AU621675B2 – Fire alarm system
– Google Patents
AU621675B2 – Fire alarm system
– Google Patents
Fire alarm system
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Info
Publication number
AU621675B2
AU621675B2
AU43751/89A
AU4375189A
AU621675B2
AU 621675 B2
AU621675 B2
AU 621675B2
AU 43751/89 A
AU43751/89 A
AU 43751/89A
AU 4375189 A
AU4375189 A
AU 4375189A
AU 621675 B2
AU621675 B2
AU 621675B2
Authority
AU
Australia
Prior art keywords
analog
fire
type sensor
receiver
detection
Prior art date
1988-10-31
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Ceased
Application number
AU43751/89A
Other versions
AU4375189A
(en
Inventor
Sadataka Yuchi
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Hochiki Corp
Original Assignee
Hochiki Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
1988-10-31
Filing date
1989-10-25
Publication date
1992-03-19
1989-10-25
Application filed by Hochiki Corp
filed
Critical
Hochiki Corp
1990-05-03
Publication of AU4375189A
publication
Critical
patent/AU4375189A/en
1992-03-19
Application granted
granted
Critical
1992-03-19
Publication of AU621675B2
publication
Critical
patent/AU621675B2/en
2009-10-25
Anticipated expiration
legal-status
Critical
Status
Ceased
legal-status
Critical
Current
Links
Espacenet
Global Dossier
Discuss
238000001514
detection method
Methods
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claims
abstract
description
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Effects
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monitoring process
Methods
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Methods
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smoke
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Methods
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signal transmission
Effects
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description
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1,3,4,8-tetrahydropyrimido[4,5-c]oxazin-7-one
Chemical compound
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Classifications
G—PHYSICS
G08—SIGNALLING
G08B—SIGNALLING OR CALLING SYSTEMS; ORDER TELEGRAPHS; ALARM SYSTEMS
G08B29/00—Checking or monitoring of signalling or alarm systems; Prevention or correction of operating errors, e.g. preventing unauthorised operation
G08B29/18—Prevention or correction of operating errors
G08B29/185—Signal analysis techniques for reducing or preventing false alarms or for enhancing the reliability of the system
G08B29/188—Data fusion; cooperative systems, e.g. voting among different detectors
G—PHYSICS
G08—SIGNALLING
G08B—SIGNALLING OR CALLING SYSTEMS; ORDER TELEGRAPHS; ALARM SYSTEMS
G08B17/00—Fire alarms; Alarms responsive to explosion
G—PHYSICS
G08—SIGNALLING
G08B—SIGNALLING OR CALLING SYSTEMS; ORDER TELEGRAPHS; ALARM SYSTEMS
G08B26/00—Alarm systems in which substations are interrogated in succession by a central station
G08B26/001—Alarm systems in which substations are interrogated in succession by a central station with individual interrogation of substations connected in parallel
G08B26/002—Alarm systems in which substations are interrogated in succession by a central station with individual interrogation of substations connected in parallel only replying the state of the sensor
Abstract
A fire alarm system includes a receiver (1) adapted to detect the presence of a fire on the basis of analog detection data contained in a received signal which is connected by means of a transmission line (2) to a plurality of analog type sensors (3), each of which is arranged in a respective monitoring area monitored by the receiver and is adapted to produce analog detection data representative of the value of a parameter, or a change thereof, caused by a fire and to transmit the data to the receiver. Associated with each analog type sensor (3) is a plurality of on-off type sensors (7) which are arranged in the same monitoring area as the associated analog type sensor, are adapted to be switched to produce a fire signal when the change in the said parameter exceeds a predetermined threshold value and are connected to a common signal line (6) connected to the associated analog type sensor (3).
Description
i ‘Our Ref: 298093 AUSTRALIA 6 2 1 6 7 M1 Patents Act COMPLET.E RPECITFCATION
(ORIGINAL)
Application Nunber: Lodged: Complete Specification Lodged: Accepted: Published: Priority: Related Art: r rzr i r Applicant(s): 04 64 Hochiki Corporation No. 10-43 Kami-Ohsaki 2-chome Shinagawa-ku Tokyo
JAPAN
ARTHUR S. CAVE CO.
Patent Trade Mark Attornerys Level 10, 10 Barrack Street SYDNEY NSW 2000 4 0 o Address for Service: 0 4 0 0o0a Complete specification for the invention entitled “Fire alarm system”.
The following statement is a full description of this invention, including the best method of performing it known to me:- 1 5020 Fire Alarm System BACKGROUND OF THE INVENTION Field of the Invention This invention relates to a fire alarm system and, more particularly, to a fire alarm system including a receiver having the function of detecting a fire based on analog detection data contained in a received signal, at least one analog type sensor provided in at Least one monitored area monitored by the receiver, in combination with one or more on-off type sensor, and a transmission line interconnecting the analog type and on-off type sensors and the receiver.
oon 0 o o 0 Q 0 a o o Discription of the Prior Art o As this type of the fire alarm system, such system in o 0o OO od.. which a plurality of so-called on-off type sensors each having a switching element which is turned on in case of fire detection are connected to a transmission line from a receiver, is most popular. This on-off type sensor senses t Et changes in the surrounding physical phenomena caused by the l fire, such as those in the temperature or smoke concentrati.on. When the magnitude of the changes exceeds a predetermined threshold value, the switching element is actuated to transmit fire alarm signals or, more precisely, current signals, to the receiver over the transmission line.
In short, with the on-off type sensor, it is the sensor itself that decides whether or not the fire has broken out.
On the other hand, a fire alarm system has been evolved la ii ra~–rg in which it is not the sensor itself, as in the on-off type sensor, but the receiver, that has the function of determining whether or not the fire has broken out. In this case, an analog type sensor, which senses the extent of the changes in the surrounding physical phenomena caused by the fire as an analog value, is used as the sensor. The analog detection signal outputted from the sensor is transmitted over the transmission line to the receiver where it is determined from the received analog detection data whether or not the fire has broken out.
With such analog fire alarm system, since the receiver gives a judgment as to the possible occurrence of a fire, it o o becomes possible to perform ingenuous signal processing, 😮 such as predictive judgment on the fire occurrence. Also, o o since the analog data itself is handled, no mistaken fire report, such as is often made by the on-off type sensor, cannot be made, so that early fire detection can be achieved with the minimum risk of mistaken signalling.
,A a o With such analog fire alarm system, it becomes 0 necessary to distinguish output analog data from a plurality 0 0
O
ca e of analog type sensor connected to the same transmission network. For this reason, an address is set for each of the o o analog type sensors and each sensor is adapted to sequentially transmit its own analog detection data to the receiver over the transmission line by time divisional multiplexed transmission according to a polling system. In this case, a reset pulse and a plurality of clock pulses are transmitted at a predetermined time interval from the
J/
2 receiver to the analog type sensors. The clock pulses start to be counted at the sensor since the time when the reset puLse is received. When the count vaLue reaches the clock count allocated to a specific receiver, it is determined that the receiver has been interrogated, and the analog detection data contained in the receiver at this time is sent to the receiver after conversion into a corresponding electrical current value.
However, in such conventional analog fire alarm system, since the sensors ‘re sequentially interrogated by relying upon the addresses allocated thereto, the time period Sinvolved in interrogating the sensors, that is the polling So period, is necessarily increased with the increase in the C 0 number of the sensors. The result is that limitations are 0 S” imposed on the numbir of the sensors that can be interrogated within a preditermined time period within the allowable Limit of the delay in fire detection and hence on the number of the sensors that can be provided in each metwork.
Thus, in a monitor area of a Larger spatial capacity, such as a large hall, it occurs frequently that the number of the sensors to be installed exceeds the allowable Limit S.per network, with the result that plural analog sensor r networks need be installed in one and the same monitor area by means of receivers or relays with complicated layout and increased costs.
On the other hand, provision of an address sensor in one monitor area results in increased costs and a -3 complicated control operation at the receiver on fire occurrence with a corresponding boad application to the control section.
SUMMARY OF THE INVENTION In view of the above mentioned problems of the prior art system, it is a principal object of the present invention to provide a fire alarm system in which the number of the installed analog type sensors can be mimimized and yet the monitoring function comparable with the case in which the analog type sensors are installed in all of the monitor areas may be achieved, and in which the system setup may be simplified at lower costs.
For accomplishing the above object, the present 0 0 o o: invention provides a fire alarm system comprising a receiver °o having the function of detecting a fire based on analog detection data contained in a received signal, at Least one analog type sensor provided in at Least one monitor area monitored by the receiver, in combination with one or more on-off type sensor, and a transmission Line interconnecting o the analog type sensor-on-off type sensor combination and o0 o “o °o the receiver. The analog type sensor transmits analog detection data proportionate to changes in surrounding gut physical phenomena caused by the fire, while the on-off type sensor is switched when the changes in the surrounding S: physical phenomena exceed a preset threshold value to transmit fire signals over the transmission Line. The analog type sensor is connected to the transmission Line, 4 and a separate signal Line is Led out from the anaLog type sensor. One or more on-off type sensors provided in the same monitor area as the analog type sensor is connected to the signal transmission Line. The analog type sensor includes analog detection means for outputting analog detection data proportionate to changes in the surrounding physical phenomena caused by the fire, fire detection means for detectiong fire signals from the on-off type sensor and transmission control means for transmitting signals containing the analog detection data from the analog detection means and the data concerning the presence or absence of the fire detection signals from the fire detection means.
According to a preferred embodiment of the present 0 0 oa oo invention, the analog type sensor includes a mounting base P 0 0 S, section fixedly provided to a ceiling or wall surface of a “oOO. building and a detection head section detachably mounted to ttt the mounting base section. The fire detection means and the transmission control means are provided in the mounting base section and the analog detection means are provided in the S1 detection head section.
a oo With the above de. cribed fire alarm system of the present invention, the sensors are grouped in plural sets each consisting of an analog sensor and one or more on-off Stype sensors connected in common to a signal line led out o« e from the analog type sensor.
o a Thus the number of the analog type sensors in need of address setting can be reduced markedly, such that only one 5 rr~ l-rrrpl~L6~riF analog sensor circuit or network suffices to get the sensors connected in their entirety to the receiver even for a broader monitor area.
When a plurality of the on-off type sensors are Sinstalled around the analog type sensor, the state of the progress of a fire at the mounting sites of the surrounding on-off type sensors can be judged to some extent by the sole analog type sensor for the monitored area covered by the same group of the sensors, so that the fire discerning function proper to the analog type sensor can be displayed to the maximum extent possible. The site of the fire can also be located from the addresses allotted to the sensors.
According to the present invention, as described hereinabove, the number of address settings based on which I interrogations from the receiver are made may be drastically reduced even for a broader monitor area, such as a large hall, where a large number of the sensors has to be r installes, since the address setting can be made with the sole analog type sensor and the associated on-off type sensor or sensors as one group. Also, since the group can S’be identified by the address allocated to the analog type o 44 S.’o sensor, the site of fire can be located promptly so that *oo* measures can be taken at an earlier time. Since one of the .at sensors of a group of sensors in necessarily an analog type sensor, the detailed state of the monitor area covered by a group of the sensors, such as the smoke or temperature, can be grasped, so that a more satisfactory fire monitoring function can be displayed as compared with the system
II
employing only the on-off type sensors.
In addition, the number of the installed analog type sensors can be reduced significantly as compared to the system employing only the analog type sensors, so that the system constrnction inclusive of the control function by the receiver can be simplified with reduction in equipment costs.
The above and other objects and features of the present invention will become more clear from the following description of the preferred embodiment of the invention especially when read in conjunction with the accompanying drawings.
BRIED DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram showing an embodiment of the o* i 1present invention.
S* rig. 2 is an illustrative view showing a mounting exanple of the sensors according to the present invention.
Fig. 3 is a singal timing chart showing the state of interrogation of and response by the sensors in the oo* o* embodiment of Fig. 1.
O o o Fig. 4 is a flow chart showing the operational flow at the side of the sensors in the embodiment shown in Fig. 1.
0 7 DESCRIPTION OF THE PREFERRED EMBODIMENTS Fig. 1 is a block diagram showing an ebodiment of the present invention.
Referring to this figure, an analog type sensor 3 is connected to a transmission line 2 which is Led out from a receiver 1 and which is adapted to perform power suppLy to the system and to effect signal transmission.
The analog type sensor 3 is made up of a base section 4 and a head section 5. The head section 5 is provided with a detection circuit 9 for analog detection of changes in certain physical phenomena, such as smoke concentration, caused by a fire. The analog data detected by the circuit 9 are supplied via an analog output circuit 10 to the base 5 ,section 4.
o, The base section 4 is provided with transmission control circuit 11 for converting the analog detection data from the analog output circuit 10 of the head section 5 into electrical current signals and transmitting the electrical current signals over the transmission Line 2 to the receiver 1.
The transmission controL circuit 11 provided in the base section 4 is responsive to polling control signals from the receiver 1 to transmit analog detection data from the output circuit 10 in the current mode on being interrogated.
More specifically, the receiver 1 repeatedly performs an interrogating operation of sending out plural clock pulses to the transmission Line 2 after sending out a reset pulse. The control circuit 11 clears a counter, not shown, 8 with the reset pulse transmitted froi the receiver 1 over Line 2 and counts the clock pulses following the reset pulse. When the count of the clocks coincides with a preset address set in the analog type sensor 3, that is, a predetermined count, the circuit 11 decides that it is being interrogated anJ converts the analog detection data from the head section 5 into a corresponding electrical current which is sent to the receiver 1. For making this decision, an address setting unit 14 is provided in the control circuit 11.
The base section of the analog type sensor 3 is provided with a fire detection circuit 12 from which a signal line 6 serving simultaneonsLy as a power supply Line is led to outside. A plurality of on/off type sensors 7 are o connected to the signal Line 6, to the terminal part of 0 o. which a terminal resistor 8 for disconnection detection is connected.
Each on-off type sensor 7 is switched when the change in a physical parameter by a fire exceeds a predetermined threshold to emit a fire signal in a known manner. Thus the sensor 7 itself has the function of determining the occurrence of a fire. More specifically, the on/off type sensor 7 sends out on fire detection an alarm current over the signal line 6 by a switching operation. This alarm current is detected by the fire detection circuit 12 Sprovided in the base section 4 of the analog type sensor 3 so as to be transmitted to the control circuit 11.
A disconnection detection circuit 13 is provided in the 9 base section 4 in association with the signal Line 6 Led out from the detection circuit 12. The disconnection detection circuit 13 senses that the disconnection monitoring current flowing in the terminaL resistor 8 is interrupted due to disconnection of the signaL Line 6 to output a disconnection detection signaL to the transmission controL circuit 11.
Thus the control circuit 11 provided in the base section 4 has, in addition to the function of transmitting the anaLog detection data from the output circuit 10 of the head section 5 to the receiver 1, the function of transm.tting the fire detection signaL from the circuit 12 or the disconnection detection signaL to the recevier 1 after conversion from the circuit 13 into eLectricaL P064r* currents, simiLarLy to the anaLog detection signaL.
o 4 Fig. 2 is an explanatory view showing a mounting S0 oo exampLe of the sensors in an monitoring area covered by the Oti fire aLarm system of the present invention.
In this figure, the receiver 1 covers three monitoring Sareas 14, 15, 16, in each of which 7 to 9 sensors, for tc exampLe, need be provided as a function of the surface measure of the areas 14 to 16.
For each of these monitor areas 14 to 16, there are provided in the fire alarm system of the present invention t an anaLog type sensor 3 at, for exampLe, the center of each of the areas 14 to 16, and a plurality of on-off type t sensors 7 around the analog type sensor 3. The on-off type sensors 7 of each of the areas 14 to 16 are connected to the signaL Line 6 Led from the fire detection circuit 12 in the 10 i base section 4 of the analog type sensor 3, for each of the areas 14 to 16.
With the sensor disposition and connection for each of the areas 14 to 16 of the fire alarm system according to the present invention, it is necessary to provide three addresses for the receiver 1 to make interrogations. If the system of the same scale in constituted as the prior-art system, all of the sensors are the analog type sensors, so that address setting in necessitated for each sensor and hence 23 addresses are necessitated for the t’hree monitor areas 14 to 16. Conversely, the rumber of the necessitated addresses is reduced drastically to three in the embodiment of Fig. 2.
0 In as much as the analog type sensor 3 capable of p o o collecting detailed fire data is provided at the center of 00 each of the monitor areas 14 to 16, and the on-off type #0 00 0 0 sensors 7 are placed there around, detailed fire data such as smoke or temperature caused by fire in the detection regions of the peripherally disposed on-off type sensors 7 may be roughly grasped by the centrally disposed analog type sensor 3.
For example, when the fire is detected by sie of the on-off type sensor 7 in the monitor area 14, analog detection data such as smoke concentration is obtained by the centrally disposed analog type sensor 3 and displayed in the receiver to allow to grasp the state of progress after the start of the fire in the monitor area 14 by the receiver 1.
11 The operation of the embodiment shown in Fig. 1 is explained with reference to a timing chart of Fig. 3 and a flow chart for the analog type sensor of Fig. 4.
During steady-state monitoring, the receiver 1 performs a repetitive operation of sending out over the transmission line 2 a reset puLse followed by clock pulses A1, A2, A3, for determining sensor interrogating addresses.
As shown by the flow chart of Fig. 4, the transmission control circuit 11 provided in the base section 4 of the analog type sensor 3 in responsive to the interrogation by the clock pulses from the receiver 1 to count the clock pulses from the receiver at step S1 to decide if the count coincides with a preset own address. If the count is decided at step S1 to be the preset address, the program proceeds to step S2 where it is first checked whether an t alarm is issued from the on/off type sensor 7, that is, 04 0 Swhether the fire detection output is issued from any of the o0 on-off type sensors 7 connected by the fire detection circuit ‘1 to the signal Line 6.
The program then proceeds to step S3 where an analog 0 0 e O, ?O utput value of the detection circuit 9 from The analog output circuit 10 provided in the head section 5 is checked.
The program then proceeds to step S4 where it is 0 checked whether a disconnection detection output is issued oa from the detection circuit 13 provided in the base section 0 t 4.
The program then proceeds ultimately to step S5 where the results at the steps S2, S3 and S4, that is, the 12 functional check outputs sch as the presence or absence of detection data from the on/off type sensors, analog detection data by the analog type sensor or the disconnection, are converted into electrical currents for transmission to the receiver.
Data transmission from the analog type sensor 3 to the receiver 1 with the current mode at step S5 is performed as indicated by the terminal response current shown in Fig. 3b.
Turning to the response current from the analog type sensor, with the clock pulse Al of Fig. 3a having been decided to coincide with the preset address, nine states 0 to 8 are set in the present embodiment during the time interval commencing with the reception of the clock pulse Al g until the reception of the clock pulse A2. The flame
