JPS6223920B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a fire detector that has a plurality of operating points and generates a different signal for each operating point.

Traditionally, fire doors have been activated in conjunction with the operation of fire detectors.
Controlled equipment such as smoke exhaust equipment or fire extinguishing equipment is driven. However, these controlled devices do not use conventional fire detectors, especially ion-type smoke detectors that use a large number of semiconductor components, even though there is a risk of serious damage if they are accidentally activated. In such cases, electrical noise or cigarette smoke can easily cause malfunctions, and for this reason, fire detectors for interlocking equipment are required to be extremely reliable.

The fire detector according to the present invention satisfies the above requirements by simply adding a simple circuit to a conventional fire detection section, and will be described in detail below with reference to the drawings.

FIG. 1 is a circuit diagram showing an embodiment of a fire detector according to the present invention, in which a reference ion chamber 1 serves as a fire detection section and a saturated ion current ionized by a radiation source 10 flows between a pair of electrodes; This is an embodiment using an ion type smoke detector comprising a series electrical circuit with a measurement ion chamber 2 through which a current of unsaturated ions ionized by a radiation source 20 flows between a pair of electrodes. This reference ion chamber 1 and measurement ion chamber 2
Both ends of the series circuit consisting of are connected between terminals L and C, and the series junction point 3 is the first field effect transistor _Q1 and the second field effect transistor Q1.
Q ₂ [hereinafter abbreviated as first FET Q ₁ and second FET Q ₂ ] are connected to respective gate electrodes. The drain electrodes of the first FET Q ₁ and the second FET Q ₂ are connected to one terminal L, and the source electrodes are connected to the other terminal C via resistors R ₁ and R ₂ , respectively. There is. The gate electrode of the first SCR S ₁ is connected to the source electrode of the first FET Q ₁ , and the anode electrode of the first SCR S ₁ is connected to one side via the first Zener diode Z ₁ . and its cathode electrode is connected to the other terminal C. Also, the second
The source electrode of FET Q ₂ is connected to the gate electrode of the second SCR S ₂ via the second Zener diode Z ₂ , and the anode electrode of this second SCR S ₂ is connected to one terminal L. and its cathode electrode is connected to the other terminal C.

FIG. 2 is a circuit diagram showing an embodiment of a receiver suitable for connection to a fire detector according to the present invention, in which a pair of receivers are connected to terminals L and C of the fire detector D via lines, respectively. Terminals L ₀ and C ₀ are provided, and a power source E is connected between the terminals L ₀ and C ₀ via a signal detection resistor R ₃ and a recovery switch SW. The detection side of the resistor _R3 for signal detection is
They are connected to the base electrodes of the first transistor T ₁ and the second transistor T ₂ via resistors R ₄ and R ₅ , respectively. The emitter electrode of the first transistor _T1 is connected to one end of the power source E, and the collector electrode is connected to the other end of the power source E via a fire alarm relay RL.
It is connected to one end of the power source E via the first normally open contact rl ₁ of RL. The emitter electrode of the second transistor T ₂ is connected to the power supply E through a Zener diode Z ₃
The collector electrode is connected to the power source E through a series circuit consisting of two resistors R ₆ and R ₇ .
connected to the other end. Junction 4 of this series circuit is connected to the base electrode of the third transistor T ₃ . The collector electrode of this third transistor _T3 is connected to one end of the power source E via the controlled device control relay CL, and the emitter electrode is connected to the other end of the power source E. A fire indicator K and a control indicator H are connected between both ends of the power source E via the second normally open contact rl ₂ of the fire alarm relay RL and the normally open contact cl of the controlled equipment control relay CL, respectively. There is.

The operation when the fire detector D according to the present invention shown in FIG. 1 is connected to the receiver J shown in FIG. 2 will be described below based on the characteristic curve diagram shown in FIG. 3. explain. In Figure 3, the horizontal axis represents the voltage V at the series connection point 3 of the series circuit consisting of the reference ion chamber 1 and the measurement ion chamber 2, and the vertical axis represents the current I flowing through both ion chambers 1 and 2. The voltage-current characteristic of the reference ion chamber 1 under normal conditions when no smoke is present in the measurement ion chamber 2 is shown by a curve A ₀ , and that of the measurement ion chamber 2 is shown by a curve B ₀ . Therefore, under normal conditions, the voltage at the series connection point 3 is low and stable at the voltage V ₀ at the point P ₀ where both curves _{A 0} and B ₀ intersect _. The source voltage is also kept low. When a fire breaks out and the smoke enters the measurement ion chamber 2 and its concentration increases, the voltage-current characteristic of the measurement ion chamber 2 changes to the characteristic shown by curve B ₁ , and the series connection point The voltage of 3 is the point P ₁ where this curve B ₁ and the curve A ₀ of the reference ion chamber 1 intersect.
The voltage increases to V ₁ [V ₁ > V ₀ ]. Then both FETs
The source voltages of Q ₁ and Q ₂ also rise and the first SCR S ₁ is triggered. However, the second SCR S ₂
Since the trigger voltage is set higher than that of the first SCR S ₁ by the Zener diode Z ₂ , the trigger voltage will not be triggered at this voltage V ₁ . 1st SCR
When _S1 is triggered, conduction occurs between terminals L and C through the first Zener diode _Z1 , and terminals L and C
Since the voltage between them drops to the Zener voltage of the first Zener diode _Z1 , a signal voltage is generated in the signal detection resistor _R3 on the receiver J side, and the conduction voltage increases to the second Zener diode _Z3 due to the action of the Zener diode Z3. The first transistor T ₁ which is set lower than the transistor T ₂ conducts first and the fire alarm relay PL is energized. The fire alarm relay PL closes its first normally open contact rl ₁ to hold itself, and drives the fire indicator K by closing its second normally open contact rl ₂ ,
Displays the operation of fire detector D. At this stage,
Controlled equipment such as fire extinguishers has not yet been activated, so if this display state continues for a long time,
Appropriate measures can be taken by contacting the site and confirming that the alarm was not a false alarm.

As mentioned above, on the fire detector D side, the voltage between its terminals L and C drops to the Zener voltage of the first Zener diode _Z1 , so the reference ion chamber 1
The voltage-current characteristics of the curve _A1 also move down in voltage to the characteristics shown by curve A1. Therefore, the voltage at the series junction point 3 is also between this curve A ₁ and the curve B ₁ of the measurement ion chamber 2.
The voltage drops instantly to the voltage V ₂ at the intersection point P ₂ [V ₂ <
_V1 ]. As the scale of the fire expands and the smoke concentration further increases, the voltage-current characteristics of the measurement ion chamber 2 change to the characteristics shown by curve B ₂ , and this curve B ₂ and the reference ion chamber 1 Point P ₃ where curve A ₁ intersects
The voltage V ₃ at the series junction 3, denoted by V 3 , finally becomes high enough to trigger the second SCR S ₂ via the second FET Q ₂ and the second Zener diode Z ₂ [V ₃ >V ₁ ]. When the second SCR S ₂ is triggered, conduction occurs between terminals L and C with low impedance, so the signal detection resistor on the receiver J side
The signal voltage appearing on R ₃ increases further, the second transistor T ₂ becomes conductive, and the third transistor T ₃
Controlled equipment control relay CL is energized via. The controlled equipment control relay CL has its normally open contact
cl is closed to drive the control display H, and at the same time, a drive signal is sent to the controlled equipment via its contacts (not shown).

As described above, the fire detector D according to the present invention
The first SCR S ₁ is triggered by relatively low concentration smoke, the voltage applied to the ionic smoke detector is dropped, and the second SCR S ₂ is triggered by even higher concentration smoke. In other words, when a relatively low concentration of smoke is detected, the detection sensitivity is lowered by lowering the voltage applied to the detection part, and when even higher concentration smoke is detected. Only the next signal is sent out.

In addition to the above-mentioned ionic smoke detector, there are conventional detectors whose detection sensitivity changes depending on changes in the voltage applied to both ends, such as photoelectric smoke detectors and heat-sensitive semiconductor heat detectors. It has been known.

Therefore, a detector for detecting various phenomena associated with such fires is needed.
Another embodiment of the fire detector according to the present invention, which has a simpler structure and operates as described above using an FD, is shown in FIG. This fire detector D ₀ is
A first SCR S ₃ to which the output voltage from the detection unit FD is directly applied to the gate electrode, and a second SCR S ₄ to which the voltage divided by two resistors R ₈ and R ₉ is applied.
and when the first SCR S ₃ is triggered, the detector FD
Two resistors R ₁₀ that reduce the voltage applied to R 10 ,
It consists of R ₁₁ . In the fire detector D ₀ configured as described above, when the detection unit FD detects a fire phenomenon at a relatively early stage, it triggers the first SCR S ₃ and sends a first signal to the receiver side. first
By the trigger of SCR _S3 , the two resistors _R10 and _R11 reduce the voltage applied to the detection section FD, thereby reducing the detection sensitivity of the detection section FD. When the fire phenomenon progresses to the extent that it is necessary to drive the controlled equipment, the second SCR _S4 , in which the divided voltage of the two resistors _R8 and _R9 is applied to the gate electrode, is triggered. There is low impedance between terminals L and C,
A second signal is sent to the receiver side.

As described above, the fire detector according to the present invention is
By skillfully taking advantage of the fact that the detection sensitivity of the detection section for various phenomena associated with fire depends on the applied voltage, it is possible to have multiple operating points with just a single detection section and a simple circuit. The present invention is useful for disaster prevention, as it enables the production of fire detectors and enables the manufacture of highly reliable fire detectors for use with controlled equipment at low cost.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram showing an embodiment of a fire detector according to the present invention, FIG. 2 is a circuit diagram showing an embodiment of a receiver suitable for connection to the fire detector according to the present invention, and FIG. The figure is a characteristic curve diagram used to explain the operation of the fire detector according to the present invention, and FIG. 4 is a circuit diagram showing another embodiment of the fire detector according to the present invention. FD...detection unit, D, D ₀ ...fire detector.

Claims (1)

[Scope of Claims] 1. A fire detector having a detection section whose detection sensitivity changes due to fluctuations in applied voltage, including a circuit that is controlled by the output of the detection section and controls the voltage applied to the detection section. A fire detector featuring: 2. The fire detector according to claim 1, wherein the detection section is an ionic smoke detection section.