WO1993024180A1

WO1993024180A1 - Alarm system for solar ultraviolet causing skin diseases (assuv)

Info

Publication number: WO1993024180A1
Application number: PCT/CA1993/000078
Authority: WO
Inventors: Ru He Zhao; Wei Ge
Original assignee: Ru He Zhao; Wei Ge
Priority date: 1992-06-01
Filing date: 1993-03-01
Publication date: 1993-12-09
Also published as: CA2070165A1; AU3490293A

Abstract

Because of the holes in the Ozonosphere near polars of the earth, skin diseases such as skin cancers, caused by solar ultraviolet, are becoming big threats to human beings. The induction of skin cancers is mainly attibuted to absorption of too much ultraviolet everyday over many years. This invention is a device or an instrument (called as Sun UV Alarm, or Solar UV Alarm, MED Alarm, etc.) which calculates how much solar ultraviolet one's skin has already received when one is exposing to the sun, and gives alarm when too much solar ultraviolet in certain period has been received, the alarm limit may be a Minimal Erythema Dose (MED) in one day, or other limits.

Description

Alarm System for Solar Ultra Violet Causing Skin Diseases(ASSUV)

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to the alarm system for detecting the Solar Ultraviolet (referred to as Solar-UV hereafter) and its accumulation (namely absorbed dose by human skins) which is harmful to human skins and may cause skin diseases such as skin cancers if the absorbed dose in certain period exceeds a limit.

2. General Description

It has been proved medically that the absorption of too much solar-UV irradiation can lead to various skin diseases, especially skin cancers. The induction of these skin diseases (including skin cancers) is caused by the accumulation of daily over exposure to solar-UV irradiation over many years. When the accumulation of over exposure to solar-UV increases up to certain value, the skin diseases (including skin cancers) may take place. This invention is intended to warn the over exposure to solar-UV irradiation on the users' skins. When the users are working in the sun or/and taking the sun bath, or/and enjoying the sunshine lying on beaches, users" yards, gardens, they use this invented device (ASSUV) to test the accumulation of the solar-UV irradiation absorbed by their skins, the ASSUV will alarm the users not to be in the sun continuously any more to avoid absorbing too much solar-UV which may cause skin diseases (including skin cancers).

SUBSTITUTESHEET This invention is a creative and intensive idea which combines the receiving of the solar-UV irradiation, the calculating, and/or memorizing, and/or accumulating and/or alarming, and/or indicating of the portion of solar-UV which is harmful to human beings together. Although there are ultraviolet detectors used in the condition of high temperature ovens to detect the ultraviolet irradiation and protect the health of workers who are working in this surroundings, there is no commercial alarm system for protecting the human skins and health in the solar-UV irradiation.

The ASSUV is very easy to use. When the users are in the sun light, switch on the ASSUV, the skins of users and the ASSUV simultaneously feel the solar-UV irradiation. When the accumulation of the solar-UV increases to a value that is harmful to human skins and may cause skin diseases (including skin cancers), (for example, one Minimal Erythema Dose - MED in one day, or Permissible 8-hour Dose, etc.), the ASSUV alarms the users that over exposure to solar-UV will happen if the users go on exposing to the sun in that day.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is the block diagram of Type-1 ASSUV.

Figure 2 is the schematic circuit of Type-1 ASSUV.

Figure 3 is the block diagram of the ASSUV of Type-2, Type-3 and Type-4.

Figure 4, Figure 5 and Figure 6 are the circuit schemes of the

ASSUV of Type-2, Type-3 and Type-4 respectively.

Figure 7 shows two inventive "single supply non-inverting integration" schemes.

DESCRIPTION OF PREFERRED EMBODIMENTS

SUBSTITUTE SHEET This invention is to detect and accumulate the strength of the solar-UV irradiation, rather than other lights. The ASSUV gives alarm based on the amount of solar UV strength integration. Normally we may use an operational amplifier to construct an invert-phase integration circuit, or we may use more than one operational amplifiers to construct a non- invert-phase integration circuit. In either case, there is at least one operational amplifier which is working in an invert- phase mode. Therefore, we must use split power supply. For battery powered devices, however, it is highly desirable to use single power supply. We invented two "single supply non- inverting integration" circuits for ASSUV (Type-2, Type-3 and Type-4) .

Figure 1 shows the six stages of the ASSUV of type-1. This type of ASSUV uses normal split power supply integration technique. In the first stage, the solar-UV is being detected by a narrow band solar-UV sensor circuit with a spectral range of 200 to 400 nm. This stage transforms the solar-UV strength into a voltage signal. The second stage uses a high input impedance circuit to isolate the first stage from the other circuit, and gives a low output impedance to provide enough power to drive the following circuit. The third stage of the ASSUV of type 1 is an integration circuit which accumulates the solar-UV strength along the time. This accumulation is used as the input signal to Schmitt triggers which is the fourth stage of the ASSUV of type-1. The output signal of the trigger is amplified and used to drive an alarm and a memory which is the final stage of the ASSUV of type-1.

In Figure 2, R_! and the Zener Diode provide a stable voltage source for the solar-UV sensing and the Schmitt triggers, which is critical for the accurate sensing and triggering. The phototransistor and R₂ transform the solar-UV strength into a voltage signal. A high input impedance

SUB_STITUTESHEET isolator consisting of OP, and R₃, isolates the solar-UV sensing circuit from the other circuit and passes on the solar-UV strength signal to a phase invertor which consists of OP₂, R₄ and R₅. An inverse phase integrator consisting of OP₃, R₆ and C accumulates the solar-UV strength signal. R, passes on this integral signal to two Schmitt triggers ST, and ST₂ cascaded together. When the solar-UV strength is accumulated to a pre-set level (adjustable by adjusting R , the first trigger ST, gives a low voltage signal to the second trigger ST₂ and ST₂ outputs a high voltage signal. This high voltage signal is power amplified by 0P₄, R₁₀ and R„, and is used to drive an alarm and a memory. A power indicator consists of R₇, R₈, LED, ST₃ and ST₄. When a user turns on the ASSUV, the LED lights up indicating the beginning of the solar-UN accumulation, if the LED does not light up, it means that the batteries have no enough power to let the whole circuit work accurately, and should be replaced. The power switch is configured such that when the ASSUV is turned off, the capacitor C is discharged immediately.

The ASSUV's of Type-2, Type-3 and Type-4 have the same block diagram shown in Figure 3. As shown in Figure 3, an ASSUV comprises six parts: SOLAR UV SENSING, SINGLE SUPPLY NON-INVERTING INTEGRATION, BATTERY LEVEL SENSING, THRESHOLD SETTING, VOLTAGE COMPARISON and ALARM SYSTEM. The working processes of these types of ASSUV are described respectively as follows:

1. Type-2 : The circuit scheme is shown in Figure 4.

SOLAR SENSING is made by a photodiode D-, a resistor R, and an operational amplifier OP,. When solar light passes through an optical filter, all other lights are blocked except the UV irradiation which sheds upon the photodiode and generates photo-current. The photo-current passes through R, produces an UV strength signal voltage U_uv which is the output

SUBSTITU E SHEET of the OP,. This UV signal voltage is the input of the next stage.

SINGLE SUPPLY NON-INVERTING INTEGRATION is accomplished by the inventive circuit consists of two operational amplifiers OP₂ and OP₃, three resistors R₂, R₃ and R₄, a capacitor C, and two switches SWITCH, and SWITCH₂. One of our inventive ideas is to use 0P₂ to transfer the UV signal voltage U_uv to R₂ (assuming SWITCH₂ is turned to R₂) directly, and thus a current U_uv/R₂ flows through R₂ and C,. So the voltage across C, is

- -^/* At (1)

where U_c, represents the integral of the solar UV strength. It is a measure of how much solar UV one has received. When U_c, reaches a threshold, an alarm is given as a warning for the users. Our another inventive idea is to use OP₃ ^s a high input impedance isolator which is necessary for transferring U_cl to the next stage. In equation (1), the factor 1/C,R₂ can be changed to 1/C,R₃ or 1/C,R₄ by SWITCH₂ so as to change the alarm level. When SWITCH, is turned to "power-off", C, is also short circuit and discharged, so that the initial value of the integral is set to zero.

THRESHOLD SETTING is made by a voltage reference D₂, OP₄ and three resistors R₅, R₆ and R₇. R₅ and D₂ provide a reference voltage U_D2 which is amplified by OP₄:

where U^-^--,-, is the triggering voltage set for both solar UV integration alarm and the low battery warning.

BATTERY LEVEL SENSING is made by two resistors R₈ and R,.

VOLTAGE COMPARISON is made by OP₅ and OP₆. When the amount of solar UV integration is low and the battery is good, both

SUB_STITUTESHEET outputs of OP₅ and OP₆ are low, no alarm is given; When the amount of solar UV integration reaches the limit, that is

^•^ci ^≥ ~^Tthrββhold ( 3 ) the output of OP₅ becomes high, this high output drives the alarm system to give the alarm; When the battery is low, that is

^US ^{≤ U}thxβBhold *

the output of OP₆ becomes high, and the alarm system is activated.

ALARM SYSTEM is constructed by two transistors T, and T₂, four resistors R₁₂, R₁₃, R₁₄ and R₁₅, four capacitors C₂, C₃, C₄ and C₅, a beeper and a LED.

2. Type-3 : The circuit scheme is shown in Figure 5. Basically this type of ASSUV is the same with Type-2, only except that the input of OP₃ is the output of OP, instead of the inverting-input of OP₂.

3. Type-4 : The circuit scheme is shown in Figure 6.

This type of ASSUV uses another inventive "single supply non- inverting integration" circuit. It consists of two operational amplifiers OP₂ and OP₃, five resistors R₂, R₃, R₄, R₅ and R₆( or R₇, or R₈) and a capacitor C,. Assuming SWITCH₂ is turned to - , our inventive ideas are to use 0P₃ to feedback the integral signal U_c, to the output of UV sensing circuit, and use 0P₂ both as a circuit isolator and an amplifier. By choosing the values of R₂, R₃, R₄, R₅ and R_ή, we can get various integral output. If we choose those values such that R₂=R₃ and R₄=R₅, then we have

^σ«- 0--.=- i^ϋ-^dt (5)

Where U_c, is the integration of the solar UV strength. The

6

SUBSTITUTE SHEET other parts of this type of ASSUV are the same as those of type-2.

SUBSTITUTE SHEET

Claims

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows:

1 An alarm system (an alarm device or instrument called as Sun UV Alarm, Solar UV Alarm, MED Alarm, Sun UV Dietmate, etc.) which gives solar ultraviolet accumulation alarm, and is used for prevention of skin diseases such as skin cancers caused by absorbing too much solar ultraviolet.

2 A system configuration shown in Figure 1 and Figure 3.

3 A short band solar-UV receiving circuit consists of R,, R₂, R₃, Phototransistor, Zener Diode, Filter and OP,, as shown in Figure 2, which is specifically designed for the solar UV spectrum ranging from 200 nm to 400 nm.

4 A configuration of solar-UV accumulation circuit consists of the following parts: (1) a stable voltage supply and a power indication for the accurate sensing and triggering, consist of R,, Zener Diode, R₇, R₈, LED, ST₃ and ST₄; (2) a low output impedance solar-UV sensing, consists of R₂, R₃, Phototransistor and OP,; (3) an integrator circuit consists of a phase invertor, an inverse phase integrator and a discharge switch. In Figure 2, this circuit consists of R₄, R₅, OP,, R^ C, 0P₂ and Switch; (4) a Triggering circuit consists of R,, ST, and ST₂; (5) a power amplifier consists of OP,, R,₀ and R,,; (6) an alarm or alarm and memory, as shown in Figure 2.

5 The said circuits used for detecting and accumulating solar-UV strength, and alarm as shown in Figure 4, Figure 5 and Figure 6.

SUBSTITUTE SHEET 6 Two "Single Supply Non-Inverting Integration" circuits as shown in Figure 7.

7 The alarm system in claim 1, claim 2 which accumulates solar UV for 0 to 5 hours in day sun light, and the alarm limit is set to one MED in one day or Permissible 8-hour Dose, or Permissible yearly Dose, etc.

SUBSTITUTE SHEET