DE3331203A1 - Device for monitoring the velocity of a gas flow in a duct - Google Patents

Abstract

Device for monitoring the velocity of a gas flow in a duct, in particular for the smoke suction system of a multipoint line smoke alarm. The device has a sensor (10) which is formed by a temperature-sensitive heated element and is arranged directly in the gas flow. The sensor (10) is connected to a temperature compensation circuit (11) which serves for compensating the temperature fluctuations of the gas. A set-point/actual-value comparison circuit (13) serves for monitoring the voltage of the sensor (10), which depends on the velocity of the gas. If the gas velocity over- or undershoots the set-point value which has been set by means of a potentiometer (12), the comparison circuit (13) activates a fault circuit (15) via a time-delay circuit (14). The fault indication is conducted, e.g. to a fire reporting centre. A measurement output circuit (17) serves for setting the limiting value of the gas velocity during commissioning of the device. A heating circuit (20) serves for heating gas suction points should they be blocked by icing. <??>The device is particularly suitable for monitoring in the case of special applications, e.g. in EDP rooms, high-bay warehouses, or in areas where temperatures are below 0 DEG C. <IMAGE>

Description

SECURITON AG Zollikofen (CH).

Device for monitoring the speed of a gas flow in a channel

The invention relates to a device for monitoring the speed of a gas flow in a channel, in particular for the smoke aspiration system of a multi-point line smoke detector, which has a first temperature-sensitive heated element, which is arranged directly in the gas flow and a second temperature-sensitive element ,, which is arranged outside of the gas stream.

A multi-point line smoke detector, also a smoke aspiration system called for fire alarm, has the task of continuously taking air samples from a 'monitored room via a To remove the pipeline network with suction holes and feed them to a smoke detector. This type of detection allows monitoring for special applications such as in IT rooms, high-bay warehouses, cavities that are difficult to access, or in areas with temperatures below 0 C. The functional reliability of such systems depends on a constant air supply to the smoke detector. It is therefore necessary to safely monitor this air supply. In addition the following functions and states of the system must be monitored:

- Correct function of the suction element (fan)

- Breakage of a pipe in the suction line

- The suction points of the suction line are blocked by dust

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or ice formation

- Closure of the air outlet after the suction element

- Air flow, provided the suction points are not in the same place Pressure area are mounted like the suction element.

One way to monitor the air supply is to use a pressure membrane to reduce the negative pressure in the suction line is measured against the ambient pressure. The disadvantage of such pressure monitoring is that only very large pressure changes can be recorded in the system. There is also the possibility that a closure of the Suction points of the pipeline due to dust or ice is not captured because the negative pressure is maintained in the suction system remain.

The invention is based on the object of providing a device for monitoring the flow of a gas in a channel to create that does its job better than the known devices and reliable monitoring guaranteed.

The invention as characterized in the claims solves the problem of creating a device according to the preamble of claim 1 that works properly, offers great functional reliability and is user-friendly. '

In the following the invention is explained in more detail with reference to drawings showing an embodiment.

Show it

Fig. 1: Schematically the structure of the smoke aspiration system of a

multipoint line smoke alarm Fig. 2: The block diagram of the device according to the invention

3: The block diagram of the device according to the invention with heating for smoke extraction points

Fig. 4: Schematically the heating arrangement for suction points. Fig. 5: A detail of the heating arrangement

6: The circuit diagram of the device according to the invention.

In Fig. 1, 1 designates a housing which has a fan 2, an optical smoke detector 3 and a printed Has circuit 4 of the device according to the invention. A pipe network 5 is connected to the housing 1, which is provided with several suction points in the form of small openings 6. The pipe network can take the form of a I, U, H, T or a cross.

The negative pressure generated by the fan 2 has the consequence that the air from the suction points 6 to the smoke detector in the housing is performed, which sends an alarm to a fire alarm center at a certain smoke concentration in the intake air.

In Fig. 2 is the block diagram of the device according to the invention, which is arranged in the housing 1 is shown. The printed circuit board of this device has a Sensor 10, which is arranged directly in the air flow and heated by a temperature-sensitive Element is formed. The probe 10 is connected to a temperature compensation circuit 11 connected, which has a temperature-sensitive element that is outside of the air flow is arranged and serves to compensate for temperature fluctuations in the air.

The measuring sensor 10, for example, in the form of a miniature NTC resistor converts the measured variable air speed into an electrical voltage. The principle of transformation

consists in the fact that the heated NTC resistor is cooled by the air flow and the associated change in resistance is evaluated. At low air speeds the resistance becomes little, at high air speeds more chilled. The associated dependency on the air temperature is determined by the subsequent temperature compensation circuit 11 eliminated.

The output of the temperature compensation circuit 11 is connected to an input of a target / actual comparison circuit 13, which is formed by a window discriminator, connected to the other input of a potentiometer 12 electrical connected is. The window discriminator monitors the voltage at the NTC resistor for a maximum and a maximum minimum value, which corresponds to values or a broken pipe and clogging of the suction points. With the Potentiometer 12 accessible from the outside will set these limit values to the existing, system-specific air speed set. This is done during commissioning with the help of a voltmeter, which is connected to the measuring sockets of a Measurement output circuit 17 is connected, the inputs of this measurement output circuit with the output of the temperature compensation circuit 11 and the. Output of the target / actual comparison circuit 13 are electrically connected. Besides the tension, which corresponds to the difference between the target and actual speed of the air, a second voltage is applied given the measurement output, which enables a measurement of the existing air velocity. These two metrics are alternately sent to the measurement output in a 7s cycle. Exceeds or falls below the air speed the set minimum or maximum value is activated by the window discriminator 13 via a delay circuit 14 a fault output circuit 15 with a delay of 5 to 30 minutes. The delay sequence is indicated by a flashing, optical display by means of a fault message

circuit 18 signals; i.e. the actual air speed deviates only briefly decreases from the set speed, this is only indicated by the flashing display. The fault exit circuit 15 does not become active.

After the delay time, the visual display becomes continuous and the fault report arrives at a fire alarm center via the fault output circuit 15. This message remains until the acknowledgment is made by switching the power supply to the device off and on again and the fault has been rectified held. The fault output circuit 15 is designed so that if the supply voltage fails, a fault occurs a fire alarm center is reported.

In Fig. 3 is a block diagram of the device according to the invention shown with a heating circuit 20 for the suction points of a pipeline network. The in Fig. 2 and 3 corresponding elements have the same reference numerals. The heating circuit 20 is connected to the output of the Target / actual comparison circuit 13 is connected and is used for Heating of the suction points when they are clogged by icing. This can be the case if the smoke aspiration system a multi-point line smoke detector is used in an area with a temperature below 0 C.

In Fig. 4, the heating arrangement for the 'suction points is schematically shown. A heating resistor 33 is arranged at each suction point 6 of the pipe network 5. The heating resistors are connected in series and by means of an electrical lead 3 5 to the device according to the invention im Housing 1, as shown in Fig. 3, connected.

In FIG. 5 a detail of the heating arrangement according to FIG. 4 is shown. A T-piece is designated by 31, which connects two pipe parts 5 to one another. At the T-piece 31 is a

Screwed intermediate piece 32, in which a heating foil is arranged. A closure flap is attached to the intermediate piece 32 34 screwed on with a suction opening 35.

In Fig. 6 is the circuit diagram of the invention Device shown. A voltage divider R24, R25 forms the reference voltage for an operational amplifier Al, which together with a transistor Tl and a resistor R23 the electrical current through an NTC resistor R21 keeps constant and thus heats it up. A change in the resistance value of the NTC resistor R21 as a result of .Cooling in the air flow passes through a resistor R17 as a current signal to an operational amplifier A2. The compensation the air temperature is realized with an NTC resistor R22 ■ and resistors R18, R19, R20 and influenced the output of an operational amplifier A2 so that a proportionality between the air speed and the output voltage of the operational amplifier A2.

When adjusting the target speed of the air flow, a potentiometer P1 is used to set a resistor chain R12, R13, R14, R15 regulated so that their midpoint has the same voltage as the output of the operational amplifier A2. With the resistor chain mentioned, two reference voltages are generated at the same time, which are used for the voltage of the The center point are symmetrical and are used as threshold values at the inputs of the ■ window discriminator Operational amplifier. A3, A4 are created. At an air speed, which is an output voltage of the operational amplifier A2, which is within these threshold values, the outputs of the operational amplifiers "A3, A4 positive and they are blocked by diodes D4, D5. A positive potential is connected to the via a resistor R26 Input 6 of a programmable timer PZ applied,

which has an internal clock generator and an internal counter, the clock frequency being controlled by an external RC circuit R27, R28, C8 is intended. Said positive potential keeps the clock and the counter at zero. Of the Output 8 of the timer PZ is logic 1 and thus it stops via a resistor R30 and a transistor T3 Relay RS picked up. The output 1 of the timer PZ is logic 0, so that a Transistor T2 is blocked and a light emitting diode ST connected to the collector of T2 via a resistor R31, which is used for visual fault indication does not light up.

The output of the operational amplifier A2 is through a resistor R2 connected to a measuring socket + M. A measuring socket-M is controlled by the output of an operational amplifier B1. The operational amplifier B1 receives a signal at one input which corresponds to the target value of the air speed is equivalent to. An operational amplifier B2 has resistors R8 to RlI, a diode D3 and a capacitor C6 switched as a clock, with a switching time of approx. 7 seconds. This clock is sent to the operational amplifier via the diode D2 Bl. If the output of the clock generator B2 is logic 0, then Bl acts as a voltage follower. At the measuring sockets + M, -M there is now a voltage which corresponds to the difference between the setpoint and actual speed of the air. If the output of the clock generator B2 is logical 1, then Bl is inverted so that its output becomes logical 0 and There is a voltage at the measuring sockets which corresponds to the actual value of the air speed.

If the actual value of the air speed changes as a result of clogging of the suction points or breakage of the suction lines and if this new value corresponds to a voltage which lies outside the specified threshold values, then the output of the operational amplifier A3 or A4 logic 0, which is the

Input 6 of the timer PZ is fed so that the clock and the ¹ counter of the timer PZ are activated.

Via the output 1 of the timer PZ and a resistor R2 the clock frequency reaches the transistor T2, which makes the light-emitting diode ST light up intermittently. During 5 minutes the output 8 of the timer PZ remains logic 1 and the transistor T3, which is connected to this output via the resistor R30 is connected remains conductive. To the collective

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The RS relay is connected to the YT3 and does not remain energized. After 5 minutes the counter of the timer PZ reaches its final value, output 8 becomes logic 0, the relay RS drops out and signals a fault. The LED ST lights up continuously.

A relay RH is connected to the output of the operational amplifier A3. As soon as this output is logical 0 because of If the air intake points become blocked, the relay RH closes its contact, so that the resistor RHheat is switched on and heats up the suction points. The output of the operational amplifier A3 remains logic 0 during the suppression time of 5 minutes. If the output of the operational amplifier A3 becomes logical 1 again after opening of the suction points, the relay RH opens its contact, whereby the heating is switched off.

Instead of NTC resistors, diodes can be used without changing the circuit diagram according to FIG will. When using PTC resistors, e.g. made of platinum, nickel, nickel-iron or copper, the Operational amplifier A2 can be wired differently. The PTC resistor R21 must be connected to the positive input of the operational amplifier A2 and the PTC resistor R22 to the negative Input of the operational amplifier A2 can be connected.

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A temperature-dependent element, e.g. R21, can consist of one of the substances mentioned and the other temperature-sensitive Element e.g. R22 made of another of the substances mentioned or a diode, or an NTC resistor. In these In some cases, the circuit diagram according to FIG. 6 must be changed by using either the polarities of the voltages to which the resistors R21, R22 or diodes are connected change, and / or the operational amplifier A2 wired differently will.

Claims (22)

SECURITON AG Zollikofen (CH) Patent claims fly device for monitoring the speed of a gas flow in a channel, in particular for the smoke suction system of a multi-point line smoke detector, which has a first temperature-sensitive heated element which is arranged directly in the gas flow and a second temperature-sensitive element which is arranged outside the gas flow, marked by, electronic means (R24, R25, Al, R23, Tl) for heating the first temperature-sensitive element (R21), Means (R22, R20, R18, R19, A2) to compensate for temperature fluctuations in the gas, Means (R12, R13, R14, R15, A3, A4) for monitoring the gas velocity-dependent voltage on the first temperature-sensitive element (R21), Means (R27, R28, C8, PZ, T3, RS, T2, ST) for evaluating the output voltage of the mentioned means for monitoring, which evaluation means are designed in such a way that when the means a potentiometer (P1) connected to the above-mentioned means for monitoring, adjustable setpoint speed of the gas flow, which lasts longer than a certain time, an error message is issued. 2. Device according to claim 1, characterized in that the temperature-sensitive elements (R21, R22) Thermistors are
t 3. Device according to claim 2, characterized in that that the temperature-sensitive elements (R21, R22) NTC resistors are. 4. Apparatus according to claim 2, characterized in that the temperature-sensitive elements (R21, R22) PTC resistors are. 5. Apparatus according to claim 4, characterized in that that the temperature-sensitive elements (R21, R22) are made of platinum. 6. Apparatus according to claim 4, characterized in that that the temperature-sensitive elements (R21, R22) are made of nickel. 7. The device according to claim 4, characterized in that the temperature-sensitive elements (R21, R22) are made of a nickel-iron alloy. 8. Apparatus according to claim 4, characterized in that that the temperature-sensitive elements (R21, R22) are made of iron. 9. The device according to claim 4, characterized in that the temperature-sensitive elements (R21, R22) are made of copper. 10. The device according to claim 1, characterized in that the temperature-sensitive elements (R21, R22) Diodes are. 11. The device according to claim 1, characterized in that are that the temperature-sensitive elements of different materials ^l. 12. The device according to claim 1, characterized in that that the means for heating the first temperature-sensitive element (R21) is an operational amplifier (Al) and a transistor (Tl). 13. The device according to claim 1, characterized in that the means for compensating for the temperature fluctuations of the gas, the second temperature-sensitive element (R22), a voltage divider (R18, R19) and a Have operational amplifier (A2). 14. The device according to claim 1, characterized in that the means for monitoring the gas velocity the gas-dependent voltage at the first temperature-dependent element (R21) a voltage divider (R12, R13, R14, R15) and a window discriminator (A3, A4), and that on said voltage divider Potentiometer (Pl) is connected. 15. The device according to claim 1, characterized in that the means for evaluating a programmable Timers (PZ), in which a binary counter and a clock generator are integrated, have the clock frequency the clock is determined by an external RC circuit (R27, R28, C8), and that the timer (PZ) is designed and connected in such a way that it has fault reporting means with a programmable delay (T3, RS) controls. 16. The device according to claim 15, characterized in that that at an output (3) of the timer (PZ) a relay (RS) via a transistor (T3) for remote reporting a fault is connected after a delay time of 5 to 30 minutes, and that with another Output (1) of the timer (PZ) a light emitting diode (ST) is electrically connected via a transistor (T2), " which intermittently with during the delay time of the clock frequency lights up and after the delay time it lights up continuously for a visual display of a fault shines. . ' 17. The device according to claim 16, characterized in that that the relay (RS) is energized in the normal state and in the event of a failure of the supply voltage for the purpose of error reporting falls off. j 18. Device according to djan claims 14 and 15,. Characterized in that! a relay is connected to an output of the window discriminator (A3, A4), which during the delay time keeps the feed circuit of a heating resistor (Rneiz) closed ^for heating the suction points of a smoke aspiration system. 19. Device according to claims 13 and 14, characterized in that that a first measuring socket (+ M) to the output of the operational amplifier (A2) of the means for Compensation of the temperature fluctuations of the gas and a second measuring socket (-M) to the output of a Operational amplifier (Bl) is connected, one input of which with the midpoint of the voltage divider (R12, R13, R14, R15) of said means for monitoring is electrically connected and its other input connected to a clock (B2, R8, R9, C6) is, the whole being designed in such a way that at the measuring sockets (+ M, -M) a voltage, which the gas velocity and a voltage which the Difference between the target and actual speed
of the gas is measurable. 20. Use of the device according to claims 1 and 18 in a range with a temperature below 0.degree
for the smoke aspiration system of a multi-point line smoke detector. 21. ' Use according to claim 20, characterized in that that a heating resistor (33) is arranged at each smoke suction point (6) of the smoke suction system, that the heating resistors are connected in series and by means of an electrical lead (35) to the device (1, 2, -3, 4) are connected. 22. Use according to claim 21, characterized in that at each smoke suction point (6) a T-piece (31) connects two pipe parts (5) together that an intermediate piece (32) is screwed to the T-piece that in the Intermediate piece, a heating film (33) is arranged, and that a closure cap (34) is attached to the intermediate piece a suction opening (35) is screwed on.