CA1046654A - Combustion detection device - Google Patents
Combustion detection deviceInfo
- Publication number
- CA1046654A CA1046654A CA241,492A CA241492A CA1046654A CA 1046654 A CA1046654 A CA 1046654A CA 241492 A CA241492 A CA 241492A CA 1046654 A CA1046654 A CA 1046654A
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- Prior art keywords
- output
- reference voltage
- combustion
- input
- leads
- Prior art date
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Abstract
Abstract of the Disclosure A combustion detection device is disclosed that senses the presence of a fire and provides an alarm indication of the same by essentially shorting the input leads from a power supply. An ionization detector is utilized to sense the products of combustion and provide an output indicative thereof, which output is coupled through a field effect transistor to an operational amplifier where the output is compared with a reference voltage that can be varied as desired. When an output from the ionization detector supplied through the field effect transistor exceeds the reference voltage, an output is provided from the operational amplifier to a triggering circuit connected between the power supply leads to essentially short the leads as an alarm indication of a sensed fire condition.
A light-emitting diode is connected to the triggering circuit to give a visual alarm indication, and calibration leads are also pro-vided to facilitate calibration of the apparatus. The triggering circuit, in one disclosed embodiment, includes a pair of transistors connected to the drive and sink outputs of the operational amplifier, while in a second disclosed embodiment, the triggering circuit in-cludes a silicon controlled rectifier.
A light-emitting diode is connected to the triggering circuit to give a visual alarm indication, and calibration leads are also pro-vided to facilitate calibration of the apparatus. The triggering circuit, in one disclosed embodiment, includes a pair of transistors connected to the drive and sink outputs of the operational amplifier, while in a second disclosed embodiment, the triggering circuit in-cludes a silicon controlled rectifier.
Description
~O~S654 '.
:. .
~ Field of the Invention ~ This invention relates to a combustion detection device, and more particularly relates to an apparatus for detecting the presence of fire and providing an al,arm,,indicative thereof.
,. . , . ~ : :
Back~round of the Invention Various types of sensing devices have been developed for monitoring a variety of conditions. One of the more important conditions often monitored is that of combustion in an effort to discover and thus minimize loss due to fire, particularly in buildings or other structures where the presence of a fire could go unnoticed until far too late to minimize loss to any appreciable extent.
Combustion detection devices have heretofore been suggested and/or utilized, but such devices have not proved to be completely satisfactory for all situations due to such diverse factors as being subject to mechanical and/or electrical component failure, vacuum leakage and aging where vacuum tube structures are utilized, and/or being relatively complex and/
or of expensive construction so as to be impractical for at least some uses.
A combustion detection device providing pulsed ~ensing utilizing an ionization detector is shown, for example, in U. S. Letters Patent Number 3,842,~09, entitled, "Ionization Detector Apparatus", issued October lS, 1974 to Ronn H.
Mayer and assigned to the assignee of the present invention.
The detector of this invention constitutes an alternative to the structure shown and claimed in U. 5. Patent Number 3,842,409.
Summary of the Invention It is an object of this invention to provide an im-proved combustion detection apparatus.
It is another object of this invention to provide an improved combustion detection apparatus suitable for-auto-matically monitoring a location to sense fire conditions.
One aspect of the present invention is defined as acombustion detection apparatus, comprising: ionization kh ~
detection means providing an output indicative of products of combustion sensed by the detection means; a pair of input leads adapted to be connected to a power supply; a reference voltage source providing a reference voltage output; com-parator means for receiving the output from the ionization `~
detection means and the reference voltage output, the comparator means having an inhibit input and drive and sink outputs with the comparator means providing an output if the output from the ionization detection means exceeds the reference voltage received from the reference voltage source;trigger means including first and second normally non-conductive semi-conductor means one of which is connected with the com-parator means to receive the drive output therefrom and the other of which is connected with the inhibit input of the comparator means whereby the semi-conductor means are caused to become conductive upon receiving an output from the com-parator means; and connecting means for connecting the semi-,..................................................................... .
conductor means between the two input leads to essentiallyshort the same upon receipt of a signal from the comparator means to thereby achieve sensing of a fire by the apparatus whereby the sensed fire can be indicated by an alarm indicating device when so connected with the two input leads.
Another aspect of the present invention is defined as a combustion detection apparatus, comprising: ioni~ation detection means including first and second americium 241 chambers, one of which is open to the atmosphere and the other of which is substantially closed, the chambers being connected so that the ionization detection means provides an output voltage that varies depending upon sensed products ; 30 of combustion in the atmosphere surrounding the open chamber;
a reference voltage source providiny a reference voltage output; comparator means for receiving the ouput from the kh/~,~
.. . . . . . .
104665~, :
ionization detection means and the reference voltage output, the comparator means having an inhibit input, a drive output and a sink output and providing an output if the output from -the ionization detection means exceeds the reference voltage output from the reference voltage source; trigger means in-cluding first and second interconnected normally nonconductive transistors one of which is connected with the comparator means to receive the drive output therefrom and the other of ,, which is connected with the inhibit input of the comparator means whereby the transistors are caused to become conductive upon receiving an output from the comparator means; alarm indicating means connected with the trigger means and, re-sponsive to the transistors becoming conductive, causing and maintaining an alarm condition; and means for receiving the alarm indication from the alarm indicating means and indicating an alarm condition.
. With these and other objects in view, which will become apparent to one skilled in the art as the description proceeds, this invention resides in the novel construction, combination, and arrangement of parts substantial ~ as hereinafter des-cribed and more particularly defined by the appended claims, it being understood that such changes in the precise embodiment of the hereindisclosed invention are meant to be included as ~, come within the scope of the claims.
Brief Description of the Drawin~
The accompanying drawings illustrate two complete embodiments of the invention according to the best mode so far devised for the practica~ application of the principles thereof and in which:
FIGURE 1 is an electrical schematic diagram of the combustion detection apparatus of this invention with the ; trigg~ring circuit shown to include a silicon controlled _ 4 ~
', .
rectifier; and FIGURE 2 is an electrical schematic diagram of the prererred embodiment of the combustion detection apparatus of this invention with the triggering circuit shown to in-clude a pair of transistors.
Detailed Description of the Invention Referring now to the drawin~s, the numeral 5 indicates the combustion detection apparatus for the embodiment illus-trated in FIGURE 1. A pair of leads 7 and 8 are provided, which leads are adapted to be connected with a conventional power supply (not shown) with lead 7 providing +24 volts and lead 3 being a return lead. A diode 10 is connected between the +24-volt power supply (not shown) and lead 7, with lead 7 also being connected with lead 8 through series connected resistors 11 and 12 and capacitor 14.
Ionization detector 16 is connected between leads 7 and 8,and, as indicated in FIGURE 1, includes a pair of americium 241 chambers 18 and 19 (radium 226 could be utilized, if desired). Ionization detector 16 senses the products of combustion present in the atmosphere surrounding the detector and provides an output voltage indicative thereof. Americium 241 chamber 18 is preferably substantially closed and, thus, serves as a reference detector while americium 241 chamber 19 is preferably open to sample or monitor the atmosphere surrounding the detector. The output from the detector is taken from the junction 21 between the chambers with the output coupled to the input of field effect transistor (FET) 23. In the absence of a sensed fire condition, i.e., under normal operating conditions, the voltage at junction 21 is about 6 volts.
Field effect transistor 23, which preferably is a ~FET
type, serves as an amplifier and has the drain electrode kh/~
.: . . . . . : . :
~ 0466S4 connected with lead 7 and the sou~ce electrode connected with lead 8 throu~h resistor 25. The output of the field effect transistor 23 is coupled from the source electrode to the positive input of operational amplifier, or com-parator 27, which operational amplifier receives a reference volta~e supply 2~. Reference voltage supply 29 includes resistor 31, potentiometer 32 and resistor 33 connected in . series between leads 7 and 8, with the center tap 35 of the potentiometer being connected to the negative input of :~
operational amplifier 27.
Pins 7 and 8 of operational amplifier 27 are directly connected to leads 7, while pin 5 is connected thereto through resistor 36. In addition, pin 4 of operational amplifier 27 i8 directly connected to lead 8 while pin 1 is connected to lead 8 through capacitor 38, and pin 8 is connected to lead 8 through capacitor 40.
j The output from operational amplifier 27 is coupled from pin 6 to the gate electrode of si.licon controlled rectifier 43, with pin 6 also being.connected to lead 8 through resistor 44. Silicon controlled rectifier 43 has its cathode connected to lead 8 while the anode is connected through resistor 46 (a 10 ohm resistor) and light-emitting , diode (LED) 47 to lead 7. In addition, a bypass capacitor '~ 49 i8 connected between the anode of silicon controlled rec-tifier 43 and lead 8, and a lead to an external indïcator (not shown) is cannected to the junction of resistor 46 and LE~ 47 through diode 50.
Callbration leads 52 and 53 are also p~ovided to , facilitate calibration of the apparatus~ Lead 52 is connected to lead 7 and to lead 8 through parallel connected capacitor 55 and zener diode 56, while the lead 53 is dir-ectly connected to americium 241 chamber 18 of ionization ~ - 6 - ~-', :., , kh/;,.,~
detector 16.
The following is a listing of components that have been utilized in a working embodiment of the invention as shown in FIGURE 1, it being understood that such listing is for illustrative purposes only and the in~ention is not meant to be limited thereto:
Diodes 10 and 50 - lN4004 Zener Diode 56 - 2N759B (12v) LED 47 - Red Lite 4 Comparator 27 - CA 3094 Resistors ~ohms) 11, 12 and 25, - 47K
36 - lM
31 - 2.2M
33 - 2.7M
Potentiometer 32 - 0-lM ohms Capacitors (~ Fd) 14, 38, 49 and 55 - 0.1 In operation, the apparatus is preferably initially calibrated by connection of leads 52 and 53 to an external calibration means and then setting potentiometer 32 to the particular threshold desired, normally about 7.2 volts, for example. The apparatus is theo placed ,"
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in any convenient position where continuous monitoring is desired for products of combustion, i.e., to sense the presence of a ~ire.
When no fire is sensed, the output from the ionization detector will be such that the field effect transistor is maintained in a conductive state, but the outp~ voltage is maintained below the setting of the reference voltage supplied to the negative input to the comparator (operational amplifier 27) so that the comaprator will therefore provide no output to the silicon controlled rectifier and, hence, no alarm will be energized.
When a fire is sensed by the apparatus, however, the output from the ionization detector will increase to the extent that the field effect transistor supplies a sufficient voltage so that an output will be coupled from comparator 27, such a voltage, of course, exceeds the reference voltage supplied from potentiometer 32 to the comparator negative input. When the output thus e~ceeds the refer-ence voltage supplied to the comparator, comparator 27 will then provide an output to silicon controlled rectifier 43 to trigger the rectifier. When the SCR 43 fires, a short will be essentially developed across the power supply leads 7 and 8 through resistor 46 and LED 47 to indicate an alarm condition, and the light-emitting Z diode 47 will be energized. Silicon controlled rectifler 43 will remain eneryized to thus continuously indicate an alarm condition until the power is removed and later reapplied after ionization detector 16 no longer senses a product of combustion indicative of a fire. A virtual short across the power supply leads 7 and 8 can be reflected in remote equipment, for example, or at a control point, to give an alarm condition in conventional ~ashion to an operator.
-7~
104~;65~
FIGURE 2 shows the preferred embodiment 105 o~ the invention. The two disclosed embodiments utilize similar components, and where utilized, have been identified by the same reference numerals. For example, leads 7 and 8 have ionization detector 16 connected therebetween with the junction 21 between americium chambers 18 and 19 being connected to the input of field effect transistor 23. In like manner, the output of the field effect transistor 23 is coupled from the source electrode to the positive input of operational amplifier 27, which amplifier receives a negative input from a reference voltage supply (identified as 129).
The values of resistors 112 (connected with line 7), resistor 125 (connected to the source electrode of FET 23), and resistors 131 and 133 (in the reference voltage supply) are, however, unlike the values of resistors 12, 25, 31 and 33, and accordingly, have been given new numerals as shown in , .
FIGURE 2.
As also shown in FIGURE 2, operational amplifier 27 is connected to a triggering circuit which includes a pair of transistors 160 and 161 with transistor 160 having its base connected to the drive output (pin 6) and its collector con-nected to the sink output (pin 8) of operational amplifier 27.
As also shown in FIGURE 2, the base of transistor 161 is con-nected to the sink output tpin 8) of operational amplifier 27 through resistor 163 and the collector of transistor 161 is connected to the inhibit input (pin 1) of operational amplifier 27 through resistor 164. The emitter of transistor 160 is directly connected to return lead 8, while the base of trans-istor 160 is connected with power supply lead 7 throughresistor 165. In addition, pin 1 o~ operational amplifier 27 is connected with return lead 8 through capacitor 138 and pin 5 .' kh/~.
.
104~6S4 of operatlonal amplifier 27 is connected with power supply lead 7 through resistor 136.
The following is a listing of components (in addition ~ -to like identified components in FIGURE 1 as identified hereinabove) that have been utilized in a working embodiment of the preferred form of this invention, it being understood that such listing is for illustrative purposes only and the invention is not meant to be limited thereto:
Resistors (ohms) 112, 144 and 165, - 10 10125 and 133, - 1.2M
136 - lOM
164 - lM
Capacitor (~ Fd) 138 - 1 Transistors 160 - 2N2222 The operation of the invention as shown in FIGURE 2 is similar to that of FIGURE 1 except that the triggering circuit includes transistors 160 and 161 connected to the ; outputs of operational amplifi~r 27 with the collector of transistor 161 being coupled to pin 1 (of the operational amplifier) through a Darlington output (that includes pins 1, 6 and 8).
With no fire sensed, the output from the ionization detector will be such as to maintain the field effect trans-istor in a conductive state while providing an output voltage to operational amplifier 27 less than that of the reference voltage output so that transistor 160 is maintained in a non-conductive state which results in a no alarm condition.
When a fire is sensed, however, the output from the ionization detector increases as does the output from the field effect transistor. When the output from the field effect transistor exceeds the reference voltage at the operation~l amplifier, an output is providad by the _ g _ , kh ~
~, . - . .
., ,, :
operational amplifier to cause transistor 160 to conduct and this essentially shorts the leads 7 and 8 through LED
47 and transistor 160 connected in series across leads 7 and 8. When transistor 160 conducts, transistor 161 starts to conduct and transistor 161 is connected to operational amplifier 27 so that transistors 160 and 161 will remain eonduetive until power to the apparatus is diseontinued. After the eondition eausing the alarm has been eorreeted, the apparatus will produee no output when power is reapplied until a eondition again exists causing an output to be produeed by the operational amplifier.
In view of the foregoing, it is to be realized that the combustion detector apparatus of this invention provides an improved device that is particularly well suited for con-tinuous monitoring to sense products of combustion indica-tive of the presenee of a fire.
kh/~
:. .
~ Field of the Invention ~ This invention relates to a combustion detection device, and more particularly relates to an apparatus for detecting the presence of fire and providing an al,arm,,indicative thereof.
,. . , . ~ : :
Back~round of the Invention Various types of sensing devices have been developed for monitoring a variety of conditions. One of the more important conditions often monitored is that of combustion in an effort to discover and thus minimize loss due to fire, particularly in buildings or other structures where the presence of a fire could go unnoticed until far too late to minimize loss to any appreciable extent.
Combustion detection devices have heretofore been suggested and/or utilized, but such devices have not proved to be completely satisfactory for all situations due to such diverse factors as being subject to mechanical and/or electrical component failure, vacuum leakage and aging where vacuum tube structures are utilized, and/or being relatively complex and/
or of expensive construction so as to be impractical for at least some uses.
A combustion detection device providing pulsed ~ensing utilizing an ionization detector is shown, for example, in U. S. Letters Patent Number 3,842,~09, entitled, "Ionization Detector Apparatus", issued October lS, 1974 to Ronn H.
Mayer and assigned to the assignee of the present invention.
The detector of this invention constitutes an alternative to the structure shown and claimed in U. 5. Patent Number 3,842,409.
Summary of the Invention It is an object of this invention to provide an im-proved combustion detection apparatus.
It is another object of this invention to provide an improved combustion detection apparatus suitable for-auto-matically monitoring a location to sense fire conditions.
One aspect of the present invention is defined as acombustion detection apparatus, comprising: ionization kh ~
detection means providing an output indicative of products of combustion sensed by the detection means; a pair of input leads adapted to be connected to a power supply; a reference voltage source providing a reference voltage output; com-parator means for receiving the output from the ionization `~
detection means and the reference voltage output, the comparator means having an inhibit input and drive and sink outputs with the comparator means providing an output if the output from the ionization detection means exceeds the reference voltage received from the reference voltage source;trigger means including first and second normally non-conductive semi-conductor means one of which is connected with the com-parator means to receive the drive output therefrom and the other of which is connected with the inhibit input of the comparator means whereby the semi-conductor means are caused to become conductive upon receiving an output from the com-parator means; and connecting means for connecting the semi-,..................................................................... .
conductor means between the two input leads to essentiallyshort the same upon receipt of a signal from the comparator means to thereby achieve sensing of a fire by the apparatus whereby the sensed fire can be indicated by an alarm indicating device when so connected with the two input leads.
Another aspect of the present invention is defined as a combustion detection apparatus, comprising: ioni~ation detection means including first and second americium 241 chambers, one of which is open to the atmosphere and the other of which is substantially closed, the chambers being connected so that the ionization detection means provides an output voltage that varies depending upon sensed products ; 30 of combustion in the atmosphere surrounding the open chamber;
a reference voltage source providiny a reference voltage output; comparator means for receiving the ouput from the kh/~,~
.. . . . . . .
104665~, :
ionization detection means and the reference voltage output, the comparator means having an inhibit input, a drive output and a sink output and providing an output if the output from -the ionization detection means exceeds the reference voltage output from the reference voltage source; trigger means in-cluding first and second interconnected normally nonconductive transistors one of which is connected with the comparator means to receive the drive output therefrom and the other of ,, which is connected with the inhibit input of the comparator means whereby the transistors are caused to become conductive upon receiving an output from the comparator means; alarm indicating means connected with the trigger means and, re-sponsive to the transistors becoming conductive, causing and maintaining an alarm condition; and means for receiving the alarm indication from the alarm indicating means and indicating an alarm condition.
. With these and other objects in view, which will become apparent to one skilled in the art as the description proceeds, this invention resides in the novel construction, combination, and arrangement of parts substantial ~ as hereinafter des-cribed and more particularly defined by the appended claims, it being understood that such changes in the precise embodiment of the hereindisclosed invention are meant to be included as ~, come within the scope of the claims.
Brief Description of the Drawin~
The accompanying drawings illustrate two complete embodiments of the invention according to the best mode so far devised for the practica~ application of the principles thereof and in which:
FIGURE 1 is an electrical schematic diagram of the combustion detection apparatus of this invention with the ; trigg~ring circuit shown to include a silicon controlled _ 4 ~
', .
rectifier; and FIGURE 2 is an electrical schematic diagram of the prererred embodiment of the combustion detection apparatus of this invention with the triggering circuit shown to in-clude a pair of transistors.
Detailed Description of the Invention Referring now to the drawin~s, the numeral 5 indicates the combustion detection apparatus for the embodiment illus-trated in FIGURE 1. A pair of leads 7 and 8 are provided, which leads are adapted to be connected with a conventional power supply (not shown) with lead 7 providing +24 volts and lead 3 being a return lead. A diode 10 is connected between the +24-volt power supply (not shown) and lead 7, with lead 7 also being connected with lead 8 through series connected resistors 11 and 12 and capacitor 14.
Ionization detector 16 is connected between leads 7 and 8,and, as indicated in FIGURE 1, includes a pair of americium 241 chambers 18 and 19 (radium 226 could be utilized, if desired). Ionization detector 16 senses the products of combustion present in the atmosphere surrounding the detector and provides an output voltage indicative thereof. Americium 241 chamber 18 is preferably substantially closed and, thus, serves as a reference detector while americium 241 chamber 19 is preferably open to sample or monitor the atmosphere surrounding the detector. The output from the detector is taken from the junction 21 between the chambers with the output coupled to the input of field effect transistor (FET) 23. In the absence of a sensed fire condition, i.e., under normal operating conditions, the voltage at junction 21 is about 6 volts.
Field effect transistor 23, which preferably is a ~FET
type, serves as an amplifier and has the drain electrode kh/~
.: . . . . . : . :
~ 0466S4 connected with lead 7 and the sou~ce electrode connected with lead 8 throu~h resistor 25. The output of the field effect transistor 23 is coupled from the source electrode to the positive input of operational amplifier, or com-parator 27, which operational amplifier receives a reference volta~e supply 2~. Reference voltage supply 29 includes resistor 31, potentiometer 32 and resistor 33 connected in . series between leads 7 and 8, with the center tap 35 of the potentiometer being connected to the negative input of :~
operational amplifier 27.
Pins 7 and 8 of operational amplifier 27 are directly connected to leads 7, while pin 5 is connected thereto through resistor 36. In addition, pin 4 of operational amplifier 27 i8 directly connected to lead 8 while pin 1 is connected to lead 8 through capacitor 38, and pin 8 is connected to lead 8 through capacitor 40.
j The output from operational amplifier 27 is coupled from pin 6 to the gate electrode of si.licon controlled rectifier 43, with pin 6 also being.connected to lead 8 through resistor 44. Silicon controlled rectifier 43 has its cathode connected to lead 8 while the anode is connected through resistor 46 (a 10 ohm resistor) and light-emitting , diode (LED) 47 to lead 7. In addition, a bypass capacitor '~ 49 i8 connected between the anode of silicon controlled rec-tifier 43 and lead 8, and a lead to an external indïcator (not shown) is cannected to the junction of resistor 46 and LE~ 47 through diode 50.
Callbration leads 52 and 53 are also p~ovided to , facilitate calibration of the apparatus~ Lead 52 is connected to lead 7 and to lead 8 through parallel connected capacitor 55 and zener diode 56, while the lead 53 is dir-ectly connected to americium 241 chamber 18 of ionization ~ - 6 - ~-', :., , kh/;,.,~
detector 16.
The following is a listing of components that have been utilized in a working embodiment of the invention as shown in FIGURE 1, it being understood that such listing is for illustrative purposes only and the in~ention is not meant to be limited thereto:
Diodes 10 and 50 - lN4004 Zener Diode 56 - 2N759B (12v) LED 47 - Red Lite 4 Comparator 27 - CA 3094 Resistors ~ohms) 11, 12 and 25, - 47K
36 - lM
31 - 2.2M
33 - 2.7M
Potentiometer 32 - 0-lM ohms Capacitors (~ Fd) 14, 38, 49 and 55 - 0.1 In operation, the apparatus is preferably initially calibrated by connection of leads 52 and 53 to an external calibration means and then setting potentiometer 32 to the particular threshold desired, normally about 7.2 volts, for example. The apparatus is theo placed ,"
' ~
-.
- 6a -.
~ B kh/~ --... .
in any convenient position where continuous monitoring is desired for products of combustion, i.e., to sense the presence of a ~ire.
When no fire is sensed, the output from the ionization detector will be such that the field effect transistor is maintained in a conductive state, but the outp~ voltage is maintained below the setting of the reference voltage supplied to the negative input to the comparator (operational amplifier 27) so that the comaprator will therefore provide no output to the silicon controlled rectifier and, hence, no alarm will be energized.
When a fire is sensed by the apparatus, however, the output from the ionization detector will increase to the extent that the field effect transistor supplies a sufficient voltage so that an output will be coupled from comparator 27, such a voltage, of course, exceeds the reference voltage supplied from potentiometer 32 to the comparator negative input. When the output thus e~ceeds the refer-ence voltage supplied to the comparator, comparator 27 will then provide an output to silicon controlled rectifier 43 to trigger the rectifier. When the SCR 43 fires, a short will be essentially developed across the power supply leads 7 and 8 through resistor 46 and LED 47 to indicate an alarm condition, and the light-emitting Z diode 47 will be energized. Silicon controlled rectifler 43 will remain eneryized to thus continuously indicate an alarm condition until the power is removed and later reapplied after ionization detector 16 no longer senses a product of combustion indicative of a fire. A virtual short across the power supply leads 7 and 8 can be reflected in remote equipment, for example, or at a control point, to give an alarm condition in conventional ~ashion to an operator.
-7~
104~;65~
FIGURE 2 shows the preferred embodiment 105 o~ the invention. The two disclosed embodiments utilize similar components, and where utilized, have been identified by the same reference numerals. For example, leads 7 and 8 have ionization detector 16 connected therebetween with the junction 21 between americium chambers 18 and 19 being connected to the input of field effect transistor 23. In like manner, the output of the field effect transistor 23 is coupled from the source electrode to the positive input of operational amplifier 27, which amplifier receives a negative input from a reference voltage supply (identified as 129).
The values of resistors 112 (connected with line 7), resistor 125 (connected to the source electrode of FET 23), and resistors 131 and 133 (in the reference voltage supply) are, however, unlike the values of resistors 12, 25, 31 and 33, and accordingly, have been given new numerals as shown in , .
FIGURE 2.
As also shown in FIGURE 2, operational amplifier 27 is connected to a triggering circuit which includes a pair of transistors 160 and 161 with transistor 160 having its base connected to the drive output (pin 6) and its collector con-nected to the sink output (pin 8) of operational amplifier 27.
As also shown in FIGURE 2, the base of transistor 161 is con-nected to the sink output tpin 8) of operational amplifier 27 through resistor 163 and the collector of transistor 161 is connected to the inhibit input (pin 1) of operational amplifier 27 through resistor 164. The emitter of transistor 160 is directly connected to return lead 8, while the base of trans-istor 160 is connected with power supply lead 7 throughresistor 165. In addition, pin 1 o~ operational amplifier 27 is connected with return lead 8 through capacitor 138 and pin 5 .' kh/~.
.
104~6S4 of operatlonal amplifier 27 is connected with power supply lead 7 through resistor 136.
The following is a listing of components (in addition ~ -to like identified components in FIGURE 1 as identified hereinabove) that have been utilized in a working embodiment of the preferred form of this invention, it being understood that such listing is for illustrative purposes only and the invention is not meant to be limited thereto:
Resistors (ohms) 112, 144 and 165, - 10 10125 and 133, - 1.2M
136 - lOM
164 - lM
Capacitor (~ Fd) 138 - 1 Transistors 160 - 2N2222 The operation of the invention as shown in FIGURE 2 is similar to that of FIGURE 1 except that the triggering circuit includes transistors 160 and 161 connected to the ; outputs of operational amplifi~r 27 with the collector of transistor 161 being coupled to pin 1 (of the operational amplifier) through a Darlington output (that includes pins 1, 6 and 8).
With no fire sensed, the output from the ionization detector will be such as to maintain the field effect trans-istor in a conductive state while providing an output voltage to operational amplifier 27 less than that of the reference voltage output so that transistor 160 is maintained in a non-conductive state which results in a no alarm condition.
When a fire is sensed, however, the output from the ionization detector increases as does the output from the field effect transistor. When the output from the field effect transistor exceeds the reference voltage at the operation~l amplifier, an output is providad by the _ g _ , kh ~
~, . - . .
., ,, :
operational amplifier to cause transistor 160 to conduct and this essentially shorts the leads 7 and 8 through LED
47 and transistor 160 connected in series across leads 7 and 8. When transistor 160 conducts, transistor 161 starts to conduct and transistor 161 is connected to operational amplifier 27 so that transistors 160 and 161 will remain eonduetive until power to the apparatus is diseontinued. After the eondition eausing the alarm has been eorreeted, the apparatus will produee no output when power is reapplied until a eondition again exists causing an output to be produeed by the operational amplifier.
In view of the foregoing, it is to be realized that the combustion detector apparatus of this invention provides an improved device that is particularly well suited for con-tinuous monitoring to sense products of combustion indica-tive of the presenee of a fire.
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Claims (6)
1. A combustion detection apparatus, comprising:
ionization detection means providing an output indica-tive of products of combustion sensed by said detection means;
a pair of input leads adapted to be connected to a power supply;
a reference voltage source providing a reference vol-tage output;
comparator means for receiving said output from said ionization detection means and said reference voltage out-put, said comparator means having an inhibit input and drive and sink outputs with said comparator means providing an output if the output from said ionization detection means exceeds said reference voltage received from said reference voltage source;
trigger means including first and second normally non-conductive semi-conductor means one of which is connected with said comparator means to receive said drive output therefrom and the other of which is connected with said inhibit input of said comparator means whereby said semi-conductor means are caused to become conductive upon re-ceiving an output from said comparator means; and connecting means for connecting said semi-conductor means between said two input leads to essentially short the same upon receipt of a signal from said comparator means to thereby achieve sensing of a fire by said apparatus whereby said sensed fire can be indicated by an alarm indicating device when so connected with said two input leads.
ionization detection means providing an output indica-tive of products of combustion sensed by said detection means;
a pair of input leads adapted to be connected to a power supply;
a reference voltage source providing a reference vol-tage output;
comparator means for receiving said output from said ionization detection means and said reference voltage out-put, said comparator means having an inhibit input and drive and sink outputs with said comparator means providing an output if the output from said ionization detection means exceeds said reference voltage received from said reference voltage source;
trigger means including first and second normally non-conductive semi-conductor means one of which is connected with said comparator means to receive said drive output therefrom and the other of which is connected with said inhibit input of said comparator means whereby said semi-conductor means are caused to become conductive upon re-ceiving an output from said comparator means; and connecting means for connecting said semi-conductor means between said two input leads to essentially short the same upon receipt of a signal from said comparator means to thereby achieve sensing of a fire by said apparatus whereby said sensed fire can be indicated by an alarm indicating device when so connected with said two input leads.
2. The combustion detection apparatus of Claim 1 wherein said semi-conductor means has a light-emitting diode in series therewith between said leads of said power supply.
3. The combustion detection apparatus of either of Claims 1 or 2 wherein said apparatus also includes calibra-tion enabling means connected with said ionization detection means whereby calibration of said apparatus by external calibration means is facilitated.
4. The combustion detection apparatus of either of Claims 1 or 2 wherein said ionization detector includes a pair of americium 241 chambers connected to said power supply leads.
5. A combustion detection apparatus comprising:
a pair of input leads adapted to be connected to a power supply;
an ionization detector providing an output indicative of products of combustion sensed by said ionization detector;
a field effect transistor connected to said ionization detector to receive the output therefrom;
a reference voltage supply means connected between said input leads;
an operational amplifier having amplifier bias, dif-ferential voltage, and inhibit inputs and drive and sink outputs, said output from said field effect transistor being coupled to said amplifier bias input and said reference voltage being coupled to said differential voltage input, said operational amplifier producing an output if said input from said field effect transistor exceeds that of said reference voltage;
a light-emitting diode; and a pair of normally nonconductive transistors one of which is connected in series with said light-emitting diode between said input leads and to the outputs of said opera-tional amplifier, and the other of which transistors is connected to said sink output and said inhibit input of said operational amplifier whereby said transistors are caused to become conductive upon receiving an output from said opera-tional amplifier indicative of products of combustion sensed by said ionization detector to essentially short said input leads to thus indicate and maintain said indication of a fire sensed by said ionization detector.
a pair of input leads adapted to be connected to a power supply;
an ionization detector providing an output indicative of products of combustion sensed by said ionization detector;
a field effect transistor connected to said ionization detector to receive the output therefrom;
a reference voltage supply means connected between said input leads;
an operational amplifier having amplifier bias, dif-ferential voltage, and inhibit inputs and drive and sink outputs, said output from said field effect transistor being coupled to said amplifier bias input and said reference voltage being coupled to said differential voltage input, said operational amplifier producing an output if said input from said field effect transistor exceeds that of said reference voltage;
a light-emitting diode; and a pair of normally nonconductive transistors one of which is connected in series with said light-emitting diode between said input leads and to the outputs of said opera-tional amplifier, and the other of which transistors is connected to said sink output and said inhibit input of said operational amplifier whereby said transistors are caused to become conductive upon receiving an output from said opera-tional amplifier indicative of products of combustion sensed by said ionization detector to essentially short said input leads to thus indicate and maintain said indication of a fire sensed by said ionization detector.
6. A combustion detection apparatus, comprising:
ionization detection means including first and second americium 241 chambers, one of which is open to the atmos-phere and the other of which is substantially closed, said chambers being connected so that said ionization detection means provides an output voltage that varies depending upon sensed products of combustion in the atmosphere surrounding said open chamber;
a reference voltage source providing a reference vol-tage output;
comparator means for receiving said output from said ionization detection means and said reference voltage out-put, said comparator means having an inhibit input, a drive output and a sink output and providing an output if the output from said ionization detection means exceeds said reference voltage output from said reference voltage source;
trigger means including first and second interconnected normally nonconductive transistors one of which is connected with said comparator means to receive said drive output therefrom and the other of which is connected with said inhibit input of said comparator means whereby said trans-istors are caused to become conductive upon receiving an output from said comparator means;
alarm indicating means connected with said trigger means and, responsive to said transistors becoming con-ductive, causing and maintaining an alarm condition; and means for receiving said alarm indication from said alarm indicating means and indicating an alarm condition.
ionization detection means including first and second americium 241 chambers, one of which is open to the atmos-phere and the other of which is substantially closed, said chambers being connected so that said ionization detection means provides an output voltage that varies depending upon sensed products of combustion in the atmosphere surrounding said open chamber;
a reference voltage source providing a reference vol-tage output;
comparator means for receiving said output from said ionization detection means and said reference voltage out-put, said comparator means having an inhibit input, a drive output and a sink output and providing an output if the output from said ionization detection means exceeds said reference voltage output from said reference voltage source;
trigger means including first and second interconnected normally nonconductive transistors one of which is connected with said comparator means to receive said drive output therefrom and the other of which is connected with said inhibit input of said comparator means whereby said trans-istors are caused to become conductive upon receiving an output from said comparator means;
alarm indicating means connected with said trigger means and, responsive to said transistors becoming con-ductive, causing and maintaining an alarm condition; and means for receiving said alarm indication from said alarm indicating means and indicating an alarm condition.
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US05/623,147 US4091364A (en) | 1974-09-09 | 1975-10-16 | Combustion detection device |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1046654A true CA1046654A (en) | 1979-01-16 |
Family
ID=24496973
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA241,492A Expired CA1046654A (en) | 1975-10-16 | 1975-12-10 | Combustion detection device |
Country Status (1)
| Country | Link |
|---|---|
| CA (1) | CA1046654A (en) |
-
1975
- 1975-12-10 CA CA241,492A patent/CA1046654A/en not_active Expired
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