DE2318803A1 - WARNING SYSTEM - Google Patents

Description

IMHJISREGULATOR I LYCKSEUS AKTIEBOLAG Lycksele, Sweden

The invention relates to a warning system.

Today there is an ever increasing demand for powerful and reliable warning or Alarm systems, which applies in particular to the so-called water alarm systems. Palis "for example within a completed When the water in the room seeps out, it is very important that this is noticed as quickly as possible, i.e. before the room as such is placed under water. Sometimes it is necessary for such an alarm to be triggered when the Humidity increases in an enclosed space. So far it has been difficult to meet this requirement since Most water alarm systems rely on a switch is closed with the help of a float or similar device. If a liquid, for example So water leaking from pipes and this

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only then "is noticed," when the ground is in the closed Space covered with water can already be quite a considerable one Damage occurred. It is therefore desirable that an alarm be given as soon as the liquid leaks begins or the floor area under the warning device wets. This then creates the possibility at an early stage to take appropriate countermeasures.

Warning signal devices are state-of-the-art known that contain a fibrous product on the electrical conductor are arranged, which are connected to an electrical warning device. How this works Alarm systems are based on the fact that the electrical contact resistance is considerably reduced when exposed to moisture, which results in the alarm being triggered. The inventive Warning or alarm system is based on the same principle, but communicates with the known systems This is an advantage in that it enables effective monitoring of the operating status of both those that respond to moisture and the device embodied in the warning system as well as the operating circumstances of this device will.

The invention provides a warning system with a moisture-sensitive arrangement in the form of electrical Created conductors between which an impedance is provided, the value of which depends entirely or in part on the one to be determined State depends, the electrical conductors are connected to an electrical warning signal device, the one includes a part responsive to the existence of an alarm state and a part which can be actuated for alarm signaling, wherein the first-mentioned part is constructed as a trigger amplifier, the input of which forms a circuit with the electrical conductor forms. For the warning system according to the invention are before Characteristic of all means which, in cooperation with the impedance present between the conductors, at intervals die Amplification of the trigger amplifier on trigger actuation

level

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control level, the trigger amplifier having such a gain in the periods between these intervals that it in interaction with the impedance in an alert state s at levels below the trigger actuation level is brought.

In order to explain the invention and to clarify further features, a warning system with an inventive Structure will be described with reference to the accompanying drawings. Show in it:

Fig. 1 is a diagrammatic representation of a warning system according to the invention, which is constructed so that it responds, if moisture accumulates in an enclosed space and if this space is flooded;

Pig. 2 is a partial view of the actual in which Pig warning system. I gate-sighted moisture-sensitive Contraption; and

Pig. 3 is a circuit diagram of the warning system shown, including the necessary electronic amplifier components.

The one in Pig. 1 shown warning system is installed in a room 1, in which a warning signal device on one wall 2 is arranged. In extension of this device 2, a moisture-sensitive, strip-like arrangement 3 is provided, which leads to the sod 4 of the room is. In practice, the moisture-sensitive arrangement can be hidden under a carpet when installed that extends from wall to wall, or under similar floor coverings, or it can be close to the ceiling or be laid on this itself, or in other places where moisture can escape.

In Pig. 2 belongs to the embodiment shown to the moisture-sensitive arrangement 3 a strip 5 of a textile material in which two electrical conductors 6 and 7 are woven in, which are constantly flowing and with the

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Warning signal device 2 are connected. The conductors β and 7 are at the end of the strip 3 through a current loop forming resistor 8 connected to each other, which will come back in the description of the operation of the warning signal device will be. 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 is between the conductors 6 and 7 due to the electrical bridging effect of the strip increased. This leads to a change in the current ratios in the individual circuits of the Warning signal device 2, which has the triggering of the alarm as a result, 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 coated with substances such as Salts to be impregnated, which are suitable between the conductors 6 and 7 such a conductivity behavior of the Material to cause solion to set off an alarm if there is a slight increase in humidity in the room.

The actual moisture-sensitive arrangement 3 can also be designed, for example, in the form of a paper strip be, on which the conductors 6 and 7 are applied as lines of a conductive paint. The moisture sensitive The arrangement can also be composed of several layers, alternating in each case conductive layers and insulating layers are provided.

As can be seen from Fig. 3, the warning signal device 2 constructed from three sections, each including electronic components, namely from one section I for warning signals, a test section II and a section III to determine the alarm status. This latter section is the entry part that the strip connects to of the liquid-absorbent material is connected, for example that shown in Fig. 2, on which the conductor β and 7 are provided which have a current loop through the

resistance

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Form resistor 8, which is referred to below as the terminal resistor may be. An electronic section III is assigned to each loop 5. In the drawing there is only an electronic one Section III, and in practice are the components envisaged as part of this section expediently formed on plug-in ora circle cards. The electronic section III is designed as an amplifier and resistors Rl and R2 are provided in the input, wherein the resistor Rl is connected to the conductor 6 in the strip 5, while the conductor 7 is grounded or to a Connection is laid. The connection point between the resistors Rl and R2 is connected to the base of a transistor Sl, which together with a transistor T2 via an interposed resistor R3 forms a Schmitt trigger circuit. A resistor R5 is placed in the Schmitt trigger circuit for feedback. This feedback circuit operates in turn a transistor T3 via a resistor R4. There is a resistor to change the trigger level of the Schmitt trigger R6 placed at the connection point between the base of the transistor Tl and the resistor R5. The free end of the Resistor R6 is equivalent to the relevant free ends of resistances in the remaining, to determine one Alarm condition serving units connected to the shown Unit III correspond. The mentioned free end of the resistor R6 is also connected to the collector of a transistor T12 connected in the test circuit II, which will be described below. The collector of the transistor T3 is connected to an alarm line and to a light-emitting diode D3 via a diode D1. As explained below, the alarm circuit I is continuously supplied with power via the diode Dl when an alarm condition is detected. It was mentioned that the collector of the transistor T3 is connected to a light-emitting diode D3, which in turn is connected to an RG-I network arrangement Cl, R8, R9 is connected, which is used to transmit a pulse via a diode D2 in the alarm circuit I. can be operated when an alarm condition is detected. the

light emitting diode

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LED D3 is fed through a resistor R7- and is also connected to a diode D4, the free end of which is connected to the respective diodes in circuits which the Circuit III correspond. The diode D4 is also connected to a resistor R17 in the test circuit II, whereupon will have to be received.

The diode D2 is connected to the relevant diodes in the remaining circuits III and via a resistor RIO the irarnsignalabschnitt I and connected to the base of a transistor T4. This transistor is using its collector a thyristor T5 and with one consisting of two transistors T6 and T7 and the RC-Netζordnung R12-15 and C2, G4 Multivibrator coupling connected. The emitter of the transistor T6 is connected to the base of a transistor T8 via a diode DIl connected, the collector of which is connected to an alarm bell K, while the emitter of the transistor T7 to the base of a Transistor T9 is placed, the collector of which 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 DC rectifier circuit DG that is used for power supply connected, which is fed from a transformer Tr. the Power supply circuit also feeds a signal lamp L2, which in turn with the collector of a transistor TIl in the Test circuit II is connected.

The base of the transistor TIl is with a thyristor TlO and with a including the resistor R19 Power supply circuit connected. The thyristor TlO is also connected through a capacitor G6 to a circuit containing a power supply resistor R20 for a transistor T12 includes. The base of the transistor T12 is fed from a trigger circuit, the transistors T13 and 114 with it the associated resistors R21 and R22 and a capacitor G7 connected to the base of the transistor T13. The latter circuits are inter alia connected to a power supply circuit which includes diodes D7 and D8, those of opposite polarity to the connecting terminals

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of the resistors R19 and R2O, where Rl and R2 as well as Tl and T3 in section III with the two ends of the secondary winding of the transformer Tr2 -are connected. Hit the diode D8 is connected to a diode D9, the vd.ederum with a die Light-emitting diode DlO including circuit and is connected to the resistor R18 and the capacitor 05. A resistance RI7 is connected to the circuit of the Thyristor TlO connected, in turn with the already mentioned Diode D4 is connected in circuit III used to establish the alarm condition.

The system check, which is carried out automatically and periodically, is carried out in the following manner. In the case of the examinee who set the alarm state it Serving amplifier circuits III, the gain (the trigger level) of all amplifier circuits via the resistors R6 changed. This is achieved thanks to the fact that when charging the capacitor 07 via the resistor R21, cHr is connected to the double base transistor TI3, a short one Pulse is transmitted to transistor T12. The collector in the transistor ΤΊ2 is therefore briefly on a low Brought tension. Iniolgsaessen increases over the resistance R6 the gain of the to determine the alarm supply. Stand serving amplifier. The current then flows over the Conductors 6 and 7 in the strip 5 and through the terminating resistor 8, Ko: -imt the relevant amplifier circuit III in operation, so first of all a voltage appears across the diode Dl on all detector sections III, which the multivibrator T6, T7 Food. At the same time, however, a current appears in all of the amplifiers III used to determine the aleirm state via the diode D2. The pulse from D2 also goes to transistor T4 via RIO and activates the transistor, which holds down the collector of transistor T6, which prevents that the transistor T8 goes into the on state. Of the Transistor T 4 also blocks the transistor via capacitor 03 T7. The method described above prevents the transistors T8 and T9 from going into the conductive state

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go when the "concerned amplifier circuits, etc. checked i.e. when the operational behavior of the strip loop is tested. As a result of the mentioned sequence, i. the increase in the gain of amplifier III is provided by the relevant diodes D4, which are provided at the terminal resistors 8 are received, a response pulse, and the circuits are generally error-free in this Pail.

If one of the loops 5 is interrupted, the resistor R7 'does not receive any when a test pulse is received strong current because one of the amplifiers shunts resistor R17 through diode D4. The thyristor TlO begins therefore not to work, but the capacitor C6 switches the Thyristor TlO, which, however, cannot be re-energized / grounded. The circuit works in such a way that the capacitor G6 at the same time as receiving one that acts as a test for Amplifier III, which is used to determine the state of the arm Pulse to the transistor T12 transmits a pulse and turns off the thyristor TlO. The consequence of this is that the current flows through the resistor R19 through the base of the transistor TIl, whereby the lamp L2 is switched on will. The process is as follows: The thyristor T10 is never triggered by the capacitor C6 when a test pulse is transmitted and transistor TIl does not conduct until an error signal is received from one of the amplifiers. In order to the thyristor T10 becomes conductive, a control current must be obtained from the resistor R17.

If, for example, water is present in a loop 5, the amplifier circuit in question becomes III Detection of an alarm condition in operation. This means that a current through the transistor T3 via the Diode Dl flows and the circuit of the warning signal section I is energized. The multivibrator circuit T6, T7 then begins work because it is not blocked, so that with every second pulse of the multivibrator circuit the bell K and the Lamp Ll can be put into operation. The alarm can be switched off by means of a button TK, which controls the control

circle

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circle of the thyristor T5 over the understand RIl against the positive side closes. The thyristor Ϊ5 then becomes conductive and holds the multi-vibrator circuit 16, 17 in a locking state, so that a low voltage appears at the collector of transistor Tb and transistor T8 is non-conductive is, whereby the bell K is switched off. In contrast, the transistor T7 is conductive and the lamp lights up as a result the power supply via the transistor T9 constantly.

If a further alarm is given during an alarm condition, another alarm is used to establish it the alarm condition serving amplifier circuits III via the capacitor 01 and the diode D2 in the amplifier concerned a pulse which causes the thyristor T5 to be set to LJe-crieb, whereupon the multi-vibrator circuit 26, T7 vaeder to work "begins. In this"., Iron takes place thus a signal that another alarm condition has occurred.

If an alarm condition occurs, the i-iultivibrator T6, T7 and also the resistor R22 via the diode Dl constant voltage supplied. The base of transistor T14 is thus excited, thereby charging the capacitor 07 is prevented. In this way it is achieved that the Circuit that checks the circuits used to determine the alarm state, except. Operation is set for as long an alarm condition exists. If there is an alarm state, there is no check to determine the alarm state serving amplifier, as in this case the by the concerned Amplifier caused amplification affects the proper functioning of the other amplifiers.

If there is an alarm condition, the capacitor 04 is also replaced by the multivibrator via the resistor R16 The voltage supplied is charged. Occurs this If so, a control current is constantly fed to the thyristor T10, which then joins the base of the transistor TI1 and the lamp L2 switches off. The latter

occurrence

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Process "means that an alarm always has priority and a Error signal interrupts.

It is now intended to be a practical system based on a system provided with a hot battery unit (not shown) Embodiment described v / earth. The operation of the system is usually such that in ten second intervals a short test pulse is transmitted. During this time, everyone who is switched on works for the plague the alarm condition serving amplifier III, this amplifier thanks to the fact that at the end of each loop 5 a terminal resistor 8 is provided is. Should one of the amplifiers not work, this indicates that one of the loops 5 is interrupted or that a fault has occurred in the amplifier or that the light-emitting diode D3 is faulty. So an impulse is transmitted which turns on the error signal lamp L2. At the time the transmission of the test pulse v / ground all light emitting diodes switched on for a short time interval - what a supervisor the observation enables whether one of the diodes did not light up and whether the fault lamp is switched on. The disorder can also be the result of a drop in the power supply, which would be seen in the fact that the light-emitting diode DlO is not switched on. The diode DlO should therefore normally light up continuously (with the system in this the latter case is battery operated). So-called priority states are also provided for the system. If a loop 5 is soaked or submerged, the alarm signal takes precedence over the error signal and the error signal lamp L2 is de-energized, whereupon the test processes in all amplifiers stop, while at the same time the "warning lamp Ll" lights up and is operated alternately with the bell K. Simultaneously with this, a signal goes to a relay (not shown) to which is excited during the duration of the alarm signaling. When the system is ready for operation again, the Flashing lamp Ll a steady light and the bell K stops ringing. Should at the same time in one of the other

stronger

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If an alarm condition occurs again, the lamp starts to flash again and the system must be made operational again. To check the operating condition of the system it is determined by visual inspection whether the light-emitting diodes D3 in the relevant amplifiers light up with a steady light, while all other diodes are switched off. As soon as the loops 5 have dried, the system resumes automatically the monitoring function is activated, the blocking of the test section is ended and the operating status is checked the loop is resumed.

In the course of a further, not yet mentioned operating process in the system according to the invention, one can use a special sanction for each of the amplifier blocks used to establish the alarm state, in this respect, namely a signal immediately behind the transistor T3 removed v / earth, whereby a relay actuation to control a hot pump or similar device on direct can be triggered. The relay can also be constructed in such a way that a signal voltage for ignition is pyrotechnic loaded valves is released, as they are commercially available today, which is then used to block Vasserleitnngen etc. This i-Iittel can also be used to mechanically Release the locked shut-off valve in order to also block v / ace lines and the like. Simultaneously with these An alarm signal can be given via the warning signal section I.

If the system is to be used, for example, as a fire alarm or as a burglar alarm, the conductor 7 can be connected to a positive voltage, v / whether the base of the transistor Tl is placed via a resistor which is constantly connected to a negative or corresponding terminal. Is one of the conductors connected with a contact breaker assembly in series 6 or 7, the transistor Tl goes over to the conducting state when the circuit is interrupted, since the blocking voltage of the conductor 7 ver sch w indet

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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 to the effect that the actual Strip 3 is treated with a substance that is present in the pail an increase in the ambient temperature, the conductivity of the material .between the conductors increases to such an extent that it the alarm is triggered.

Also within the scope of the system according to the invention For example, the working lines of an emergency pump or a pyrotechnically charged shut-off valve to one of the inputs the trigger amplifier are placed so that in the course of the test function A check can be carried out in the system as to whether the working lines of the facility are functional.

If various types of response devices are connected to the inputs of the trigger amplifiers, it can be useful to the gain at the test interval increases to different levels depending on the characteristics of the different elements steer. In this case, the gain control can be brought to different control levels in stages, with also the level of triggering of the alarm or changes in the impedance of the various interconnected elements can be determined and displayed.

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Claims (7)

- 13 - P _._ a ΐ_ j3_ n__t_ ans ρ r ü che Warning system with a response in the form of electrical conductors, between which an impedance is provided, the v.'ert of which depends entirely or partially on the state to be determined, the electrical conductors being connected to an electrical warning signal device, to which one is used to set an alarm state serving section and a section serving for signaling belong, and the first-mentioned section is constructed as a trigger amplifier, the input of which forms a circuit with the electrical conductor, characterized by means (II) for regulating the gain of the trigger amplifier (III) at intervals Triggering actuation level in interaction with the impedance between the conductors (6, 7), the trigger amplifier (III) in the periods between these intervals providing a suitable amplification in cooperation with the impedance to produce a state of alert at levels below the triggering actuation level Has. 2. Warning system according to claim 1, characterized in that the means (II) for regulating the gain of the trigger amplifier (III) include a periodically operating control circuit that also interacts with the warning signal serving section (I) in the sense of an inactivation in the intervals of higher amplification than the trigger amplifier (III) can be actuated, the control circuit for the control amplifier being switched on during these intervals can be actuated by display means for displaying the trigger actuation. 3. Warning system according to one of claims 1 or 2, characterized in that that the impedance between the electrical conductors (6, 7) of the response means (5-7) cLen electrical Includes transitional resistance of a load-bearing material (5), which together with the electrical conductors (6, 7) forms the response means (5-7). 309642/1126 -U- 4. Warning system according to claim 3, characterized in that the Impedance between the electrical conductors and the. Response means (5-7) includes the contact resistance together with a bridging impedance (8), which is preferably between the outer ends of the electrical conductors (6, 7) is laid. 5. Warning system according to one of the preceding claims, characterized characterized in that the material (5) in a known manner includes a textile material or the like, v / obei this material (5) is impregnated with substances that are sensitive to the state of evaporation of liquids and can be activated by this, the impregnation substances for producing a change in the contact resistance between the electrical conductors (6, 7) are suitable. 6. Yiarnanlage according to one of claims 1 to 4? characterized, that the material (5) is impregnated with substances which are sensitive to heat and can be activated by this are, the impregnation substances when activated for Bringing a change in the contact resistance between the electrical conductors (6, 7) are suitable. 7. Warning system according to one of the preceding claims, characterized characterized in that the control circuit for stepwise control of the gain level between the levels during the intervals of a high gain of the trigger circuit in question can be actuated. 309842/1126 ■ ff Blank page