KR20030035287A - A Measurement Device For Penetration Ratio of An Ultraviolet Rays - Google Patents

Abstract

PURPOSE: An apparatus for measuring the transmissivity of ultraviolet rays is provided to easily identify the transmissivity of ultraviolet rays and measure the transmissivity of ultraviolet rays without a limit on time and space. CONSTITUTION: A case(10) is provided to secure an object to be measured, at an upper part. A UV irradiator is embedded in the case for irradiating UV rays to a lens which is the object to be measured. A light receiving sensor(20), photo diode, senses amount of UV rays having transmitted to the lens for converting the sensed amount of UV rays into microvoltage. A timer includes an A/D converter converting the microvoltage of the light receiving sensor into a predetermined band of frequency. A microprocessor converts the frequency into figures for comparing and judging data. An LED bar(60) receives compared data of the microprocessor for displaying the data, and is arranged in a row on one side of the case. A digital figure plate(70) receives the compared data of the microprocessor on the other side of the case to be identified with naked eyes.

Description

Ultraviolet ray transmittance measuring device {A Measurement Device For Penetration Ratio of An Ultraviolet Rays}

The present invention relates to an ultraviolet measuring device that can represent the transmittance of ultraviolet rays as a numerical value, by irradiating a predetermined ultraviolet ray to the object to be irradiated by the light receiving sensor detects the amount of ultraviolet rays transmitted through the object and converts it into a minute current again timer The present invention relates to an ultraviolet transmittance measuring apparatus, which is applied to a LED bar and a digital number plate by comparing and analyzing a program code reference value of a memory and a frequency obtained by converting a microcurrent applied to the measured timer.

In general, the increase in ultraviolet rays caused by the destruction of the ozone layer today is expected to have a significant negative impact on future human activities. Due to this, the damage of the indoor ultraviolet light is not small, and in particular, the indoor ultraviolet light is mostly faced by the eyes, so the long-term irradiation on the eyes of the human organs has a problem that the damage is also increasing day by day.

As the ozone layer is destroyed by freon gas and air pollution caused by such rapid industrial development, the sun protection sunglasses, automobile shading film, and sun cream that can block the ultraviolet rays directly emitted from the destroyed ozone layer are often used in our real life for health reasons. It is used.

Although, such as automotive shading film, sunscreen sunglasses and sunscreen creams advertise 100% UV protection in advertising, but how much to actually block the amount of UV light is left to the manufacturer's conscience or know. There is a problem that there is no way.

In addition, the optician can not immediately confirm to the customer whether the lens recommended to the customer can block the harmful ultraviolet rays, there is a problem in forming a trust with the customer.

Therefore, the present invention has been made in view of the above-described conventional problems, the first object of the present invention is easy to move and use, UV transmittance measuring device that can measure the lens used for blocking UV at any place To provide a device.

The second object of the present invention is to provide a light receiving sensor for converting the amount of ultraviolet rays applied to the micro voltage to display the blocking rate of the UV blocking lens, and to convert the minute voltage applied from the light receiving sensor unit back to the frequency wavelength band. It is to provide an ultraviolet transmittance measuring device having a timer including an A / D converter.

Objects of the present invention, the main switch 12 is provided on one side of the case 10 to control the power supplied from the power supply terminal 11;

An irradiating part 13 which is bent upward from the case 10 and integrally formed so as to irradiate ultraviolet rays to the lens 300 mounted on the upper center of the case 10, and is installed downward on the bottom surface of the irradiating part 13. UV light irradiator 13a;

An operation switch 14 electrically connected to control the light emission of the UV light irradiator 13a with respect to the power applied from the main switch 12;

A light receiving sensor embedded in a central portion of the case 10 so as to detect an amount of ultraviolet light transmitted through the lens 300 and convert it into a micro voltage, and is located on a vertical line with the UV light irradiator 13a;

A timer 30 including an A / D converter for converting the frequency into a frequency for a predetermined time in proportion to the minute voltage output from the light receiving sensor;

A memory 40 electrically connected to the timer 30 and having a reference value of a predetermined program code stored therein;

A microprocessor (50) for comparing and determining a reference value of the memory (40) by converting it into a numerical value;

Receiving and displaying the comparison data of the microprocessor (50), LED bar (60) arranged in a line on the upper side of the case (10); And

Receiving the comparison data of the microprocessor 50, the digital number plate 70 is installed on the other side of the case 10 to identify with the naked eye; is achieved by the ultraviolet transmittance measuring device, characterized in that consisting of.

In addition, the light receiving sensor is preferably a photodiode (20).

In addition, the case 10 is formed integrally with the irradiation part 13 by die casting casting, and the material is preferably aluminum alloy.

Other objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings.

1 is a perspective view of an ultraviolet transmittance measuring apparatus according to the present invention,

2 is a block diagram of an ultraviolet transmittance measuring apparatus according to the present invention;

3 is a state of use of the ultraviolet transmittance measuring apparatus according to the present invention,

Figure 4 is a flow chart according to the operating state of the ultraviolet transmittance measuring apparatus according to the present invention.

<Description of the code according to the main part of the drawing>

10: Case 11: power terminal

12: main switch 13: irradiation part

13a: UV light irradiator 14: operation switch

20: photodiode 30: timer

40: memory 50: microprocessor

60: LED bar 70: digital number plate

100: UV transmittance measuring device 200: power cable

300: lens

Next, the ultraviolet transmittance measuring apparatus according to the present invention will be described with reference to the accompanying drawings.

1 is a perspective view of an ultraviolet transmittance measuring apparatus according to the present invention, Figure 2 is a block diagram of the ultraviolet transmittance measuring apparatus according to the present invention, Figure 3 is a state diagram of the use of the ultraviolet transmittance measuring apparatus according to the present invention.

As shown in Figure 1, 2 and 3, the measuring device 100 is placed in the upper part of the measurement object, the case 10, each component is built-in, the case 10 is embedded in the measurement Applying a UV light irradiator 13a for irradiating ultraviolet rays to the lens 300 as a target, a light receiving sensor for detecting the amount of ultraviolet light transmitted through the lens 300 and converting it into a small voltage, and a small voltage of the light receiving sensor And a timer 30 including an A / D converter (not shown) for converting to a frequency of a predetermined band, and a microprocessor 50 for quantifying the data into data and determining the result.

Here, the case 10 is typically manufactured by a die casting casting method used to manufacture a housing of a precision product, the material of which is aluminum alloy.

In addition, in order to be able to irradiate the ultraviolet rays to the lens 300 placed on the upper portion of the case 10, the central portion of one side edge of the case 10 is bent upwards to form the irradiation part 13 integrally, The UV light irradiator 13a is built in the bottom of the irradiator 13, and the light source of the UV light irradiator 13a is preferably a halogen lamp having a capacity of about 15 Watts.

In addition, a light receiving sensor is built into the lower side of the case 10 with the lens 300 interposed therebetween, and the light receiving sensor measures the amount of ultraviolet light passing through the lens 300. It is preferable to use the photodiode 20 by sensing and converting it into a small voltage.

On the other hand, the microprocessor 50 is electrically connected to the timer 30, the timer 30 has a built-in A / D converter (not shown) to convert the minute voltage of the photodiode 20 of the electrical pulse form To convert to frequency.

Here, the A / D converter (not shown) generates a frequency of a predetermined band proportional to the capacity of the small voltage applied from the photodiode 20, and eventually converts an analog voltage into a pulse shape. will be.

The converted frequency is transmitted to the microprocessor 50 and processed by a reference value of a predetermined program code stored in the memory 40. The microprocessor 50 digitizes the frequency based on the program code. Determination is made by comparing with the built-in reference value.

At this time, the reference value is stored in the memory 40 provided to interoperate with the microprocessor 50, and the microprocessor 50 reads the reference value stored in the memory 40 and compares it with the digitized frequency. Done.

In addition, one side of the case 10 has a built-in LED bar 60 to emit light, the other side is provided with a digital number plate 70 can be confirmed by comparing the wavelength band and transmittance of the frequency.

The LED bar 60 is formed by arranging a plurality of LEDs that emit light corresponding to each unit in a line inside the case 10 to display the comparison data to the microprocessor 50 in a wavelength band of 300 nm to 400 nm. .

In addition, the digital number plate 70 displays the compared data so that the transmittance (%) can be confirmed.

The LED bar 60 from above is arranged so that a total of 10 LEDs display each 20 nm unit, and the digital number plate 70 bundles three 7-segment diodes so that they can be represented numerically to transmittance of three digits. consist of.

In addition, a power terminal 11 is provided below the edge of the case 10 to supply power through the power cable 200, and a button-type main switch to control power applied from the power terminal 11. 12 is mounted.

In addition, the power terminal 11 is made of a male socket, the power cable 200 is fitted to be detachable.

In addition, in order to selectively control whether the UV light irradiator 13a emits light with respect to power applied from the main switch 12, the operation switch 14 electrically connected to the main switch 12 is pressed to operate. It protrudes on the upper part of the case 10 so as to make it easy.

Hereinafter, an operation procedure of the ultraviolet transmittance measuring apparatus will be described in detail with reference to FIG. 4.

Figure 4 is a flow chart according to the operating state of the ultraviolet transmittance measuring apparatus according to the present invention. As shown in FIG. 3, the measuring device 100 receives a voltage of about 85 to 264 V AC by pressing the main switch 12.

In addition, the digital number plate 70 together with the diode of the LED bar 60 by the applied power is turned on all the numbers '100', the LED bar 60 is turned off after about 2 to 3 seconds, the The digital number plate 70 maintains a state in which it is lit by the number '000' and waits for an initialization state. (S20)

When the operation switch 14 installed on the case 10 is pressed while the main switch 12 is in the ON state as described above, main power is applied to the UV light irradiator 13a.

Then, the UV light irradiator 13a irradiates ultraviolet rays to the lens 300, which is the measurement target placed on the center, by the applied power. At this time, the irradiation time of the UV light irradiator 13a is about 4 to 7 seconds. The ultraviolet ray transmitted through the lens 300 is transmitted to the photodiode 20 (S40).

In addition, the photodiode 20 detects ultraviolet rays transmitted through the lens 300 for about 4 to 7 seconds along with the irradiation time of the UV light irradiator 13a, and then converts the detected ultraviolet rays into minute voltages. The converted minute voltage is transmitted to the timer 30 (S50).

The timer 30 converts the minute voltage into a digital frequency of a predetermined band through a built-in A / D converter (not shown), and the converted frequency is transmitted to the microprocessor 50 (S60).

In addition, the frequency transmitted to the microprocessor 50 is compared with the reference value based on the reference value of the predetermined program code stored in the memory 40 (S70).

At this time, if re-measurement is desired, press the operation switch 14 again to delete the existing measurement value stored in the memory 40, LED bar 60 is all turned off and at the same time the digital number plate 70 is' 000 'Stay lit by the number (S80)

The microprocessor 50 determines the irradiation time of the UV light irradiator 13a by the program code stored in the memory 40, and the irradiation time may be adjusted by changing the program code.

In addition, the LED bar 60 has a plurality of LEDs corresponding to the units of each frequency band in a row so that each frequency band can be displayed in nanometer (nm) value of the ultraviolet rays transmitted by emitting light in the form of a bar graph. The frequency band can be visually confirmed. (S90)

In addition, the UV transmittance of the lens 300 may be directly displayed in a percentage unit that visually identifies the numerical value compared in the digital number plate 70 (S100).

More specifically, the microprocessor 50 compares and analyzes the program code stored in the memory 40 with the frequency applied from the timer 30 so that the frequency band is turned on by the LED bar 60, and the transmittance is digital. Displayed on the number plate 70, the display time of the frequency band of the LED bar 60 and the transmittance of the digital number plate 70 is maintained for about 7 to 15 seconds.

In addition, when the measurement is completed based on the program code of the memory 40, the microprocessor 50 resets all data to the initial mode.

The measurement target of the UV transmittance measuring apparatus 100 according to the present invention as described above is optionally selected from the UV protection cream, UV blocking contact lens, window, automobile glass, etc., coated with a certain thickness on the transparent glass, in addition to the lens 300. Can be measured.

In addition, the material of the case 10 formed by die casting integrally, in addition to aluminum alloy, zinc alloy may also be used.

As described above, according to the ultraviolet light transmittance measuring device according to the present invention, the appearance is integrally simple and has an LED bar, which is a display device of the existing product, and a digital display unit, and anyone can easily identify the ultraviolet light transmittance. There are features that can be.

In addition, since the volume and light weight are easy to carry, there is an effect that can measure the UV transmittance of the measurement object regardless of the location and time.

In addition, since the case is manufactured in one piece, it is possible to realize a reduction in the production cost, and therefore, there is an effect that it can contribute not only to import substitution but also to overseas export increase.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, various other modifications and variations may be made without departing from the spirit and scope of the invention. It is therefore contemplated that the appended claims will cover such modifications and variations as fall within the true scope of the invention.

Claims (3)

A main switch 12 provided at one side of the case 10 to control power supplied from the power supply terminal 11; An irradiating part 13 which is bent upward from the case 10 and integrally formed so as to irradiate ultraviolet rays to the lens 300 mounted on the upper center of the case 10, and is installed downward on the bottom surface of the irradiating part 13. UV light irradiator 13a; An operation switch 14 electrically connected to control the light emission of the UV light irradiator 13a with respect to the power output from the main switch 12; A light receiving sensor embedded in a central portion of the case 10 so as to detect an amount of ultraviolet light transmitted through the lens 300 and convert it into a micro voltage, and is located on a vertical line with the UV light irradiator 13a; A timer 30 including an A / D converter for converting the frequency into a frequency for a predetermined time in proportion to the minute voltage output from the light receiving sensor; A memory 40 electrically connected to the timer 30 and having a reference value of a predetermined program code stored therein; A microprocessor (50) for comparing and determining a reference value of the memory (40) by converting it into a numerical value; Receiving and displaying the comparison data of the microprocessor (50), LED bar (60) arranged in a line on the upper side of the case (10); And And a digital number plate (70) installed on the other side of the case (10) to receive the comparative data of the microprocessor (50) and to visually identify the microprocessor (50). The apparatus of claim 1, wherein the light receiving sensor is a photodiode (20). The apparatus for measuring ultraviolet transmittance according to claim 1, wherein the case (10) is formed integrally with the irradiation part (13) by die casting casting, and the material is aluminum alloy.