DE2318803B2 - Warning signal system - Google Patents

Description

at the same time, the signal portion is blocked, so the simulation of the clad Funklionsbereitschait reveals without simultaneously each a warning signal triggered jrd _w. By gradually changing the threshold value during the periodic test times, details of any errors such as the location of the error, the extent of the resistance deviation or the like can be determined.

The parameter that changes as a result of the state to be checked can be an impedance, for example a resistance dependent on humidity or temperature, but also a capacitive or inductive impedance or the resistance of a pressure sensitive element. However, it can also be a switching function, for example a Breaker contact arrangement or around active circuits.

To explain the invention and to clarify further features, a warning system with a structure according to the invention will be described below with reference to the drawings. In it shows

F i g. 1 is a diagrammatic representation of a warning system according to the invention, which is constructed in such a way that iie responds when moisture collects in an enclosed space and when this space is flooded,

F i g. 2 shows a partial view of the actual, in the case of the warning system in FIG. 1 provided moisture-sensitive Device and

3 shows a circuit diagram of the warning system shown including the necessary electronic amplifier components.

The in F i g. 1 shown warning system is installed in a room I. In which a warning signal device 2 is arranged on one wall. In the extension of this device 2, a moisture-sensitive, strip-like arrangement 3 is provided, which is guided to the floor 4 of the room. In practice, the moisture-sensitive arrangement in the installed state under e ^; A carpet that extends from wall to wall, or under similar floor coverings, or it can be laid close to the ceiling or on the ceiling itself, or in other places where moisture can escape.

In the case of the in FIG. 2, the moisture-sensitive arrangement 3 includes a strip 5 of a textile material into which two electrical conductors 6 and 7 are woven, which are always live and connected to the warning signal device 2. The conductors 6 and 7 are connected to one another at the end of the strip 3 by a resistor 8 forming a current loop, which we shall return to in the description of the mode of operation of the warning signal device. The arrangement is such that when liquid runs out onto the bottom 4, this liquid is sucked up by the strip 5 made of textile material, so that the conductivity of the material between the conductors 6 and 7 increases as a result of the electrical bridging effect of the strip . This leads to a change in the current ratios in the individual circuits of the warning signal device 2, which results in the triggering of the alarm, as will be explained below.

To enable different alarm states and to increase the conductivity when the strip 5 becomes wet, the strip can be filled with substances, such as salts, be impregnated, which are suitable between the! .. festers 6 and 7 such a conductor ability behavior of the material to produce that even with a slight increase in moisture in an alarm is triggered in the room. The actual moisture-sensitive arrangement

tion 3 can for example also be in the form of a paper tire on which the conductors 6 and 7 as Lines of a conductive paint are applied. The moisture-sensitive arrangement can also composed of several layers

ίο be, alternating respectively conductive layers and insulating layers are provided.

As shown in FIG. 3, the warning signal device 2 is made up of three sections which each include electronic components, namely a S'gnahbabschnitt I for issuing warning signals, a test section 11 and a state detector section IH. This last-mentioned section is the entrance part to which the strip of liquid-absorbent material is connected, for example that in FIG. 2 , on which the conductors 6 and 7 are provided, which form a current loop through the resistor 8, which is hereinafter referred to as the terminal resistor. Each loop 6, 7, 8 is assigned such a state:! Detector section 111 . Only a single state detector section HI is shown in the drawing, and in practice the components provided as components of this reticle are expediently formed on plug-in Sirom circuit cards. The Statusde detector section Hl is constructed as an amplifier and in the input resistors Ri and Rl are provided, the resistor R \ is connected to the conductor 6 in the Strei fen 5, while the conductor 7 is grounded or connected to a terminal. The connection point between the resistors R \ and Rl is connected to the base of a transistor 7Ί, which together with a transistor 72 via an intermediate resistor /? 3 forms a Schmitt trigger circuit. A resistor R5 is placed in the Schmitt trigger circuit for feedback. This feedback circuit in turn actuates a transistor 73 via a resistor RA. To change the trigger level of the Schmitl-Ti trigger, a resistor R6 is connected to the connection point between the base of the transistor 71 and the resistor /? 5. The free end of the resistor / 6 is connected to the relevant free ends of equivalent resistors in the other units serving to determine an alarm condition, which correspond to the illustrated condition detector section III. The mentioned free end of the resistor R6 is also connected to the collector of a transistor 712 in the Prüfabschniti II, which will be described below. The collector of the transistor 73 is connected via a diode D \ to an alarm line and to a light-emitting diode Di.

As will be explained below, the signal section I is continuously supplied with current via the diode Di when an alarm condition is detected. It was mentioned that the collector of the transistor 73 is connected to a light emitting diode iOJ. which in turn is connected to an RC network arrangement Ct, R &, R $ . which can be actuated to transmit a pulse via a diode Dl into the signal section I when an alarm condition is detected. The light-emitting diode DJ is fed via a resistor R1 and is also connected to a diode D4, the free end of which is connected to the relevant diodes in circuits which correspond to the circuit IH. The diode D4 is also connected to a resistor R \ 7 in the test section II,

which will still have to be dealt with.

The diode D1 is connected to the relevant diodes in the remaining additional detector sections III and, via a resistor RiQ, to the signal section I and to the base of a transistor 74. This transistor is connected via its collector to a thyristor 75 and to a multivibrator coupling consisting of two transistors 76 and 77 and the RC network arrangement K12-15 and C1, C4. The emitter of transistor 76 is connected via a diode DlI to the base of a transistor 78 whose collector is connected to an alarm bell K , while the emitter of transistor 77 is connected to the base of a transistor 79 whose collector is connected to a warning lamp Ll . The free end of the warning lamp Ll and the free end of the alarm bell K are connected to one another and to a rectifier circuit DC which is used for power supply and which is fed from a transformer Tr. The power supply circuit also feeds a signal lamp L2, which in turn is connected to the collector of a transistor 711 in the test circuit II.

The base of the transistor 7Ί1 is connected to a thyristor 710 and to a power supply circuit including the resistor /? 19. The thyristor 710 is also connected to a circuit including a power supply resistor RI3 for a transistor 712 through a capacitor CB. The base of transistor 712 is supplied from a trigger circuit, the transistors 713 and 714 einbegreift with the associated resistors R22 and RIi and one at the base of transistor 713 down capacitor Cl. The latter circuits are inter alia connected to a power supply circuit which includes diodes DJ and DS, which are of opposite polarity to the connecting terminals of resistors Λ19 and R2O , where Ri and Rl and 71 and 73 in the state detector section III with the two ends of the secondary winding of the transformer TfI are connected. A diode Dd is connected to the diode LTB, which in turn is connected to a circuit including the light-emitting diode DiO and to the resistor R18 and the capacitor C5. A resistor /? 17 is connected via a Zener diode Da to the circuit of the thyristor 710, which in turn is connected to the already mentioned diode DA in the state detector section U1 serving to determine the alarm state.

The test of the system, which is done automatically and periodically, proceeds in the following manner. When checking the condition detector sections IH which are used to establish the alarm condition and are constructed as amplifiers, the amplification (the trigger level) of all amplifier circuits is changed via the resistors RS. This is achieved thanks to the fact that when charging the capacitor Cl via the resistor / 721. connected to double base transistor 713, a short pulse is transmitted to transistor 712. The collector in transistor 712 is therefore brought to a low voltage for a short time. As a result, the amplification of the amplifiers used to establish the alarm state increases via the resistors RS. The current then flows via the conductors 6 and 7 in the strip 5 and through the terminal resistor 8. If the relevant condition detector section III comes into operation, a voltage appears on all condition detector sections III via the diode Di first. which feed the multivibrator 76, 77. At the same time, however, a current appears in all of the state detector sections III via the diode Dl. The pulse from Dl also goes via /? 10 to the transistor 74 and actuates the transistor which holds down the collector of the transistor 76, which prevents the transistor 78 in passes the on state. The transistor 74 also blocks the transistor 77 via the capacitor C3 . The method described above prevents the

ίο transistors 78 and 79 go into the conductive state when the relevant amplifier circuits etc. are tested, that is, when the performance of the strip loop is tested. As a result of the process mentioned, ie the increase in the gain of the state detector sections III, a response pulse is received from the relevant diodes D4 when the terminating resistors 8 are carrying current, and the circuits are generally fault-free in this case. If one of the loops 6, 7, 8 is interrupted, the resistor RJ does not receive a strong current when an incoming test pulse is received, since one of the amplifiers bypasses the contradiction Λ? Ι7 via the diode D4. The thyristor 710 therefore does not start to work, but the capacitor CB switches off the thyristor 710, which, however, cannot be re-excited. The circuit operates in such a way that the capacitor CB transmits a pulse to the transistor 712 and switches off the thyristor 710 at the same time as a pulse serving as a test for the condition detector section III serving to establish the alarm condition is received. The consequence of this is that the current flows through the resistor Ri9 through the base of the transistor 711, whereby the lamp L2 is switched on. The sequence is as follows: the thyristor 710 is never driven by the capacitor CB when a test pulse is transmitted, and the transistor 711 does not conduct until an error signal is received from one of the amplifiers. So that the thyristor 710 becomes conductive, a control current must be obtained from the resistor Ri7.

If, for example, water is present in the strip 5, the relevant state detector section III is put into operation to determine an alarm state. This means that a current flows through the transistor 73 via the diode DI and the circuit of the signal section I is excited. The multivibrator circuit 76, 77 then begins to work because it is blocked, so that with every second pulse of the multivibrator circuit the bell K or the lamp Ll in

so be put into operation. The alarm can be switched off by means of a button TK , which closes the control circuit of the thyristor 75 against the positive side via the resistor RU. The thyristor 75 then becomes conductive and holds the multivibrator circuit 76, 77 in a locked state, so that a low voltage appears at the collector of the transistor 76 and the transistor 78 becomes non-conductive, whereby the bell K is switched off. In contrast, the transistor 77 is conductive, and the lamp lights up continuously as a result of the current supply via the transistor 79.

If another alarm is given during an alarm condition, another one goes to Determination of the alarm state serving amplifier circuits III via the capacitor Cl and the diode D2 in the respective amplifiers a pulse. which causes the thyristor 75 to be out of order is set, whereupon the multivibrator circuit

75, 77 starts working again. Done in this way thus a signal that another alarm condition has occurred.

If an alarm condition occurs, a constant voltage is fed to the multivibrator 76, 77 and also to the resistor KX1 via the diode D1. The base of transistor 714 is thus excited, thereby preventing capacitor CJ from charging. In this way it is achieved that the circuit which tests the circuits used to establish the alarm state is put out of operation as long as an alarm state exists. If there is an alarm condition, the amplifiers used to determine the alarm condition are not checked, since in this case the amplification brought about by the amplifiers concerned affects the proper functioning of the other amplifiers.

If there is an alarm condition, the capacitor will too Charge C4 through the resistor /? 16 using the voltage supplied to the multivibrator circuit. If this occurs, the thyristor 7Ί0 is constantly supplied with a control current, which then forms the basis of the transistor 711 shunted and the lamp Λ2 turns off. This latter process means that an alarm always has priority and interrupts an alarm signal.

A practical exemplary embodiment will now be described on the basis of a system provided with a battery pack unit (not shown). The operation of the system is normally such that a short test pulse is transmitted in ten second intervals. During this line, all connected amplifiers of the state detector section III work. which are put into operation thanks to the fact that a terminal resistor 8 is provided at the end of each loop 6. 7, 8. Should one of the amplifiers not work, this indicates that cine of the loops 6. 7. 8 is interrupted or that a fault has occurred in the amplifier or that the light-emitting diode O3 is faulty. A pulse is transmitted which turns on the error signal lamp 12. At the time of the transmission of the test pulse, all light emitting diodes are switched on for a short time interval, which enables a supervisor to observe whether one of the diodes has not lit up and whether the error lamp is switched on. The disturbance can also be the result of a drop in the mains power supply, which would be evident from the fact that the light-emitting diode D10 is not switched on. The diode D10 should therefore normally light up continuously (the system being battery-operated in this last-mentioned case). So-called priority states are also provided for the system. If a strip 5 is soaked or flooded, the alarm signal takes precedence over the error signal, and the Fchlersignallampe L2 is de-energized, whereupon the testing processes in all amplifiers stop, while the warning lamp Lt lights up and is operated alternately with the bell K. Simultaneously with this, a signal is sent to a relay (not shown). which is excited during the duration of the alarm signaling. Is the system ready for operation again? so the warning lamp IA sends out a steady light. and the bell K stops ringing. If at the same time an alarm condition occurs again in one of the other amplifiers, the lamp starts to flash again and the system must be made operational again. To check the operating country of the system, it is determined by visual inspection whether the light-emitting diodes Di in the relevant amplifiers light up with a steady light, while all the other diodes are switched off. As soon as the loops 5 have dried, the system automatically resumes the monitoring function. the blocking of the test section is ended and the checking of the operation of the loops is resumed.

In the course of another, not yet mentioned Operating process in the system according to the invention can be seen a special function of each operate the state selector section, namely a signal immediately after the transistor 73 can be removed, whereby a relay actuation for .Control of an emergency pump or similar device can be triggered directly. The relay can also be constructed so that a signal voltage is released to ignite pyrotechnically charged valves, as they are commercially available today are what is then intended. To block water pipes etc. These funds can also be used to: to release a mechanically locked shut-off valve, in order to also block water pipes and the like / u. Simultaneously with these measures, the .Signalabschnitt I be given an alarm signal.

If the system is to be used, for example, as a fire alarm or as a burglar alarm, the Conductor 7 can be applied to a positive voltage, whereby the base of the transistor 7Ί through a resistor constantly with a negative or equivalent connection connected is. Is one of the 6 or 7 mil a breaker contact arrangement connected in series, so the transistor 71 goes into the conductive state when the circuit is interrupted, there the blocking voltage from the conductor 7 disappears and the base is connected to a negative terminal. whereupon the alarm is triggered.

To enable a fire alarm to be triggered, a solution would be conceivable that the actual strip 3 mils of a substance treated in! "all an increase in the ambient temperature the capability of the material between the Let the ladders rise so far that the alarm is triggered comes.

The work performance of a Emergency pump or a pyrotechnically charged shut-off valve to one of the inputs of the trigger amplifier be placed so that in the course of the test function of the system, a test can be made as to whether the work performance the facility are functional.

Are response means different with the inputs of the trigger amplifiers of the state detector sections Kind of connected, so it may be appropriate to increase the gain at the test interval depending on the characteristics to control the different elements at different levels. In this case, the gain control can be brought in stages to different Stcucrpcgcl, whereby the stage of triggering of the Alarms or changes in the impedance of the various interconnected elements are detected and can be displayed.

For this purpose 2 sheets of drawings 509 513/357

Claims (9)

Patent claims: 1. Warning signal system with a response means in the form of electrical conductors, between which by the An electrical parameter is changed from the normal state to the alarm state, and «Has a state detector section with a threshold detector and a signal section, this state detector section being connected to the electrical conductors and the output signal of the threshold detector the size of the electrical parameter above or below of the threshold value of the threshold detector and the signal portion in response to it Output or non-output of a warning signal controls, characterized in that the Warning signal system further comprises a test section (H), the periodically the threshold value of the Threshold detector to one value or gradually to several successive values below the size of the electrical parameter in the normal state. 2. Warning signal system according to claim 1, characterized in that one of the threshold value of the Threshold detector periodically reducing control circuit in the test section (II) the signal section when emitting the threshold value of the threshold detector down-controlling pulses with respect to blocked from emitting the warning signal. 3. Warning signal system according to claim 2, characterized in that the control circuit in the test section (II) when releasing the down the threshold value of the threshold detector; your impulses at the same time in the middle of the display! , 'OS, ¹ turns on. 4. Warning signal system according to one of claims 1 to 3, characterized in that the changeable electrical parameter between the conductors (6, 7) is an impedance. 5. Warning signal system according to claim 4, characterized in that the impedance through the contact resistance is formed between the electrical conductors (6, 7) in a carrier material (5). 6. Warning signal system according to claim 5, characterized in that the electrical conductors (6, 7) at the end by a connection / (8) with each other are connected. 7. Warning signal system according to claim 5 or 6, characterized in that the carrier material (5) is a textile material or the like which is impregnated with substances which are sensitive to liquid vapors and can be activated by this to change the resistance between the electrical conductors (6, 7) are. 8. Warning signal system according to claim 4 or 5, characterized in that the material (5) with substances is impregnated, which is sensitive to heat and this leads to a change in resistance can be activated between the electrical conductors (6, 7). 9. Warning signal system according to one of claims 1 to 3, characterized in that the changeable electrical parameters is given by a switching function between the electrical conductors (6, 7). The invention relates to a warning signal system for warning of an alarm condition, with a Response means in the form of electrical conductors, between which through the transition from the normal state to the Alarm condition an electrical parameter is changed and with a condition detector section and a signal section comprising warning signaling device, the state detector section with the electrical Ladders and a threshold detector , o tor includes whose output signal the size of the electrical Parameter above or below the threshold value of the threshold selector and controls the signal section in response to outputting or not outputting a warning signal. "Today there is an ever increasing decline ^J ask for efficient and reliable warning or alarm systems, which applies in particular to water alarm systems. If, for example, water seeps into an enclosed space, it happens ■ .o very much on it. that this as rasd as possible. noticed even before the room is submerged. Sometimes it is necessary that such an alarm is triggered when the humidity in the room increases. So far it has been difficult to meet this requirement to wear, since most water alarm systems are based on the fact that a switch with the help of a Float or similar devices is closed. If a liquid, for example water, nus pipelines runs out and only then notices this If the floor in the enclosed space is covered with water, it can already be quite considerable Damage occurred. It is therefore desirable. that an alarm is triggered as soon as the liquid begins to emerge or the floor area under the Warning device wetted. This then creates the possibility to take appropriate countermeasures at an early stage. According to the prior art, warning signal devices are known which contain a fiber: offer: '. Certificate th. Are arranged on the electrical conductor with an electrical warning device are connected. The mode of action of these alarm systems is based on the fact that the electrical contact resistance is reduced in the event of the effect of moisture, which triggers the alarm has the consequence. However, there are difficulties here, since the functionality of the lie which may be within a very small range of variation of the electrical parameter, for example of the resistance, must switch. not can be continuously checked at the same time. In the case of lies that have not had an alarm status to report for years, can ultimately lead to wire breaks or changes in characteristics due to corrosion or other damage result that make a response in the event of damage appear doubtful. In contrast, the invention is based on the object to create a warning signal system that is safe through ongoing monitoring. This task will. based on a warning system of the entrance mentioned type, achieved in that the warning signal system further comprises a test section which periodically the threshold value of the threshold detector to one value or in steps to several successive ones Values below the size of the electrical Para - (> 5 meters in normal state reduced. Due to the reduction of the threshold value at intervals of IO seconds is periodically, in each case for a short pulse duration, a case of damage is simulated and preferably