of the weather-resistance test apparatus is represented by square, square, In the case of the structure, the shape of the specimen receiving surface of the specimen receiving part is square, regular hexagon, and regular octagon.

If each reflector has a trapezoidal shape with no corners removed, the structure of the light concentrator is a quadrangular pyramid, a hexagonal pyramid, or an octagonal pyramid. If each reflector has a rectangular shape, the structure of the light concentrator is a quadrangular pyramid, Or the shape of the corner is removed from the octagon.

In addition, in case of triangular-pyramidal or both-wing type, the condensing efficiency is low, which is unsuitable as an accelerated weathering test apparatus. In the case of conical type, it is unsuitable for uneven irradiation such as focusing at the center of the specimen receiving surface.

That is, when rectangular reflectors are used, theoretically, as the number of side reflectors increases in the case of the square, hexagonal, and octagonal pyramids, the collimation uniformity of the irradiated surface of the sample holder becomes low.

In the case of the square-pyramid type, if the reflection effect of the corner portion of the light concentrator is added by using a trapezoid-shaped reflector, the light convergence ratio is partially high at the diagonal portion of the irradiation area, and the gain against the irradiation area is large Therefore, it is preferable to use a rectangular-shaped reflector but a truncated quadrangular-prism-like structure with corners removed.

However, in the case of hexagonal and octagonal pyramids, the light collection ratio at the center of the high light intensity is higher than that of the quadrangular pyramid, but the light reflected by each reflector is uniformly condensed on the sample surface, It is inadequate in terms of space efficiency for the test apparatus.

Fig. 19 is a view for confirming the effect of the uniformity of the light collection ratio of the portion of the specimen light receiving portion of the weather resistance test apparatus according to the present invention.

Referring to FIG. 19, the result of measuring the uniformity of ultraviolet light condensation in a light receiving portion of a quadrangular pyramid type concentrating device (weather test device according to the present invention) having corners removed by using a rectangular reflector can be confirmed.

Specifically, the degree of ultraviolet condensation of the specimen rest position by the ultraviolet light illuminometer in Daejeon area on September 18, 2010 at 2 pm through the weather resistance test apparatus according to the present invention was as follows.

As can be seen from the above results, the ultraviolet light intensity measured at 17 sites has a difference in light intensity between 5.1 and 5.4 without any distinction between the corner and center of the mount, and the uniformity of the ultraviolet light intensity suitable for use as the accelerated weathering test was confirmed .

With continued reference to FIG. 10, it is possible to confirm the light collection ratio, the light collection uniformity, the irradiation area, and the light collection temperature with respect to the structure of the weather resistance test apparatus. When the length of the reflector reaches the opposite end of the bottom surface of the specimen receiving surface of the specimen receiver, the length of the reflector reaches the reference length (twice the number of reflections), and the reflector structure and reflector inclination angle The change in condensing performance can be confirmed.

10, the predetermined angle in the weather resistance test apparatus according to the present invention is 10 to 20 degrees, and the length of the side portions of each of the plurality of reflectors with respect to the length of each side of the specimen light receiving portion May have a value of 8 or less.

)가 높아질수록, 그리고 측면 반사판의 개수가 많아 질수록 높은 집광비를 얻을 수 있지만, 공간적인 효율을 감안할 때, 상기 시편 수광부의 한변의 길이R에 대한 반사판 길이(L)의 비(L/R)는 8이하의 값을 갖는 것이 가장 효율적이다. 이를 초과하는 경우에는 반사판의 길이가 지나치게 길어져 장치 관리 및 운영에 지장을 초래하기 때문이다.
More specifically, the reflector efficiency in Fig. 10 means the ratio (X / R) of the width of the light receiving portion irradiated surface to the orthorhombic extent of the inclined reflector. Here, the side angle (the reference mounting angle based on the specimen light receiving surface of the rectangular reflector

The ratio L / R (L / R)) of the length L of the reflector to the length R of one side of the specimen light receiving part, considering the spatial efficiency, can be obtained as the number of side reflectors increases, ) Is the most efficient to have a value of 8 or less. If it exceeds this value, the length of the reflector becomes excessively long, which may hinder the management and operation of the apparatus.

14 to 17, it can be seen that the length of the reflector is excessively long. More specifically, the portion a in FIG. 14, the portion b in FIG. 15, and the portion C in FIG. 16 correspond to the ratio of the reflector length L to the length R of one side of the specimen light receiving portion defined in the above- (L / R). As a result, even if light is incident on the areas a, b, and c, the light does not reach the specimen light receiving part. In addition, as shown in FIG. 17, when the reflector is longer than the reference length, it can be confirmed that even if the second reflected light is directed downward, uniform irradiation can not be secured with respect to the entire specimen light receiving portion.

More specifically, in FIG. 14, after the second reflection, the light escapes upward. In FIG. 15, the light does not reach the specimen light receiving portion and is repeatedly reflected to the original position. In FIG. 16, It will escape on this. When the length of the reflector is longer than the reference length, the length of the reflector must be adjusted so as to uniformly irradiate the whole of the specimen light receiving portion. Specifically, it is possible to assume an optimum reflector length as described above within a range of lengths between the lengths of the reflector plates shown in FIGS.

That is, when the direct incident light is the reference length, which is the length of the reflector reaching the sample irradiation surface at the bottom of the apparatus at the top of the reflector at the entrance of the weathering test apparatus according to the present invention, It is possible to reach the irradiated surface of the bottom of the apparatus more than several times. However, as shown in FIGS. 14 to 17, a part or all of the incident reflected light can not reach the bottom surface of the apparatus.

In addition, when the incident light reflected at the reference length or more is directed downward according to the inclination angle, the entire area of the specimen light receiving part is irregularly investigated unless the direct incident light of the side reflector peak reaches the edge of the final specimen light receiving part. It is necessary to satisfy the numerical relationship of Equation (1) even if it has a reflection path. That is, considering only the direct light incident perpendicularly to the sample mounting surface except for the scattered light incident at various angles, the length of the reflection plate capable of ensuring the uniformity of the collimation on the sample mounting surface of the sample light receiving portion according to a given inclination angle can be expressed by Equation 1 As the inclination angle increases, the length of the optimum reflector must be increased and the degree of condensation increases accordingly

However, when the inclination angle exceeds 80 DEG, the length of the optimum reflector increases excessively, which makes it difficult to be practically used. The relationship between the light collection ratio and the space efficiency according to the reflection plate inclination angle satisfying these conditions can be confirmed by the graph of FIG.

Hereinafter, the surface material of the reflector of the weather resistance test apparatus according to the present invention will be described.

The surface material of the plurality of reflectors of the weather resistance test apparatus according to the present invention may be an aluminum plate or an aluminum deposited film coated with an inorganic thin film layer formed of any one of SiO ₂ , Al ₂ O ₃ and TiO ₂ , An aluminum plate or an aluminum deposited film coated with an organic thin film layer or an aluminum plate or an aluminum deposited film coated with a film layer formed of any one of the fluorine resin and the silicone resin.

Conventional applications in which the ultraviolet reflector used in the present invention is used include the fields of a reflector for UV curing machine and a solar detoxification for sterilization of medical waste and the like.

The requirements for ultraviolet reflectors used outdoors are high ultraviolet reflectance, durability to use environment and reasonable price. With regard to high ultraviolet reflectance, high purity aluminum is known as the only material that can be practically used. For durability, anodizing treatment, SiO 2 coating, fluorine-based or silicon or acryl-based polymer coating is known.

In terms of price, it is advantageous to use a film in which aluminum is deposited on a polyester (PET) film rather than directly using a high-purity aluminum plate.

As a result of the studies conducted for the practice of the present invention, a high purity aluminum plate exhibited the best ultraviolet reflectance in tests conducted with various materials. When exposed to the outdoor environment, it was most preferable that the SiO 2 thin film was coated to prevent surface oxidation.

The reflectance of ultraviolet light was low in the case of silver or titanium thin film coating, and the reflectance of ultraviolet light was also relatively low in the multi-layer coated aluminum plate which was developed for reflection of the visible ray center for solar cell.

In the case of the aluminum evaporated film, the ultraviolet reflectance is superior to the aluminum plate but the durability is insufficient. However, the price is very cheap, so it is possible to use it in consideration of the replacement cycle or to use a thin film protective coated film.

Hereinafter, a production example of the weather resistance test apparatus according to the present invention will be described with reference to the drawings.

18 is a view for explaining a production example of the weather resistance test apparatus according to the present invention.

18, the specimen light receiving portion of the weather resistance testing apparatus according to the present invention includes at least one specimen 121, 122, 123, 124, 125, and the contact type black panel thermometer 130 or the non- And may include a surface thermometer (not shown), may include a blowing fan 150, and may include a blowing fan protection box 160 for protecting the blowing fan.

In addition, it may include at least one water injection nozzle 141, 142.

That is, the specimen light receiving portion of the weather resistance testing apparatus according to the present invention keeps the temperature of the surface of the black panel constant by blowing the outside air through the blowing fan installed on one side of the specimen light receiving portion, Can be interlocked with a contact-type black panel thermometer or non-contact specimen surface thermometer that senses the temperature of the sample in real time.

The temperature that is the standard for the photo-thermal test is the temperature that the light-receiving material and the surface of the product actually reach, which is a different temperature from the normal atmospheric temperature and thus is hard to obtain with general climate information. The surface temperature of products that receive light in daylight exposure environments often absorbs the highest radiant energy to reach high temperatures when they have a black color. Therefore, when the surface color of the product is assumed to be black, the surface temperature of the light-receiving product is referred to as a black panel temperature (BPT).

In the accelerated photodegradation test, the reference test temperature is the black panel temperature, and the weather resistance test apparatus according to the present invention is equipped with a thermometer capable of measuring the black panel temperature.

As described above, the weathering test apparatus according to the present invention can cause excessive heat deterioration and thermal damage due to temperature rise of the specimen stand due to light condensation. Therefore, by using a test specimen surface thermometer such as a black panel thermometer, . For this purpose, a fan capable of blowing external air directly to the surface of the specimen was installed. In conjunction with the surface thermometer, tests conducted in Daejeon, Korea, were able to maintain the black panel surface temperature at 60 ℃ or less even at the maximum condensation, It is possible to suppress the damage of the test piece due to thermal shock.

Further, the weather resistance test apparatus according to the present invention includes a water spray nozzle positioned at one side of a corner of the specimen light receiving part and performing water spraying in a near mist spray manner, wherein the water spray nozzle is an electronically controlled adjusting device or a solenoid valve It is possible to control the water jetting period in accordance with the water jetting period.

More specifically, in order to improve the deterioration acceleration and reproducibility by moisture, by using an electronically controlled adjusting device and a solenoid valve which can control the spraying cycle variously according to a given cycle test condition in the vicinity of the specimen holder, In addition to the effects of artificial water spraying, the specimen is immersed in the sun and the wetting effect due to rain and dew are given as natural conditions. And the like.

It is difficult to expose the surface of the specimen to precipitation by looking at the land opposite to the sun by the prior art accelerated weathering tester of the prior art. Even after the dew is formed, the water droplet easily falls to the bottom and the wetting effect of the surface of the specimen becomes insufficient However, in the present invention, since the surface of the specimen is opposite to the sky, the natural precipitation effect and the wetting effect due to dew formation can be acted as it is.

Further, as the specimen light receiving section of the weathering test apparatus according to the present invention moves in response to at least one control command among a GPS (Global Positioning System) -based program control device and an optical sensor-based sun position tracking device, It can be arranged parallel to the normal plane. Here, the normal surface of the above-described sun means a plane formed perpendicular to the direction in which the sun is irradiated.

More specifically, in the present invention, a solar tracker is used to place a specimen holder surface (surface of a specimen receiver) parallel to the normal plane of the sun through a sun position tracking device for effective solar light collection.

As a tracking device used in this case, a conventionally used control method based on a program, a program control method using a global positioning system (GPS) method, an optical sensor method, and a hybrid method of these methods can be used. According to the study of the present invention, it is difficult to track the sun position by the optical sensor due to the atmospheric change of clouds in the general climate region such as Korea where the sunlight is insufficient, so that it is used for tracking the sun position of the outdoor collecting type accelerated weathering test apparatus The optical sensor method is more disadvantageous than the program method or the combination of the program and the optical sensor. Therefore, in the present invention, it is recommended to use the tracking method used in the solar tracking device as a program method or a combination of a program and an optical sensor.

Hereinafter, the performance of the weather resistance test apparatus according to the present invention will be described with reference to the drawings. 20 is a view showing a state in which the weather resistance test apparatus according to the present invention is installed in multiple. 21 is a graph comparing the performance of the weather resistance test apparatus according to the present invention with the prior art. FIG. 22 is a graph showing cumulative ultraviolet radiation dose for one year through the weathering test apparatus according to the present invention. FIG. 23 and 24 are graphs showing the performance of the weather resistance test apparatus according to the present invention.

Specifically, FIG. 20 shows an apparatus for testing weatherability according to the present invention mounted on a solar tracker operated by a mixed sun position tracking method of a program and an optical sensor. The device is equipped with 16 square-bell-shaped condensers in a 4X4 arrangement.

The ultraviolet irradiation amount of the stationary outdoor exposure test station fixed at 35 ° south-east during the day observed by the ultraviolet ray illuminometer in the Daejeon area from 6:00 am to 19:00 pm on June 1, 2010 and the ultraviolet irradiation amount Can be confirmed through FIG.

As a result of the comparison test, it was confirmed that the ultraviolet condensation ratio of about 434% was obtained as compared with the stationary type apparatus in which the weather resistance test apparatus according to the present invention was arranged in the south-east direction.

As described above, it is known that, even in the case of having a high ultraviolet condensation degree on a clear day, the cumulative ultraviolet condensation degree in the long term is close to one times as large as that in a general climate region including a lot of cloudy weather, As shown in FIG. 22, the cumulative ultraviolet radiation dose was 2.5 times or more, which is a minimum of 2.5 times the monthly average, as shown in the cumulative ultraviolet radiation dose amount performed for one year from January to December 2012.

The results of the weathering-type accelerated weathering test carried out during the convergence test in 2012 by mounting a general-purpose polystyrene (GPPS) specimen having a size of 68 mm x 47 mm x 3 mm on the weather resistance test apparatus manufactured in the production example of the present invention are shown in Figs. As shown in the graph of chromaticity change according to cumulative ultraviolet radiation amount and test period shown in FIG. 24, degradation behavior similar to the weathering test result by the fixed outdoor exposure performed at an inclination angle of 35 ° to the south was shown.

The test site for the weathering test apparatus according to the present invention was tested in Jangdong, Yuseong-gu, Daejeon, Republic of Korea. The test period required for 500MJ / m2 exposure based on the UV exposure in the range of 300nm to 400nm was 641 Day, the test of the weathering test apparatus according to the present invention took 229 days, and the same test results were obtained, and the acceleration effect of about 2.8 times was obtained.

Indoor acceleration tests using the Xenon-arc tester indicated by the reference "SAE J1960" of Automobile Exterior Materials of Automobiles by the American Society of Automotive Engineers showed that the total test time required to reach the same ultraviolet dose was 158 days, The acceleration effect is 4.0 times as much as the fixed exposure test based on the irradiation dose.

As described above, the surface chromaticity change of the polystyrene specimen as shown in FIGS. 23 and 24 is similar to that of the conventional light exposure test using the fixed exposure test and the photo-thermal degradation using the weather resistance test apparatus according to the present invention, , Indoor stimulation test using Xenon - arc light source shows inconsistent results with natural deterioration phenomenon by fixed exposure test after exposure to ultraviolet rays of 200 MJ / m2 or more.

As described above, the weathering test apparatus according to the present invention can realize excellent deterioration reproducibility with respect to field deterioration due to the use of actual natural sunlight as a light source and accelerate light degradation comparable to an indoor accelerated test apparatus using a xenon-arc light source Outdoor weathering tests can be carried out in the long-term accelerated test in the Daejeon area, which is a general climate area with a lot of clouds.

Hereinafter, the weather resistance test method according to the present invention will be described. As described above, the description of the technical details overlapping with the weather resistance test apparatus according to the present invention will be omitted.

Fig. 27 is a flowchart of a weathering test method according to the present invention.

27, the weather resistance test method according to the present invention is a weather resistance test method for predicting the light-degradation lifetime of a product in a predetermined area, which is based on a global positioning system (GPS) (S100) for preparing a specimen light receiving portion arranged in parallel with the normal plane of the sun is firstly performed.

After step S100, an aluminum plate or an aluminum deposited film coated with an inorganic thin film layer formed of any one of SiO ₂ , Al ₂ O ₃ , and TiO ₂ , aluminum film coated with an organic thin film layer through any one of fluorine resin and silicone resin, A plurality of reflector preparing steps S110 to prepare a plurality of reflectors having a surface or an aluminum plate or an aluminum evaporated film coated with a film layer formed of any one of the fluororesin and the silicone resin, It proceeds.

After the step S110, a coupling step (S120) for coupling the plurality of reflection plates to each side of the specimen light receiving part is performed so as to be tilted to the outside of the specimen light receiving part by a predetermined angle with reference to the normal surface of the specimen light receiving part.

After step S120, light incident on the first reflector of the plurality of reflectors is firstly reflected to reach a second reflector facing the first reflector, and light reaching the second reflector is reflected by the second reflector , A weathering test step (S130) is performed in which the entire region of the specimen light receiving portion is uniformly condensed and the weather resistance of the product is tested based on the irradiated solar ultraviolet ray.

Hereinafter, a method of arranging the weather resistance test apparatus according to the present invention will be described. As described above, the description of the technical details overlapping with the weather resistance test apparatus according to the present invention will be omitted.

The method for arranging the weather resistance test apparatus according to the present invention is a method for arranging each of the weather resistance test apparatuses in multiple, and will be described separately for the second embodiment and the first embodiment.

Fig. 25 is a view for explaining a first embodiment of a method of arranging multiple weather resistance test apparatuses according to the present invention. 26 is a view for explaining a second embodiment of a method of arranging the weather resistance test apparatus according to the present invention in multiple. 28 is a flowchart of a method of arranging the weather resistance test apparatus according to the present invention.

28, the method for arranging the weather resistance test apparatus according to the present invention is characterized in that in the method for arranging the weather resistance test apparatus according to the present invention in multiple, the center of the first reflector of the first weather resistance test apparatus, The center of the second reflector nearest to the first reflector among the plurality of reflectors of the second weathering test apparatus located nearest to the first weather resistance test apparatus is arranged such that the coordinate values of the X and Y axes are different from each other in the two- (S200) is performed.

After the step S200, the center of the specimen light-receiving part of the first weathering test device and the center of the specimen light-receiving part of the second weathering test device are set such that any coordinate value of the X-axis and the Y- The second arranging step S210 of arranging them so as to be equal to each other is proceeded.

In the present invention, by using a rectangular trumpet-type condensing device (weathering test apparatus according to the present invention) with its corners removed, a square specimen holder is inevitably used, and four rectangular reflectors are placed on the sides of the square specimen holder, (+) Shape when the specimen holder is viewed from the front by mounting the specimen holder at an inclination angle of 15 ° ± 5 °.

Considering the length of the individual reflector compared to the total area of the specimen holder, it is possible to arrange a plurality of concentrator devices of a suitable size specimen holder and the corresponding reflector size in various ways, rather than being made of the accelerated weathering- It is suitable to use.

As shown in FIG. 25, the method of mounting the unit light collecting device on a plane includes a first embodiment in which the reflection plate and the reflection plate are staggered, and a second embodiment in which the reflection plate and the reflection plate are disposed in contact with each other, There is an example.

As a result of the study for carrying out the present invention, the arrangement of the weathering test apparatus according to the second embodiment is characterized in that the scattered light is slightly received, so that the degree of ultraviolet light condensation is larger than that of the first embodiment, Therefore, both the second embodiment and the first embodiment can be used in the present invention. However, when considering the efficiency of space allocation, the first embodiment may be recommended.

25, the center 11 of the first reflector of the first weathering test apparatus 10 and the second weathering test apparatus 10 disposed in the closest proximity to the first weathering test apparatus 10, The center (21) of the plurality of reflectors of the test apparatus (20) nearest to the first reflector is arranged such that the coordinate values of the X and Y axes are different from each other in the two-dimensional coordinate space.

The center 12 of the specimen light receiving section of the first weathering test apparatus 10 and the center 22 of the specimen light receiving section of the second weathering test apparatus 20 are located in the X- Axis are arranged so that one of the coordinate values is equal to each other.

26, the center 31 of the third reflector of the third weathering test apparatus 30 and the fourth weathering end located in the closest proximity to the third weathering test apparatus 10, as shown in FIG. 26, A center 41 of a plurality of reflectors of the test apparatus 40 that is closest to the third reflector is arranged such that one of the coordinate values of the X and Y axes is the same in the two-dimensional coordinate space. That is, the coordinate values in the Y-axis are the same in Fig.

As described above, according to the weathering test apparatus and method and the method of arranging the apparatus according to the present invention, the sample is placed in a position directly facing the sunlight to be exposed to direct sunlight, By using the weathering test apparatus, it is possible to efficiently collect scattered light or scattered light incident from various angles on a cloudy day

As described above, the apparatus and method for testing weatherability of the present invention and the method for arranging the apparatus according to the present invention are not limited to the configuration and method of the embodiments described above, but the embodiments may be modified variously All or some of the embodiments may be selectively combined.

100; Weathering test equipment
200; Frame 110; The reflector portion
111, 112, 113, 114; A plurality of reflectors
112A, 113A; Side of reflector
120; Sample probe
121, 122, 123, 124; Psalter
130; Contact timing Black panel thermometer
140; A water spray nozzle 150; Blowing fan
160; Ventilating fan protection box
10; A first weathering test apparatus 20; Second Weathering Test Device
30; A third weathering test apparatus 40; The fourth weathering test apparatus
11; A center 21 of the first reflector; The center of the second reflector
31; The center 41 of the third reflector; The center of the fourth reflector
12; The center of the specimen light-receiving section of the first weathering test apparatus
22; The center of the specimen light-receiving section of the second weathering test apparatus

Claims (10)

1. A weathering test apparatus for predicting a light-heat-degradation lifetime of a product in a predetermined area,
A square shaped specimen receiving section; And
And a plurality of reflection plates connected to respective sides of the specimen light receiving unit and formed of a plurality of reflection plates inclined to the outside of the specimen light receiving unit by a predetermined angle based on the normal face of the specimen light receiving unit,
And the side portions of the plurality of reflectors are spaced apart from each other. The method according to claim 1,
Light incident on the first reflector of the plurality of reflectors is reflected first and then reaches a second reflector facing the first reflector so that the light reaching the second reflector is reflected second, As investigated,
Wherein the solar ultraviolet light is uniformly condensed and irradiated on the entire region of the specimen light receiving section. The method according to claim 1,
The predetermined angle is 10 to 20 degrees,
Wherein the ratio of the length of each side of each of the plurality of reflectors to the length of each side of the specimen light receiving portion has a value of 8 or less. The method according to claim 1,
The predetermined angle is 10 to 20 degrees,
Wherein a length of a side portion of each of the plurality of reflectors,

Wherein L is a length of a side portion of each of the plurality of reflectors, X is a length of a projected sunlight incident on each of the plurality of reflectors in a direction of a normal surface of the specimen light receiving portion,

Is a value obtained by subtracting the predetermined angle from 90 degrees as an installation angle of each of the plurality of reflection plates. The method according to claim 1,
The specimen light-
The outside air is blown through the blowing fan installed on one side of the specimen light receiving part to keep the surface temperature of the black panel constant,
The air-
Wherein the temperature sensor is interlocked with a contact type black panel thermometer or a non-contact type surface thermometer for sensing the temperature of the black panel in real time. The method according to claim 1,
And a water spray nozzle located at one side of the edge of the specimen light receiving part and performing water spraying by a near mist spray method,
Wherein the water spray nozzle controls the water spraying cycle in correspondence with the electronically controlled adjusting device or the solenoid valve. The method according to claim 1,
The surface material of the plurality of reflector plates may be,
An aluminum plate or an aluminum deposited film coated with an inorganic thin film layer formed of any one of SiO ₂ , Al ₂ O ₃ and TiO ₂ ,
An aluminum plate or an aluminum evaporated film coated with an organic thin film layer through any one of a fluorine resin and a silicone resin,
Wherein the film is an aluminum plate or an aluminum evaporation film coated with a film layer formed of any one of the fluorine resin and the silicone resin. The method according to claim 1,
The specimen light-
And is disposed in parallel with the normal plane of the sun as it moves in response to a control command of the sun position tracking device. A weather resistance test method for predicting a light-degradation lifetime of a product in a predetermined area,
A specimen light receiving section for preparing a specimen light receiving section disposed parallel to the normal plane of the sun as it moves in response to at least one control command among a GPS (Global Positioning System) -based program control device and an optical sensor-based sun position tracking device step;
An aluminum plate or an aluminum evaporation film coated with an inorganic thin film layer formed of any one of SiO ₂ , Al ₂ O ₃ and TiO ₂ , an aluminum plate or an aluminum evaporation film coated with an organic thin film layer through any one of fluorine resin and silicone resin A plurality of reflection plates for preparing a plurality of reflection plates made of a surface material of an aluminum plate or an aluminum evaporation film coated with a film layer formed of any one of the fluorine resin and the silicone resin;
A coupling step of coupling the plurality of reflection plates to each side of the specimen light receiving unit so as to be tilted to the outside of the specimen light receiving unit by a predetermined angle with reference to the normal surface of the specimen light receiving unit; And
The light incident on the first reflector of the plurality of reflectors is reflected first and then reaches the second reflector facing the first reflector, and as the light reaching the second reflector is reflected second, And a weather resistance test step of testing the weather resistance of the product on the basis of irradiated solar ultraviolet light uniformly collected in the entire area. A method for multiple arrangement of a weathering test apparatus according to any one of claims 1 to 8,
The center of the first reflector of the first weathering test apparatus and the center of the second reflector nearest to the first reflector among the plurality of reflectors of the second weathering test apparatus placed in the closest proximity to the first weathering test apparatus, A first arraying step of arranging coordinate values of the X-axis and the Y-axis in the space so as to be different from each other; And
The center of the specimen light receiving portion of the first weathering test device and the center of the specimen light receiving portion of the second weathering test device are arranged such that coordinate values of any one of the X and Y axes in the two- 2 < / RTI > arraying step.

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