DE2318803C3 - Warning signal system - Google Patents

Description

The signal section is blocked at the moment so that the Silerung indicates that it is operational. Without triggering a warning signal at the same time - (L By gradually changing the threshold value during the periodic test times, freedom of possible errors such as the location of the error, the degree of resistance deviation or the like can be determined.

The may change as the condition to be checked, _e J parameter may be an impedance, a b * üspielseise of the moisture or the temperature-dependent resistor *, however, a kapaziti or inductive impedance or the resistance of a pressure sensitive element. However, it can also be a switching function, for example an interrupter contact arrangement or active circuits.

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

ρ i g 1 a diagrammatic representation of an inventive Warning system that is constructed in such a way that tie responds when in an enclosed space Moisture accumulates and if this space is submerged,

Fig.2 is a partial view of the actual, in which Warning system of Fig. 1 provided moisture-sensitive Device and

F i g. 3 is a circuit diagram of the warning system shown including the necessary electronic amplifier components.

The warning system shown in Fig. 1 is in one Room 1 installed, in which a warning signal device 2 is arranged on one wall. In extension of this device 2, a moisture-sensitive, strip-like arrangement 3 is provided which is attached to the floor 4 of the room is performed. In practice, the moisture-sensitive arrangement in the installed state be hidden under a wall-to-wall carpeting or similar Floor coverings, or they can be laid close to the ceiling or on this itself, or in other places where moisture can escape.

In the case of the in FIG. 2, the moisture-sensitive arrangement 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 which forms 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 this 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 getting wet of the strip 5, the strip can be impregnated with substances, such as salts, which are suitable are, between the conductors 6 and 7 such conductivity behavior of the material that even with a slight increase in moisture in an alarm is triggered in the room.

The actual moisture-sensitive north artery

S nung 3 can, for example, also be in the form of a piece of paper: -

be formed strip on which the conductors 6 and 7 as

Lines of a conductive paint applied

are. The moisture-sensitive arrangement can furthermore also be 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, each including electronic components, namely a signal section I for issuing warning signals, a test section U and a state detector section 111. This last-mentioned section is the input part to which the strip of liquid-absorbent material is connected is, for example the one 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. such a state detector section III is assigned to each loop 6, 7, 8. Only a single condition detector section 111 is shown in the drawing, and in practice the components provided as constituent parts of this section are expediently formed on plug-in circuit cards. The state detector section III is constructed as an amplifier and resistors RX and Rl are provided in the input, the resistor Rl being connected to the conductor 6 in the strip 5, while the conductor 7 is grounded or connected to a terminal. The connection point between the resistors RX and R2 is connected to the base of a transistor 71 which, together with a transistor 72, forms a Schmitt trigger circuit via an intermediate resistor /? 3. A resistor RS is placed in the Schmitt trigger circuit for feedback. This feedback circuit in turn actuates a transistor 73 via a resistor / 4. To change the trigger level of the Schmitt trigger, a resistor Rb is connected to the connection point between the base of the transistor 71 and the resistor R5. The free end of the resistor Λ6 is connected to the relevant free ends of equivalent resistors in the other units serving for the detection of 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 test section II, which will be described in the following. The collector of the transistor 73 is connected via a diode DX to an alarm line and to a light emitting diode D3 . As will be explained below, the signal section I is continuously supplied with current via the diode D1 when an alarm state is determined. It was mentioned that the collector of the transistor 73 is connected to a light-emitting diode Di , which in turn is connected to an RC network arrangement CX, RA, 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 D3 is fed via a resistor R1 and is also connected to a diode 65 DA , the free end of which is connected to the relevant diodes in circuits which correspond to the circuit 111. The diode D4 is also connected to a resistor RX7 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 state detector sections III and, via a resistor /? 10, 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 /? 12-15 and C2, CA. The emitter of transistor 76 is connected via a diode DIl 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 IA . The free end of the warning lamp L \ 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 12, which in turn is connected to the collector of a transistor 711 in the test circuit II.

The base of the transistor 711 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 /? 20 for a transistor 712 through a capacitor CB. The base of the transistor 712 is fed from a trigger circuit, the transistors 713 and 714 with the associated resistors RIi and RT). and includes a capacitor CJ connected to the base of transistor 713. The latter circuits are connected, inter alia, to a power supply circuit which includes diodes DJ and DS which are of opposite polarity to the connecting terminals of the resistors /? 19 and RIO , where Ri and Rl and 71 and 73 in the state detector section HI with the two ends of the secondary winding of transformer 772 are connected. A diode D9 is connected to the diode DS , which in turn is connected to a circuit including the light-emitting diode ZT10 and to the resistor RiS and the capacitor C5. A resistor /? 17 is connected via a Zener diode DB to the circuit of the thyristor 710, which in turn is connected to the aforementioned diode D4 in the state detector section III serving to determine the alarm state.

The test of the system, which is done automatically and periodically, proceeds in the following manner. When the state detector sections III, which are used to determine the alarm state and are designed as amplifiers, are checked, the amplification (the trigger level) of all amplifier circuits is changed via the resistors RS. This is achieved thanks to the fact that when the capacitor CJ is charged, a short pulse is transmitted to the transistor 712 via the resistor A21 which is connected to the double base transistor 713. The collector in the transistor 712 is therefore brought briefly to a low voltage. As a result, the amplification of the amplifier 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 state detector section III comes into operation, a voltage appears via the diode D1 on all state detector sections III that feed the multivibrator 7B, 77. At the same time, however, a current appears across the diode D2 in all of the state detector sections IH. The pulse from D2 also goes to transistor 74 via RW and actuates the transistor which holds the collector of transistor 76 down, preventing transistor 78 from going on. 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 testing the amplifier circuits, etc. concerned, d. i.e. when the performance the strip loop is tested as a result of the procedure mentioned, i. H. increasing the gain of State detector sections III, is from the relevant diodes D4, if the end resistors 8 conduct current, receive a response pulse, and the circuits are generally error-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 occurs, since one of the amplifiers shunt the resistor R \ 7 via the diode D4 Capacitor CB turns off thyristor 71C, 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 the thyristor 710 switches off at the same time as a pulse ar serving as a test for the state detector section III serving to establish the alarm state is received. The consequence of this is that the current flows through the resistor φ19 through the base of the transistor 711, whereby the lamp 12 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. In order for the thyristor 710 to become conductive, a control current must be obtained from the resistor RYJ.

If, for example, water is present in the strip 5, the relevant state detector section HI is put into operation to determine an alarm state. This means that a current flows through the transistor 73 via the diode Dl and the circuit of the signal section I is excited. The multivibrator circuit 76, 77 then begins to work, since it is not blocked, so that with every second pulse of the multivibrator circuit the bell K or the lamp L \ in

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 All. 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 shines)

due to the power supply via the transistor 79 constantly.

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

76, 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, Ti 'and also to the resistor R22 via the diode DI. It is thus excited the base of the transistor 714, whereby the charging of the capacitor C1 is prevented. In this way it is achieved that the circuit which tests the circuits used to determine 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 in question affects the proper functioning of the other amplifiers.

If there is an alarm condition, the capacitor C4 is also charged via the resistor /? 16 by the voltage supplied to the multivibrator circuit. If this occurs, the thyristor 710 is constantly supplied with a control current, which then shunts the base of the transistor 711 and switches off the lamp L2. This latter process means that an alarm always has priority and an error signal! interrupts.

A practical embodiment will now be described on the basis of a system provided with an emergency battery unit (not shown). The system normally works in such a way that a short test pulse is transmitted at ten-second intervals. During this time, all connected amplifiers of the state detector sections 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 stimulates. that one of the loops 6, 7. 8 is interrupted or that a disturbance has occurred in the amplifier or that the light-emitting diode Di is disturbed. A pulse is transmitted that switches on the error signal lamp L2. At the time of the transmission of the test pulse, all light 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 DiO should therefore normally light up continuously (the system in this latter case being battery-operated). So-called priority states are also provided for the system. If a strip 5 is soaked through or flooded, the alarm signal takes precedence over the error signal, and the error signal lamp L2 is de-energized, whereupon the testing processes in all amplifiers stop, while at the same time the warning lamp IA lights up and the bell K is operated alternately - At the same time a signal is sent to a relay (not shown). that is excited during the duration of the alarm signal, the system is ready for operation again. so the warning lamp IA emits 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 test the Beiriebszustandcs of the system is determined by the inspection whether or not the light-emitting diodes D3 light up in the relevant amplifiers with continuous light, while all the ^others-1 diodes are turned 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

ίο Checking the operational status of the loops 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 the state detector sections operate, namely a signal immediately after the transistor 73 can be removed, whereby a relay operation to control an emergency pump or the like Establishment can be triggered directly.

The relay can also be constructed so that a signal voltage for igniting pyrotechnically charged Valves is delivered, as they howl are commercially available, which is then used to water pipes, etc. to lock. These funds can also be used for this purpose. to release a mechanically locked shut-off valve, in order to also block water pipes and the like. Simultaneously with these measures, the signal section «. 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, with the base of transistor 71 via a resistor is constantly connected to a negative or equivalent terminal. Is one of the conductors 6 or 7 with an interrupter 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 mn is connected to a negative terminal is. whereupon the alarm is triggered.

To enable a fire alarm to be triggered, a solution would be conceivable that the actual strip 3 is treated with a substance that is treated in the event of an increase in the ambient temperature the conductivity of the material between the conductors increases so much that it triggers an alarm comes.

The work performance of a Emergency pump or a pyrotechnically charged shut-off valve to one of the inputs of the trigger amplifier ker are placed, so that in the course of the test function of the system, a test can be made whether the Ar The inputs of the trigger amplifier are functional State detector sections connected to response means of various types, so it may be appropriate. di < Gain at the test interval depending on the characteristics of the various elements on different Control level. In this case the reinforcement « Regulation can be brought in stages to different tax levels g €, whereby the stage of triggering de Alarms or changes in the impedance of the various. interconnected elements fixed *

^b S represents and can be displayed.

For this purpose 2 sheets of drawings

Claims (9)

Patent claims: 1. Warning signal system with a response means in the form of electrical conductors, between which by the Transition from the normal state to the alarm state, an electrical parameter is changed, and which comprises 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 declaration the magnitude of the electrical parameter above or below of the threshold value of the threshold detector and the signal portion in response to it Delivering or not delivering a warning signal controls, characterized in that the Warning signal system further comprises a test section (H), which 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-steering 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) at the same time switches on display means (D3) when the pulses that control the threshold value of the threshold detector are emitted 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) are connected to one another at the end by a terminating impedance (8). 7. Warning signal system according to claim 5 or 6, characterized in that the carrier material (5) a textile material or the like that is impregnated with substances 5 "which are sensitive to liquid vapor and can be activated by this to change the resistance between the electrical conductors (6, 7) are. 8. Warning signal system mch 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 I to 3, characterized in that the variable electrical parameters is given by a switching function between the electrical conductors (6, 7). 65 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 changed an electrical parameter through the transition from the normal state to the alarm state is, and with a state detector section and a signal section comprising warning signaling device, the state detector section with the electrical Conductors is connected and comprises a threshold detector, the output signal of the magnitude 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 increasing demand for powerful and reliable warning devices Alarm systems, which applies in particular to water alarm systems If, for example, within a If water seeps into the enclosed space, it is very important that this is noticed as quickly as possible, even before the room is submerged. Sometimes it is necessary that such an alarm has already been triggered becomes when the humidity in the room increases. So far it has been difficult to meet this requirement to wear, since most water alarms were on it are based, · Λ · \ β a switch with the help of a Schwi.r. : iers or similar devices closed will. If a liquid, for example water, leaks out of a pipeline and only then notices it 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 be triggered as soon as the liquid has reached its destination begins to leak or the floor area under the warning device wets this creates the possibility of to take appropriate countermeasures at an early stage. According to the prior art, warning signal devices are known which contain a fiber product, on which electrical conductors are arranged, which are connected to an electrical warning device. The way these alarm systems work is based on the fact that the electrical contact resistance when exposed to moisture is reduced, which triggers the alarm. However, this results Difficulties, as the functionality of the system, which may be within a very small The range of variation of the electrical parameter, for example the contradiction, does not have to switch can be continuously checked at the same time. For systems 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 of ensuring that a check is carried out continuously To create a warning signal system. This task is based on a warning signal system of the initially 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 gradually to several successive ones Reduces values below the size of the electrical parameter in the normal state. By belittling of the threshold value at approximately 10-second intervals is periodically, each time for a short pulse duration, a case of damage is simulated and preferably