NL8402448A - DEVICE FOR CONTROLLING THE SPEED OF A GAS FLOW IN A CHANNEL. - Google Patents

Description

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Device for controlling the velocity of a gas flow in a channel.

The invention relates to a device for controlling the velocity of a gas flow in a duct, in particular for the smoke extraction 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 located outside the gas flow.

A multipoint-shaped line smoke detector, also called a smoke aspiration system for fire detection, has the task of continuously taking air samples from a room to be monitored via a pipeline network with suction openings and supplying these to a smoke detector. This method of detection allows control in special applications such as, for example, in EDV spaces, high-regal warehouses, hard-to-access cavities, or also in the region of a temperature below Ö ° C. The reliability of such systems depends on a steady air supply to the smoke detector. It is therefore required to check this air supply reliably. To this end, the following functions and states of the system must be checked:

Correct functioning of the suction element (fan)

Breakage of a pipe in the suction pipe 25 Blockage of the suction points of the suction pipe due to dust or icing

Blocking of the air outlet to the suction element

Airflow, provided that the suction sites 30 are not mounted in the same pressure area as the suction element.

One possibility to check the air supply is that the underpressure in the suction line is measured with respect to the ambient pressure by means of a pressure membrane. The drawback of such a pressure control is that only very large pressure changes can be measured in the system. Furthermore, there is the possibility that a blockage of the suction site of the pipe line by dust or ice cannot be detected, since the negative pressure in the suction system 5 is maintained.

The present invention is based on the problem of providing a device for controlling the flow of a gas in a channel, which is better suited to its task than the known devices and which ensures reliable control.

To this end, the invention provides an apparatus as described in the preamble, characterized by electronic means for heating the first temperature-sensitive element, means for compensating the temperature fluctuations of the gas, means for controlling the voltage dependent on the gas velocity on the first temperature-sensitive element, 20 'means for evaluating the output voltage of said means for checking, which evaluation means are designed such that upon coming below or above the potentiometer 25 connected to said checking means adjustable nominal speed of the gas flow, which lasts longer than a certain time, an error message occurs. Such a device functions without interference, offers greater operational reliability and is easy to operate.

The invention will be further elucidated hereinbelow on the basis of an exemplary embodiment with reference to the drawing. In the drawing: Fig. 1 schematically shows the structure of the smoke extraction system of a multi-point line smoke detector, Fig. 2 shows the block diagram of the device according to the invention, Fig. 3 shows the block diagram of the device according to the invention with heating for smoke aspiration sites Fig. 4 schematically shows the heating device 40 for suction sites, Fig. 5 shows a detail of the heating device, and Fig. 6 shows the circuit diagram of the device according to the invention.

In Fig. 1, 1 denotes a housing, which has a fan 2, an optical smoke detector 3 and a printed circuit 4 of the device according to the invention. A pipe net 5 is connected to the housing 1 and is provided with several suction places 10 in the form of small openings 6. The pipe net can have the form of an I, IJ, Η, T or a cross.

The underpressure generated by the fan 2 results in the air being supplied from the suction points 6 to the smoke detector in the housing 1, which transmits an alarm to a fire alarm control center at a certain smoke concentration of the suction air.

Fig. 2 shows the block diagram of the device according to the invention, which is arranged in the housing 1. The printed circuit of this device 20 has a measuring probe 10 which is arranged directly in the air stream and which is formed by a temperature-sensitive heated element. The measuring probe 10 is connected to a temperature compensation circuit II, which contains a temperature-sensitive element which is arranged outside the air flow and serves to compensate for the temperature fluctuations of the air.

The probe 10, for example in the form of a miniature NTC resistor, converts the measured variable air velocity into an electrical voltage. The principle of the conversion consists in that the heated NTC resistance is cooled by the air flow and the associated resistance change is evaluated.

At small air speeds, the resistance is cooled little, at large air speeds more is cooled. The associated dependence on the air temperature is eliminated by the subsequent temperature compensation circuit 11.

The output of the temperature compensation circuit 11 is connected to one input of a 40 N / W (nominal value / actual value comparison 8402448 - 4 - //

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circuit 13, which is formed by a window discriminator, to the other input of which a potentiometer 12 is electrically connected. The window discriminator controls the voltage at the NTC resistor at a maximum 5 and a minimum value, which values correspond relatively to a pipe break and a blockage of the suction sites. With the potentiometer 12, which is accessible from the outside, these limit values are set to the air velocity specific to the device. This is done during commissioning with the aid of a voltmeter, which is connected to the measuring terminals of a measuring output circuit 17, the inputs of this measuring output circuit being electrically connected to the output of the temperature compensation circuit 11 and the output 15 of the N / W 'comparison circuit 13. In addition to the voltage, which corresponds to the difference between the nominal and the actual speed of the air, a second voltage is given to the measuring output, which allows a measurement of the air velocity present 20 These two measured variables are alternately given to the measuring output in a 7-second rhythm. When the air velocity is above or below the set minimum or maximum value respectively, the window discriminator 13 activates a fault output circuit 15 with a delay circuit 14 with a delay of 5 to 30 minutes. The delay sequence is indicated by a flashing, optical indication by means of a error message circuit 18 signaled? that is, if the actual air speed deviates from the nominal speed by only a short time, this is only indicated by the flashing indication. The fault output circuit 15 does not become active.

After the delay time, the optical indication becomes continuous and the fault message is reached via the fault output circuit 15 at a fire control panel. This message continues until termination by switching the power supply of the device off and on again and rectifying the fault. The fault output circuit 15 is designed such that in the event of failure of the supply voltage, a fault is reported to a fire alarm control panel 8402448 & ^ - 5 -.

Fig. 3 shows a block diagram of the device according to the invention with a heating circuit 20 for suction places of a pipeline network.

The elements corresponding in FIG. 2 and 3 have the same reference numerals. The heating circuit 20 is connected to the output of the N / W (nominal / actual value) comparison circuit 13 and serves to heat the suction sites 10 at their clogging by icing. This can be the case when the smoke extraction system of a multi-point-shaped line smoke detector is used in an area with a temperature below 0 ° C.

In; fig. 4 schematically shows the heating device for the suction sites. A heating resistor 33 is provided at each suction point of the pipe net 5. The heating resistors are connected in series and connected by means of an electrical supply line 35 to the device in the housing 1, as shown in Fig. 3.

Fig. 5 shows a detail of the heating device according to Fig. 4. The 31 is a T-piece, which connects two tube parts 5 to each other. An intermediate piece 32 is screwed to the T-piece 31, in which a heating foil 33 is arranged.

A sealing cap 34 with a suction opening 35 is screwed to the intermediate piece 32. .

Fig. 6 shows the circuit diagram of the device according to the invention. A voltage divider R24, R25 constitutes the reference voltage for an operational amplifier A1, which, together with a transistor T1 and a resistor R23, keeps the electrical current through an NTC resistor R31 constant and therefore heats it. A change in the resistance value of the NTC resistor 21 as a result of cooling in the air flow reaches an operational amplifier A2 via a resistor R17 as a current signal. Air temperature compensation is accomplished with an NTC resistor R22 and resistors R18, R19, R20 and this 40 affects the output of an operational 8402448

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- 6 - amplifier such that there is a proportionality between the air velocity and the output voltage of the operational amplifier A2.

When adjusting the nominal speed 5 of the air flow, a resistance circuit R12, R13, R14, R15 is controlled with a potentiometer PI such that its center shows the same voltage. as the output of the operational amplifier A2. Two reference voltages, which are symmetrical with respect to the voltage of the center point and which are applied as threshold values at the inputs of the operational amplifiers A3, A4, forming a window discriminator, are simultaneously formed with the said resistance circuit. At an air velocity corresponding to an output voltage of the operational amplifier A2, which is within these thresholds, the outputs of the operational amplifiers A3, A4 are positive and are cut off by diodes D4, D5. A positive potential is through a resistor R26 applied to the input 6 of a programmable timer PZ, which has an internal clock and an internal counter, the clock frequency being determined by an external RC circuit R27, R28, C8. The said positive potential keeps the clock and counter at zero. The output 8 of the timer PZ is a logic 1 and thus keeps a relay RS attracted via a resistor R30 and a transistor T3. The output 1 of the timer PZ is a logic zero, so that a transistor T2 connected to this output is blocked and a light-emitting diode ST connected to the collector of the transistor T2 via a resistor R31, which serves for the optical fault indication, lights up. not on.

The output of the operational amplifier A2 is connected via a resistor R2 to a measuring terminal 35 + M. A measuring terminal -M is driven by the output of an operational amplifier B1. The operational amplifier B1 obtains a signal at one input, which corresponds to the nominal value of the air speed. An operational amplifier B2 is switched as a clock with a switching time of approximately 7 seconds, with resistor R8 to Ril, a diode D3 and a capacitor C6 8402448 y - 7. This clock frequency reaches the operational amplifier D1 via the diode D2. If the output of the clock B2 is a logic zero, B1 acts as a voltage-5 follower. The test valves + M, -M now have a voltage corresponding to the difference between the nominal and the actual velocity of the air. If the output of the clock B2 is a logic 1, B1 is inverted, so that the output thereof becomes a logic zero and a voltage corresponding to the actual value of the air velocity is applied to the measuring terminals.

When the actual value of the air velocity changes due to blockage of the suction sites or rupture of the suction lines and this new value corresponds to a voltage which is outside the mentioned threshold values, the output of the operational amplifier A3 or A4 becomes logic zero, which is applied to the input 6 of the timer PZ, so that the clock and counter of the timer PZ are activated.

Via the output 1 of the timer PZ and a resistor R29, the clock frequency reaches the transistor T2, which causes the light emitting diode S2 to light up intermittently.

The output of the timer 25 remains a logic 1 for 5 minutes and the transistor T3, which is connected to this output via the resistor R30, remains conductive.

Relay RS is connected to the collector of transistor T3, which remains not pulled. After 5 minutes, the counter of the timer PZ reaches its end position, the output 8 becomes logic zero, and the relay RS drops out and signals a malfunction. The light-emitting diode ST then lights continuously.

A relay RH is connected to the output of the operational amplifier A3. As soon as this output becomes logic zero due to clogging of the air intake points, the relay RH closes its contact, so that the RJieiz resistor is switched on and the intake points heated. The output of the operational amplifier A3 remains logic zero during the blanking time of 5 minutes. When the output of the operational amplifier 8402448 - 8 - A3 becomes logic 1 again after opening the suction points, the relay RH opens its contact, which switches off the heating.

Diodes 5 can be used instead of NTC resistors without changing the circuit diagram shown in Fig. 6. When using PTC resistors, for example of platinum, nickel, nickel iron, or copper, the operational amplifier A2 must be switched 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.

A temperature-dependent element, for example R21, may consist of one of the said substances, and the other temperature-sensitive element, for example R22, may be of another of the said substances, or a diode or an NTO resistor. In these cases, the circuit diagram of FIG. 6 must be changed by changing · / 1 or the polarity of the voltages to which resistors R21, R22 or diodes are connected, or / and switching operational amplifier A2 differently. .

- conclusions - 8402448

Claims (19)

1. Device for controlling the velocity of a gas flow in a duct, in particular for the smoke extraction system of a multipoint-shaped 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 disposed outside the gas stream, characterized by electronic means (R24, R25, Al, R23, T1). 10 for heating the first temperature sensitive element (R21), means (R22, R20, R18, R19, A2) for compensating the temperature fluctuations of the gas, means {R12, R13, R14, R15, A3, A4) for Checking the gas velocity dependent voltage on the first temperature sensitive element (R21J, means (R27, R28, C8, PZ, T3, RS, T2, ST) for evaluating the output voltage of said means for checking, which evaluation means are designed in such a way that a disturbance message takes place upon coming below or above the nominal speed of the gas flow, which lasts longer than a certain time, which is adjustable by means of a potentiometer (PI) connected to said control means. 2. Device according to claim 1, characterized in that the temperature sensitive elements (R21, R22) are thermistors. 3. Device according to claim 1, characterized in that the temperature sensitive elements (R21, R22J are NTC resistors.) 8402448 Device according to claim 2, characterized in that the temperature sensitive elements (R21, R22) are PTC resistors. v - 10 - 5. Device according to claim 4, characterized in that the temperature-sensitive elements (R21, R22J consist of platinum. 6. Device according to claim 4. with the 5. e. Note that the temperature-sensitive elements (R21, R22] are made of nickel. 7. Device according to claim 4, characterized in that the temperature-sensitive. elements (R21, R22) are made of nickel-iron alloy. 8. Device according to claim 4, characterized in that the temperature-sensitive elements (R21, R22I consist of iron. 9. Device according to claim 4, characterized in that the temperature-sensitive elements. (R21, R22i consist of copper. IQ. Device according to claim 1, characterized in that the temperature-sensitive elements (R21, R22I are diodes. 11. Device as claimed in claim 1, characterized in that the temperature-sensitive elements consist of different substances. 12. Device according to claim 1, characterized in that the means for heating the first temperature-sensitive element (R21I) comprise an operational amplifier (A1 and a transistor (T11). 13. Device according to claim 1, characterized in that the means for compensating the temperature fluctuations of the gas comprise the second temperature sensitive element (R22I, a voltage divider 30 (R18, R19I and an operational amplifier (A2). 14. Device according to claim 1, characterized in that the means for controlling the voltage dependent on the gas velocity of the gas at the first temperature-dependent element (R21) is a voltage divider (R12, R13). , R14, R15] and a window dis-criminator (A3, A4], and that a potentiometer (PI) is connected to said voltage divider. Device according to claim 1, characterized in that the means for evaluating a programmable timer (PZ), in which a binary counter 10 and a clock are integrated, exhibit the clock frequency of the clock by an external RC circuit ( R27, R28, C8] has been determined, and that the timer (PZ) is designed and switched in such a way that it controls jamming means (T3, RS) with a programmable delay Device according to claim 15, characterized in that one output (31 of the timer (PZ) a relay (RS) is connected via a transistor (T3] for the remote reporting of a fault after a delay time of 5 to 30 minutes, and that with another 20 output (II of the timer (PZ) a light-emitting diode (STJ is electrically connected via a transistor (T21), which light-emitting diode lights up intermittently with the clock frequency during the delay time and continuously illuminates after the delay time for the optical indication of a fault. Device as claimed in claim 15, characterized in that the relay (RS] is energized in normal condition and drops out in the event of a power supply failure with a view to an error message. 1 2 3 4 5 6 8402448 18. Device as claimed in claims 14 and 15, 2, characterized in that a relay is connected to one input of the 3 window discriminator (A3, A4), which during the delay time the supply circuit 5 of a heating resistor for heating 6. keeps the intake points of a smoke extraction system closed. * v- 't - 12 - 19. Device according to claims 13 and 14, characterized in that a first measuring clamp (+ M) at the output of the operational amplifier (A2) of the means for compensating the temperature fluctuation of the gas and a second measuring terminal (-M) is connected to the output of an operational amplifier (PI), one input of which is electrically connected to the center of the voltage divider (R12, R13, R14, R151 of the said control means, and of which the other 10 input is connected to a clock (B2, R8, R9, C6), the whole of which is designed such that at the measuring terminals (+ M, -M] in a T-second rhythm, a voltage corresponding to the gas velocity and a voltage , which corresponds to the difference between the nominal and the actual speed of the gas, can be measured. Use of the device according to claims 1 and 18 in an area with a temperature below Q ° C for the smoke extraction system of a multi-point-shaped line smoke detector. The use according to claim 20, characterized in that a heating resistor (33) is arranged at each smoke suction location (6] of the smoke suction system, that the heating resistors are connected in series and by means of an electric supply line (35). are connected to the establishment (1,2,3,41. Use according to claim 21, characterized in that a T-piece (31) connects two pipe sections (5) to each smoke extraction location (6), that an intermediate piece (32) is screwed to the T-piece. that a heating foil (33) is fitted in the intermediate piece, and that a sealing cap (34) with a suction opening (35) is screwed to the intermediate piece. 8402448