JPS6362713B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an electronic timepiece with a built-in gas sensor.

In recent years, many gases such as city gas and LP gas have entered our daily lives as energy sources. As a result of these, gas explosions and fatal accidents due to gas poisoning occur frequently. Such accidents can be prevented if gas leaks are discovered early, but the measuring instruments are generally large and inconvenient to carry. Therefore, it is almost impossible for a measuring device to be present at the site of a gas leak.

An object of the present invention is to provide an electronic timepiece with a function of measuring gas concentration in the air, which is small and can be carried at all times by incorporating a gas sensor into the electronic timepiece.

Hereinafter, the present invention will be explained in detail according to Examples. FIG. 1 is an external view of a watch according to an embodiment of the present invention. 1 is a liquid crystal display device that displays the time on the upper stage and the detected gas concentration on the lower stage. 2 is a gas sensor that detects gas concentration; 3 is a buzzer that generates a warning sound to warn when the gas concentration exceeds a preset value; and 4, 5, 6, and 7 are operating switches. 4 is a lamp switch used to illuminate the liquid crystal display device when used in a dark place. 7 is the mode switch, basic mode, time correction mode,
Cyclically select the warning gas concentration set mode. 6 is a set switch which can set the digit number selected by switch 5. The selected digit is displayed, for example, by blinking at 2 Hz.

FIG. 2 is a side view of the movement portion of the embodiment of FIG. 1. 8 is the outer case, 9 is the glass, 1
0 is a reflector, 11 is a liquid crystal display panel with a liquid crystal sealed between two pieces of glass, and a polarizing plate is attached to the outside of each glass, 12 is a gas sensor unit with a built-in semiconductor gas sensor, and 13 is a gas sensor unit. 12 electrode patterns and circuit board 16
14 is an operating button, and 15 is a spring switch terminal. When the operating button 14 is pressed, conductive rubber is electrically connected to the electrode pattern on the circuit board 16. Further, it is fixed to the circuit board 16 by soldering. 1
7 is a power supply battery, 18 is a crystal resonator unit as part of the oscillator, and this electrode terminal is connected to the circuit board 16.
is soldered to the electrode pattern. 19 is
The MOSIC chip is fixed to the circuit board 16 and electrically connected to the electrode pattern of the circuit board 16 by wire bonding. 20 is the liquid crystal panel 11
This is conductive rubber that establishes conduction between the electrodes of the circuit board 16 and the electrode pattern of the circuit board 16.

FIG. 3 is a sectional view of the gas sensor unit 12 of FIG. 21 is a metal member forming a cylindrical member; 22 is a molding material that protects the electrode portion of the semiconductor gas sensor; 23 is a semiconductor gas sensor;
4 is an insulating and heat-insulating substrate on which the semiconductor gas sensor is fixed, has an electrode pattern, and is electrically connected to the semiconductor gas sensor by bonding. Further, this substrate is fixed to a circular metal member 25. The metal member 25 is fixed to an insulating substrate 26 and has a wiring hole for electrically connecting the metal patterns of the substrates 23 and 26. Also, the metal member 25
is fixed to the metal member 21 by caulking. The substrate 26 has an electrode pattern and is electrically connected to the circuit board 16 via the conductive rubber 13 shown in FIG.

FIG. 4 shows a cross-sectional view of the semiconductor gas sensor.
An N-type silicon layer 32 is formed on a P-type silicon substrate 31, and further a p-type silicon layer 33 which becomes a resistance layer is formed. 33 is connected to electrodes 36 and 38, and heat is generated by passing a current there.
Acts as a heater. This is to increase the temperature of the gas sensor and improve the sensitivity of gas detection. Similarly, an N-type silicon layer 30 is formed, and further a P-type silicon layer 29 which becomes a resistance layer is formed. The P-type silicon layer 29 controls the impurity concentration to be low. When the impurity concentration is low, the temperature coefficient of resistance is large. Therefore, by detecting this resistance value, the temperature of the semiconductor gas sensor can be measured. A current is passed between the electrodes 36 and 39 to detect the resistance value of the P-type silicon layer 29. 28 is an insulating layer of _SiO2 . 35 on this
gas sensor is formed. This is a metal oxide, and its resistance value changes depending on the gas concentration. Using this, electrodes 36 and 3
7 and detects the resistance value of the gas sensor 35 to measure the gas concentration. 2
An insulating film 7 covers the upper surface of the semiconductor gas sensor except for the electrode that connects the gas sensor 35 to the outside.

FIG. 5 is an example of a block diagram of an electronic circuit constituting the electronic timepiece with a gas sensor according to the present invention. This circuit is centered around a microprocessor, and all system operations are controlled by microprogram instructions built into the ROM. A reference signal generated by an oscillator 50 using a crystal oscillator as a time reference source is frequency-divided by a frequency divider and input to a clock signal control circuit 49. The clock generated here is sent to the entire system and runs it. Program counter 47 is ROM
40 address is specified, and the data there is sent to instruction register 41. Next, the data sent to the instruction decoder 42 is decoded and becomes a command signal to control the system. Data pointer 43 is RAM
44 address. The RAM 44 can read or write data at a designated address. RAM has the role of temporarily storing data needed to operate the system. All data is transmitted via data bus 45 and processed by arithmetic circuitry 46.
There is an I/O port 48 as an inlet/outlet for the signals of the microprocessor described above. Next, the external devices connected to the I/O port 48 and their operations will be described. FIG. 6 is a timing chart of signals S ₁ , S ₂ , S ₃ , S ₄ , and S ₅ when detecting gas concentration. 62 within the broken line is a semiconductor gas sensor.
When a gas concentration measurement command is issued from the ROM 40, the signal _S1 becomes a logic level "high". (Hereinafter, the logic level "low" will be referred to as "high" for short. Similarly, the logic level "low" will be referred to as "low.") This causes a constant current to flow from the constant current generator 58 to the temperature detection element 60 and the gas sensor 59, which is a sensor for measuring gas concentration. is added. When the signal S ₂ becomes "high" at the same time as S ₁ , a current flows through the heater 61 by the heater control circuit 63 serving as a current supply circuit, and the temperature of the semiconductor gas sensor 62 rises. When this temperature exceeds a certain preset temperature, the voltage across the temperature detection element 60 becomes higher than the voltage of the reference power supply 57. These voltages are compared by comparator 56 and the output signal _S3 becomes "low". This signal is processed by the microprocessor section via the I/O port, causing _S2 to go "low". This cuts off the heater current. Similarly, when the temperature of the semiconductor gas sensor falls below the set temperature, S ₃ becomes "high" again, S ₂ also becomes "high", and current flows to the heater. By repeating this process, the temperature of the semiconductor gas sensor can be maintained at the set value. When S ₃ goes "low", a digital signal is sent to S ₄ .
( _S4 in FIG. 6 is "high", indicating that a digital signal is being sent.) This is converted into a voltage change signal by the D/A converter 54. This voltage changes so that it is initially high and then gradually becomes low, and is compared with the voltage across the gas sensor 59 by the comparator 55. When the voltage of the D/A converter 54 becomes lower, _S5 becomes "low". The measurement ends here, and S ₁ , S ₂ are fixed at "low". The digital signal _S4 at this time becomes the measured value.
This value is converted to a gas concentration value and is displayed on the liquid crystal display 5.
2. Further, if the value exceeds a preset value, the warning generating device 51 notifies you with a buzzer sound. This is one cycle of gas concentration measurement. In order to reduce current consumption, this measurement is not performed continuously but at regular time intervals. A switch 53 is provided for external operation.
The above gas concentration measurement data is processed within the electronic circuit enclosed by the frame in Figure 5, and all data is processed at I/O port 4.
8, and is processed by the arithmetic circuit 46 according to microprogram instructions contained in the ROM 40.

The warning function and the clock function are similarly processed by the electronic circuit 100, and the data processed by the arithmetic circuit 46 according to the microprogram instructions built in the ROM 40 is sent via the I/O port 48 to the warning generating device 51, It is displayed on the liquid crystal display device 52.

In this embodiment, a liquid crystal display device 52 is used as an optical display means, a warning device 51 is used as a warning means, and a D/A converter 54 is used as a means for measuring concentration according to the terminal voltage of a resistive element of a gas concentration sensor.
and a comparator 55, and a comparator 56 was used as means for detecting that a predetermined temperature was reached based on the terminal voltage of the temperature detection element.

As described above, according to the present invention, an air gas concentration measuring device can be worn together with a watch, so that one can always protect oneself from accidents caused by gas leaks. In addition, since it can be used as both a clock circuit and a gas concentration measuring circuit, it can be miniaturized, making it easy to create an electronic clock with a gas sensor, which has great effects in terms of safety and structure. In addition, the concentration measurement sensor, heater, and concentration detection element are all made of semiconductors.
Since it is formed in the body, it has the advantage of being able to measure high concentrations, achieving a compact gas sensor function, and being easily stored in small electronic watches.

[Brief explanation of drawings]

FIG. 1 is an example of an electronic timepiece according to the present invention, FIG. 2 is a side view of the embodiment, FIG. 3 is a sectional view of a sensor unit for measuring gas concentration in the air, and FIG. 4 is a sectional view of a semiconductor gas sensor. FIG. 5 is a block diagram of an electronic circuit constituting the electronic timepiece of the present invention, and FIG. 6 is a timing chart of signals S ₁ , S ₂ , S ₃ , S ₄ and S ₅ . 1...Liquid crystal display panel, 2...Unit for measuring gas concentration in air, 3...Warning buzzer, 4
...Lamp switch, 5...Select switch,
6...Set switch, 7...Mode switch,
8... Exterior case, 9... Glass, 10... Reflective plate, 11... Liquid crystal panel, 12... Unit for measuring gas concentration in air, 13... Conductive rubber, 14...
...Switch button, 15...Switch spring, 16
... Circuit board, 17 ... Small battery, 18 ... Crystal resonator unit, 19 ... MOSIC, 20 ... Conductive rubber, 21 ... Gas sensor unit case,
22...Molding material, 23...Semiconductor gas sensor, 24...Insulating substrate, 25...Metal substrate, 26
...Insulating substrate, 27...Insulating film, 28...P type silicon layer, 30...N type silicon layer, 31...P
type silicon substrate, 32...N type silicon layer, 33
... P-type silicon layer, 34 ... electrode, 35 ... gas sensor, 36 ... common electrode, 37 ... electrode for gas sensor, 38 ... electrode for heater, 39 ...
...Temperature detection element electrode, 40...ROM, 41...
...Instruction register, 42...Instruction decoder, 43...Data pointer, 44...RAM, 45...Data bus, 46...Arithmetic circuit, 47...Program counter, 48... ...I/O port, 49...Clock signal control circuit, 50...Oscillator, frequency divider, 51
... Alarm generating device, 52 ... Liquid crystal display device, 53
...Switch, 54...D/A converter, 55...
Comparator, 56... Comparator, 57...
Reference power supply, 58...constant current generator, 59...gas sensor, 60...temperature detection element, 61...heater, 62...semiconductor gas sensor, 63...heater control circuit, _S1 ...constant current control Signal, S ₂ ... Heater control signal, S ₃
...Temperature detection signal, _S4 ...Voltage control signal, _S5 ...Gas concentration detection signal, 100...Electronic circuit.

Claims (1)

[Claims] 1. An electronic watch equipped with an optical display means 52 and a warning generating means 51, a gas concentration measuring sensor 59 made of a resistive element, a heater 61 made of a resistive element and generating heat at a predetermined temperature near the gas concentration measuring sensor, A temperature detection element 60 which is made of a resistive element and detects the temperature around the heater, a constant current generator 58 which supplies a constant current to the gas concentration measurement sensor and the temperature detection element based on input from an external operation switch 53, and the heater. a circuit 63 for supplying current to the temperature detection element; means 56 and 57 for detecting that a predetermined temperature has been reached based on the terminal voltage of the temperature detection element; and when the detection means detects that the predetermined temperature has been reached, the gas concentration sensor means 5 for measuring the concentration according to the terminal voltage of the resistive element;
4, 55, a semiconductor resistance layer comprising an electronic circuit 100 that operates the optical display means or the warning means according to the output of the measuring means, and in which the heater and the temperature detection element are formed on the same silicon substrate 31; 29 and 33, the gas concentration measuring sensor is formed from a metal oxide 35 whose resistance value changes depending on the gas concentration formed on the semiconductor resistance layer for heater, and the heater and temperature sensor formed in one body. An electronic timepiece characterized in that a detection element and a gas concentration measuring sensor are housed in a cylindrical member 21 that guides air outside the timepiece, are integrated, and are connected to a circuit board 16.