Nuclear radiation level detector

A nuclear radiation level detector includes an ionization chamber. Within the ionization chamber are spaced electrodes. The space between the electrodes communicates with the atmosphere so as to expose the electrodes to the atmosphere. A voltage source applies a potential across the electrodes. When the atmosphere is not contaminated with nuclear radiation above a reference level, the current flow between the electrodes is nil or substantially so. In the event the atmosphere is contaminated with nuclear radiation above a reference level, a measurable current flows between the electrodes. A measurement and alarm circuit operates an alarm in response to the current flow between the electrodes of a measurable magnitude.

BACKGROUND OF THE INVENTION 
The present invention relates in general to nuclear radiation level 
detectors, and more particularly to a nuclear radiation level detector 
suitable for use in homes, schools, hospitals, offices, vehicles, and the 
like. 
Heretofore, smoke detectors have been employed to operate an alarm in the 
event smoke is detected in a home, school, hospital, hotel, or the like. 
There is a need for a low cost electronic device to detect nuclear 
radiation levels that can be mounted in a home or the like in a manner 
similar to the mounting of a smoke detector in a home or the like. 
Nuclear power plants or similar facilities have employed apparatus for 
detecting the level of nuclear radiation. However, such apparatus have 
been too expensive, complex and cumbersome for homes, hotels, hospitals, 
schools, and the like. 
In the text by Price, Nuclear Radiation Detection published by McGraw Hill 
(1958), pages 74 and 88, there is disclosed a standard air-wall ionization 
chamber connected to an electrometer for nuclear radiation detection. As 
the energy of X-photons or gamma-ray photons increase, the size of the 
standardization chamber increases. This action was obviated through the 
use of an actual wall of solid material with the same composition as air. 
An air-equivalent chamber is produced by using Bakelite, Lucite and other 
plastics for the solid material. The surface of the plastic is coated with 
a colloidal carbon to give it the conductive properties for electrodes of 
ionization chambers. 
Motorola Semiconductor Products, Inc. of Austin, Tex., has manufactured and 
sold an MC14467, an integrated circuit semiconductor device referred to as 
a low power, complementary metal-oxide semiconductor, medium scale 
integration, for use in low cost smoke detectors. The MC14467 integrated 
circuit semiconductor device, when used with an ionization chamber and 
external components, serves as a smoke detector. 
SUMMARY OF THE INVENTION 
An object of the present invention is to provide a nuclear radiation level 
detector that is suitable for use in homes, schools, hotels, hospitals, 
offices and the like. 
Another object of the present invention is to provide a nuclear radiation 
level detector that is economical to manufacture without sacrificing 
reliability. 
Another object of the present invention is to provide a portable nuclear 
radiation level detector for enabling a continuous monitoring of the 
nuclear radiation level whether at a specific location or while in 
transit. 
Briefly described, the nuclear radiation level detector of the present 
invention comprises an ionization chamber. Included in the ionization 
chamber are spaced electrodes. The space between the electrodes 
communicates with the atmosphere so as to expose the electrodes to the 
atmosphere. A voltage source applies a potential across the electrodes. 
When the atmosphere is not contaminated with nuclear radiation above a 
reference level, the current flow between the electrodes is nil or 
substantially so. In the event the atmosphere is contaminated with nuclear 
radiation above a reference level, a measurable current flows between the 
electrodes. A suitable measurement and alarm circuit responds to the 
current flow to produce an alarm. 
A feature of the present invention is that the ionization chamber is 
inexpensive to manufacture and yet is stable. 
Another feature of the present invention is that the cathode electrode of 
the ionization chamber forms an electrostatic shield for the ionization 
chamber and the anode electrode of the ionization chamber is well 
insulated to prevent current losses from within the ionization chamber and 
to prevent the entry of error currents from external sources into the 
ionization chamber. 
Another feature of the present invention is that the measurement and alarm 
circuitry is electrostatically shielded to provide accurate meter 
measurements. 
Another feature of the present invention is the employment of a voltage 
inverting circuit powered by the oscillator timer of the measurement and 
alarm circuit to increase the sensitivity of the radiation level detector 
while enabling the radiation level detector to operate from a low voltage 
battery.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
Illustrated in FIGS. 1-3 is a nuclear radiation level detector 10 embodying 
the present invention which comprises a plastic housing 15. The plastic 
housing 15 includes a hollow body 16 and a cover 17. The hollow housing 15 
is divided into an ionization chamber 20 and a measurement and alarm 
chamber 25 by a wall 26. The cover 17 is divided into a section 17a that 
covers the ionization chamber 20 and a section 17b that covers the 
measurement and alarm chamber 25. In the exemplary embodiment, the housing 
15 is an injection molded plastic housing. The cover sections 17a and 17b 
are removably secured to the hollow body 16 by suitable self-tapping 
screws. 
Disposed within the ionization chamber 20 is a pedestal insulator 31 (FIG. 
3). In the exemplary embodiment, the pedestal insulator 31 is made of 
plastic and is integrally formed by injection molded plastic during the 
forming of the hollow body 16 by injection molded plastic. The pedestal 
insulator 31 is not lined with metallic coating. In this manner, a high 
quality insulator is attained. 
Secured to the distal end of the pedestal insulator 31 is a suitable anode 
electrode 35 (FIGS. 3 and 4). In the exemplary embodiment, the anode 
electrode 35 is made of an electrically conductive metal, such as tin 
plated steel. The anode electrode 35, which serves to collect ions, could 
be made of any material with a conductive surface. 
The inside walls of the ionization chamber 20, except for the pedestal 
insulator 31, are lined with a metallic conductor 40. In the preferred 
embodiment, the inner walls of the ionization chamber 20 are lined with a 
metallic conductor 40 such as aluminum by vacuum metallization. Other 
suitable means could be employed to line the inner walls of the ionization 
chamber 20 with the metallic conductor 40, such as conductive painting, 
metallic lamination, or the like. 
The metallic conductors 40 are electrically connected to form a cathode 
electrode 45 (FIGS. 3 and 4). The conductors 40 are electrically connected 
to one another by direct contact. The conductor lining on the inner wall 
of the cover section 17a when in position is in contact with the conductor 
lining on the housing body 16 of the ionization chamber 20. By virtue of 
the plastic housing 15 and the shielded inner walls of the plastic housing 
15 through the metallic conductors 40, the anode electrode 35 is 
electrostatically shielded for accurate measurement of the nuclear 
radiation of the atmosphere. In this manner, the anode electrode 35 is 
well insulated to minimize loss of current generated from the nuclear 
radiation of the atmosphere and also to inhibit the entry of stray or 
error currents into the ionization chamber 20 from other or extraneous 
sources. 
Since the cathode electrode 45 is connected to a source of low d.c. voltage 
60 (FIGS. 2 and 4), there is a low alternating current impedance relative 
to ground potential, maintained by a capacitor 84 (FIG. 6). Thus, the 
cathode electrode 45 serves as an electrostatic shield to reduce currents 
produced by interfering electrical fields from reaching the anode 
electrode 35. Any such currents produced by these fields will be 
intercepted by the cathode electrode 45 and by-passed to ground. The 
measurement of low currents lends itself to a high impedance, low level 
measuring circuit, such as a measurement and alarm circuit 55 (FIGS. 3 and 
6). The measurement and alarm circuit 55 is secured by screws to standoffs 
on the cover section 17b. 
The anode electrode 35 and the cathode electrode 45 are separated by an air 
space (FIGS. 3 and 4). The atmosphere enters the air space between the 
anode electrode 35 and the cathode electrode 45 through suitable openings 
56 formed in the hollow body 16. Hence, the electrodes 35 and 45 are 
exposed to the atmosphere. The voltage source 60 (FIGS. 3 and 4) applies a 
potential across the electrodes 35 and 45. The measurement and alarm 
circuit 55 measures the current flow between the cathode electrode 45 and 
the anode electrode 35. When the ionizing nuclear radiation between the 
cathode electrode 45 and the anode electrode 35 is substantially nil, 
there is no current flow between the cathode electrode 45 and the anode 
electrode 35. When the ionizing alpha, beta or gamma nuclear radiation 
between the cathode electrode 45 and the anode electrode 35 is present at 
a detectable level, the air molecules between the cathode electrode 45 and 
the anode electrode 35 are ionized to produce a net electrical charge. The 
ionized air molecules are attracted to an oppositely charged electrode 
and, hence, produce a measurable current flow between the cathode 
electrode 45 and the anode electrode 35 that is measured by the 
measurement and alarm circuit 55. 
The chamber 25 for the measurement and alarm circuit 55 is 
electrostatically shielded, since the measurement and alarm circuit 55 
operates at a high impedance. In this manner, unwanted interference is 
excluded from the chamber 25 by the electrostatic shield and, hence, the 
measurement and alarm circuit 55 is shielded from outside interference. 
Toward this end, the inside walls of the chamber 25 are lined with a 
metallic conductor 61 (FIG. 3). In the preferred embodiment, the inner 
walls of the chamber 25 are lined with the metallic conductor 61, such as 
aluminum, by vacuum metallization. Other suitable means could be employed 
to line the inner walls of the chamber 25 with the metallic conductor 61, 
such as conductive painting, metallic lamination, or the like. 
The anode electrode 35 is connected to the measurement and alarm circuit 55 
over a conductor 62 (FIGS. 3, 5 and 6). The cathode electrode 45 is at a 
negative potential relative to circuit ground and is connected to an 
inverting circuit 80 (FIG. 6) of the measurement and alarm circuit 55 via 
a conductor 63 (FIGS. 2 and 6). The conductor lining 61 on the inner wall 
of the cover section 17b, when in position, contacts the conductor lining 
61 on the housing body 16 of the measurement and alarm chamber 25. A 
suitable spring 63a maintains the conductor 63 in constant engagement with 
the lining 40 of the ionization chamber 20. The measurement and alarm 
circuit 55 is mounted on the cover section 17b by suitable self-tapping 
screws. 
The current from the anode electrode 35 is applied through a current 
sensing resistor 65 (FIG. 6) to the measurement and alarm circuit 55. The 
current sensing resistor 65 is connected in series with a voltage produced 
by voltage divider 74 (FIG. 6). By adjusting the voltage resulting from 
the sensing resistor 65 and the source of voltage 60, the amount of 
current and, hence, the nuclear radiation required to trigger a detector 
circuit 66 of the measurement and alarm circuit 55 can be regulated. 
More specifically, the current flow from the anode electrode 35 produces a 
voltage across the current sensing resistor 65. The voltage across the 
current sensing resistor 65 reduces the resultant voltage between the 
input of the detector 66 (FIG. 4) and ground. The voltage divider 74 (FIG. 
6) produces a voltage in series with the current sensing resistor 65 and 
ground. The resulting voltage, when the radiation level is above a 
reference level, activates the measurement circuit 55 causing a suitable 
alarm 70 to be activated. In the preferred embodiment, the alarm 70 is a 
piezo-electric horn 71 to produce an audible sound and a light emitting 
diode 87 to produce a light. The horn 71 (FIG. 6) is of the type 
manufactured by Murata Erie of Japan as Model No. 75B-34R7-3C2. The light 
produced by the light emitting diode 87 (FIG. 6) is an interrupted light 
in a periodic on and off mode. 
The sensitivity of the radiation level detector 10 is regulated by a 
divider network 74 (FIG. 6) comprising resistor 75, variable resistor 76, 
resistor 77 and variable resistor 78. The divider network 74 serves to 
bias the current sensing resistor 65 so that the adjustment of the 
variable resistor 76 at the low resistance end reduces the bias and is 
adequate to trigger the measurement circuit 55 at the present radiation 
level of the atmosphere. Moving the variable resistor 76 to the high 
resistance end will increase the bias and will raise the voltage level 
required to trigger the measurement circuit 55. Hence, the lowest 
resistance position of the variable resistor 76 which triggers the 
measurement circuit 55 is a measurement of the radiation level at a normal 
radiation level atmosphere condition. Variable resistor 78 serves to 
calibrate the unit so that the measurement and alarm circuit 55 triggers 
at the desired radiation level with the variable resistor 76 at the low 
resistance end. A capacitor 79 serves to determine the frequency at which 
the radiation level is sensed. 
Generally, the radiation level detector 10 is mounted on the wall of a 
residence or the like with the variable resistor 76 set to the lowest 
resistance or the highest sensitivity position. While the alarm 71 is 
activated, the operator adjusts the variable resistor 76 to the lowest 
resistance, or the highest sensitivity position. The radiation level 
detector 10 is adjusted through the resistor 78 to activate the alarms at 
the desired level of radiation. 
The sensitivity of the ionization chamber 20 to the nuclear radiation level 
of the atmosphere is a function of the voltage from anode electrode 35 to 
cathode electrode 45. In the exemplary embodiment, the operating anode 
voltage is one-half the potential of the battery 60. In the exemplary 
embodiment, the battery voltage is 9 volts and the anode voltage is 4.5 
volts. Operating the anode 35 at one-half the voltage of the battery 60 
reduces the sensitivity of the radiation level detector 10 by 
approximately a factor of 10 below its maximum value. For this reason, the 
voltage inverter circuit 80 (FIG. 6) produces, in the exemplary 
embodiment, approximately -8 volts to bias the cathode electrode 45 of the 
ionization chamber 20. As a consequence thereof, the potential difference 
between the anode electrode 35 and the cathode electrode 45, in the 
exemplary embodiment, is 13 volts. The sensitivity of the radiation level 
detector 10 is thereby increased in excess of 70% of its maximum value. 
The voltage inverter circuit 80 comprises capacitor 81, rectifier 82, 
rectifier 83 and the capacitor 84. The voltage inverter circuit 80 employs 
periodic pulses emitted by an oscillator timer circuit 85 (FIG. 5) as a 
power source. The operation is similar to that commonly employed in a 
voltage doubler circuit. In the exemplary embodiment, the periodic pulses 
are applied to the voltage inverter circuit 80 every 40 seconds. A 
resistor 86 controls the frequency of the oscillator timer 85. Once every 
40 seconds a negative pulse of approximately 10 milliseconds duration is 
applied through the capacitor 81 to the diode 82, which conducts, thereby 
charging the capacitor 84 to a negative potential. When the pulse goes 
positive, the diode 82 conducts, effectively "clamping" the junction of 
the diodes 82 and 83 to approximately +0.6 volts, in preparation for the 
next negative pulse. The light emitting diode 87 in series with a resistor 
88 interconnects the source of voltage 60 with the measurement and alarm 
circuit 55. When there is no radiation, this diode flashes once every 40 
seconds. A capacitor 88' is connected in parallel with the 9 volt battery 
60 to reduce the AC impedance of the voltage source. The resistor 88 sets 
the LED current. 
Motorola Semiconductor Products Inc. of Austin, Tex., manufactures and 
sells an integrated circuit semiconductor device 90 (FIGS. 5 and 6), known 
as the MC14467. In the exemplary embodiment, the present invention employs 
the MC14467 integrated circuit semiconductor device. The MC14467 
integrated circuit semiconductor device 90 is a low power complementary 
metal-oxide semiconductor, medium scale integration. 
The integrated circuit semiconductor device 90, in the exemplary 
embodiment, includes the oscillator timer 85 which operates with a period 
of 16.7 seconds during normal operating conditions. During each 16.7 
seconds, internal power is applied to the integrated circuit semiconductor 
device 90. When power is applied to the integrated circuit semiconductor 
device 90, a test is made of the nuclear radiation level of the atmosphere 
to which the anode electrode 35 and the cathode electrode 45 are exposed. 
An oscillator capacitor 91 of a low leakage type is employed, since very 
small currents are used in the oscillator timer 85. 
When a radiation level detected by the anode electrode 35 and the cathode 
electrode 45 exceeds the reference trigger level, the sensing detector 66 
of the integrated circuit semiconductor device 90 is activated to trigger 
a latch circuit 92 of the integrated circuit semiconductor device 90. The 
triggering of the latch circuit 92 causes the oscillator timer 85 to 
generate oscillating pulses, in the exemplary embodiment, every 40 
milliseconds. 
Connected to the output of the oscillator timer 85 is the horn driver 
circuit 89 of the integrated circuit semiconductor device 90 and a light 
emitting diode driver circuit 93 of the integrated circuit semiconductor 
device 90. The horn driver circuit 89 is triggered by the oscillator timer 
85, when the nuclear radiation level detected by the anode electrode 35 
and the cathode electrode 45 exceeds the nuclear radiation reference level 
to operate the piezoelectric horn 71. In a similar manner, the light 
emitting diode driver circuit 93, in response to the operation of the 
oscillator timer 85, operates the light emitting diode 87 (FIG. 6), when 
the nuclear radiation level detected in the ionization chamber 20 by the 
anode electrode 35 and the cathode electrode 45 exceeds the reference 
level of nuclear radiation. When the nuclear radiation level in the 
ionization chamber 25 exceeds the reference level of nuclear radiation, 
the light emitting diode 87 (FIG. 6) pulses on and off, in the exemplary 
embodiment, at a rate of once per second. The piezoelectric horn 71, in 
the exemplary embodiment, modulates 200 milliseconds on and 40 
milliseconds off. 
An active guard amplifier 95 of the integrated circuit semiconductor device 
90 is connected to the sensing detector 66 and the terminals of the 
integrated circuit semiconductor device 90 adjacent the input terminal of 
the sensing detector 66. In the exemplary embodiment, the terminals of the 
integrated circuit semiconductor device 90 for the active guard operating 
amplifier 95 and the sensing detector 66 are within 100 millivolts of the 
input signal. This arrangement keeps surface leakage of currents to a 
minimum and provides a method of measuring the input voltage without 
loading the ionization chamber 20. In the preferred embodiment, the input 
terminal of the sensing detector 66 has internal diode protection against 
static damage. A resistor 94 interconnects the active guard amplifier 95 
with the source of voltage 60 to set the output current of the operating 
amplifier 95. 
The horn driver circuit 89 comprises a NAND gate 96. In series with the 
NAND gate 96 is a power amplifier 97. The output of the power amplifier 97 
is connected to one input of the horn 71. A NAND gate 98 is connected to 
the output of the NAND gate 96 and a power amplifier 99 is connected to 
the output of the NAND gate 98. The output of the power amplifier 99 is 
connected to another input of the horn 71. As shown in FIG. 6, the horn 71 
includes a feedback circuit 105, which includes a resistor 106 and a 
capacitor 107. The resistor 106 and the capacitor 107 are connected to the 
integrated circuit semiconductor device 90 for producing audible tones 
when the measurement and alarm circuit 55 is in the radiation alarm mode. 
Should the source of voltage 60 drop below a safe operating level to 
indicate a need for replacement, short audible tones are produced by the 
horn 71. Toward this end, the feedback circuit 105, which includes the 
resistor 106 and the capacitor 107, is connected to the horn terminals of 
the integrated circuit semiconductor device 90. 
Should it be desired that the operation of the horn 71 be reduced to clicks 
instead of loud audible sounds, a switch 110 is connected to the horn 
terminals of the integrated circuit semiconductor device 90 through a 
resistor 111. When the switch 110 is actuated to produce the click sound, 
the light emitting diode 72 is operable to flash at one second intervals 
when the nuclear radiation level in the ionization chamber 20 is above the 
adjusted reference level. 
A test of the operation of the horn 71 and the light emitting diode 87 is 
made through a switch 112. The switch 112 is connected to the adjustable 
element of the variable resistor 76. When the switch 112 is closed, the 
adjustable element of the variable resistor 76 is momentarily connected to 
ground to cause the operation of the horn 71 and the light emitting diode 
87. 
In the exemplary embodiment, the oscillator timer 85 of the integrated 
circuit semiconductor device 90 operates with a period of 16.7 seconds 
during normal operating conditions. During each 16.7 seconds, the internal 
power is applied to the integrated circuit semiconductor device 90. When 
power is applied to the integrated circuit semiconductor device 90, a test 
is made of the nuclear radiation level of the atmosphere to which the 
anode electrode 35 and the cathode electrode 45 are exposed. In the 
exemplary embodiment, every 24 clock cycles a check is made for low 
battery condition by comparing the voltage VDD and the voltage across a 
Zener diode 115 (FIG. 5) by means of a low battery comparator circuit 116 
of the integrated circuit semiconductor device 90. The varying and 
self-adjusting voltage across the Zener diode 115 and the voltage VDD 
oppose one another in an offset or subtracting manner. 
Should the voltage VDD fall below a reference voltage or trip point, a 
suitable detector 120 of the integrated circuit semiconductor device 90 is 
activated. The activation of the comparator detector 120 triggers a 
suitable latch circuit 125 of the integrated circuit semiconductor device 
90. The triggering of the latch circuit 125 causes the oscillator timer 85 
to generate oscillating pulses, in the exemplary embodiment, every 40 
milliseconds. The oscillating frequency of the oscillator timer 85, when 
latched by the latch circuit 125, operates the horn 71 to produce short 
audible tones and operates the light emitting diode 87 in a periodic on 
and off mode of short durations to indicate that the voltage output across 
the battery 60 is below the safe reference voltage or trip point. The low 
battery comparator information is only latched during the pulse time of 
the light emitting diode 87. When the radiation level detector 10 is 
operating in a radiation alarm mode, the low voltage comparator circuit 
116 is inhibited from operating by the output of the oscillator timer 85 
applied to the latch circuit 125. 
The alarm sensitivity threshold of the sensing detector 66 and the low 
battery threshold of the comparator within the integrated circuit 
semiconductor device 90, are set by a voltage divider network 130 of the 
integrated circuit semiconductor device 90 (FIG. 5). The voltage divider 
network 130 includes resistors 131, 132 and 133. 
In the exemplary embodiment, the following circuit elements have the 
following values: 
Battery 60: 9 volts 
Resistor 65: 2.5.times.10" ohms 
Resistor 75: 220K ohms 
Resistor 76: 2 megohms 
Resistor 77: 1 megohms 
Resistor 78: 2 megohms 
Capacitor 79: 0.1 micofarads 
Capacitor 81: 0.1 microfarads 
Capacitor 84: 0.5 microfarads 
Resistor 86: 8.2 megohms 
Resistor 88: 1K ohms 
Capacitor 88: 100 microfarads 
Resistor 94: 1 megohms 
Resistor 106: 220K ohms 
Capacitor 107: 0.001 microfarads 
Resistor 111: 1.5 megohms 
Resistor 131: 80K ohms 
Resistor 132: 1045K ohms 
Resistor 133: 1125K ohms