DE956117C - Alarm or control system - Google Patents

Description

ISSUED JANUARY 10, 1957

The invention relates to a two-wire alarm or control system and more particularly to an alarm or control system Control system in which both wires form a continuous long loop, the from the central device and returns to it, with the long loop in a number in Series of connected sections or groups divided by double pole switches that are shunted are with direct current permeable impedances, d. H. with ohmic or inductive resistances.

Control and alarm circuits of the two-wire type with impedances shunted on group switches are already known. A number of bipolar thermal contacts or thermal switches are in each Group of the loop circle arranged, and both wires are opened when a thermal contact automatically by a defined temperature increase or one of the group switches manually is opened. A power source on the central device normally delivers direct current in parallel the two wires to automatically monitor the loop, and after breaking both wires of the loop circuit in the event of an alarm, the two connection terminals at each end of the loop ■ circle with the opposite terminals of a direct current source via a measuring bridge or a corresponding device for displaying the alarming group is connected. The impedances on the group switches are now parallel to the opposite one in each of the wire circles Ends of the open compartment, and the number of impedances on each side of the open switch is measured in some way, e.g. B. by a

Bridge method to the division of the loop circle indicate which is open.

The previous practice was to use capacitive impedances on the group switches, since no practical solution to the requirements of a conflicting execution is possible seemed, in which the group impedances should have high ohmic resistance, in order to be effective Avoid shorting out the two wires of a long ίο loop with a number of divisions (It is actually still desirable to have an automatic relay control for short-circuit or having poor insulation between the two wires of the loop circuit), and at the same time should have a low ohmic resistance, in part a reliable and easily measurable one Differentiation between the conditions at the various departmental steps to ensure and the relatively low insulation resistance that can occur in a long loop circuit, those in a zone of high humidity, acid fumes, or other harmful conditions (for example in ships) and is practically not allowed to influence the group display. With kapaas It is of course necessary to provide an alternating current source to the measuring circuits to stimulate. The apparatus using capacitive impedances is working satisfactorily and is now in the Use, however, may require an AC power source for the impedance measuring devices can be avoided, and other benefits can be obtained if the compartment impedances are of the resistive or inductive type.

The object of the invention is to provide alarm and / or control circuits of the two-wire shunt impedance type to create where the shunt impedances are direct current permeable, d. H. are ohmic or inductive resistances. A Another object of the invention is to provide two-wire alarm or control circuits with group impedances creating direct current permeable type that is free from the restrictions and Are disadvantages that were previously inevitable with long loop circles. In particular it is The object of the invention to create alarm or control systems of the type mentioned, in which the group impedances a resistor or a. Inductance in series with a rectifier (flow valve) and the circuit arrangement is such that the impedances during normal operation of the circuit are not conductive for direct current, but for the opposite polarity of the current are conductive in the event of a two-wire break in the loop.

These and other objects of the invention as well as the advances and advantages achieved go from the following description, which refers to the drawing, in which a part an automatic fire alarm system according to the invention is shown schematically.

The reference numerals α and b denote the two wires of a long loop which is divided into a number of groups, e.g. ten (I to X), by a number of group units or detectors SI, each of which preferably contains a normally closed double pole switch 5 " At the beginning of each group a group indicator is provided, for the sake of simplicity of description it is assumed that the left (output) part of the loop circuit begins at the positive pole of a current source 11 which is located at the central station and returns to the negative pole of this battery. A number of thermal contacts T are arranged in series in the two-wire line in each compartment, the number of thermal contacts depending on the size of the compartment and the conditions or type of rooms through which runs the compartment. The thermal contacts T are normally closed double-pole shells ter, which open automatically when the temperature exceeds a preselected value.

A relay Ra is arranged in series in the line α near the beginning (exit) of the loop circuit, and a relay Rb is arranged correspondingly in series in the line b at the end of the loop circuit. These relays are closed manually or through an electrical circuit to operate the system. The relays have holding contacts i2 _a and I2 ₆ , which keep them energized as long as there is no interruption in the lines α or b and there is no short circuit between the wires. The relays Ra and Rb each have a large number of contact pairs for signaling and control purposes _, including the pairs i3 a and i3 _& with working contacts, which are in operation when the relays are energized, around the α-circuit to the negative terminal of the battery 11 carry out and the fr circuit to the positive battery terminal. The wire a of the loop circuit is returned directly to the negative battery terminal, but a voltage reducing resistor R is provided between the contact 13j and the positive terminal.

With each fire alarm or station indicator SI , the side of the switch S facing the left (exit) side of the central station is bridged by a direct current-permeable impedance CI , which is in series with a dry rectifier, the rectifier being switched so that it blocks the flow of current from wire b to wire a when, as stated above, wire 6 has the higher positive potential. This enables automatic short-circuit control between a and b. The direct current-permeable impedance can be an inductance or choke with an iron core or, as shown, an ohmic resistor.

As is known in two-wire systems of this general type, if the wires α and b are broken, both relays Ra and Rb will be de-energized and relay Rb will fail due to a short circuit between the two wires. The relay Ra does not drop out due to a short circuit, since it

is then shunted by the resistor R , the resistance "i?" being sufficiently large to produce the necessary potential difference between a and b Indicate that one of the relays has dropped out

ίο Determine the location of the fault and eliminate it.

A fire alarm signal should only sound if both lines are interrupted at the same time, the interruption either through

t5 opening of a switch £ can occur or through the automatic opening of one of the thermal contacts T due to an abnormally high temperature. When this has occurred, the ends of the wires from the battery terminals are connected through, for example, the

so relays are disconnected and connected to group indicators, such as Wheatstone bridges, which, when balanced, indicate the exact department that has been opened. A bridge W is provided for the loop to the left of the interruption and a corresponding bridge, not shown, for the side to the right of the interruption. The arrangements for representing the measuring circuits are as follows: The normally closed contact of the pair I2 _{a of} the relay Ra is connected by a line 14 to the bridge point A of the bridge W and the normally closed contact of the pair 13j of the relay Rb through a line 15 to an adjacent bridge point B. . Accordingly, the normally closed contacts of the switch pairs I2 ₆ of the relay Rb and I3a of the relay R are connected by lines 14 'and 15' with the other measuring bridge. The middle springs of the pairs I2 _a and 13 ^ are connected to the wires α and b , and the simultaneous failure of both relays connects the left part of the open line system with the bridge W as a branch of the same.

The two adjacent ^ branches BC and CD include impedances of the same ohmic resistance, which are preferably the windings of relays 16 and 17, which have contacts in the corresponding error signal circuits (not shown) to give automatic error signals when the bridge circuit BC or is de-energized. CD. The branch DA of the bridge is a variable impedance or a "group seeker" SS consisting of ten DC -permeable impedances, especially resistors r, if the DC -permeable impedances CI of the various stations are of the resistance type as shown. A contact bar c can be turned with the help of a handwheel d to connect the resistors in parallel step by step until the bridge is replaced by the same number of parallel connected resistors r, as equal-

current-permeable impedances CI are present in the bridge branch AB , is balanced.

The zero branch AC of the bridge contains a relay 18 which drops out when the bridge is balanced. The relay 18 has contacts' (not shown) in the signal circuits to indicate the condition which indicates the number of interrupted groups. The negative terminal of the battery 11 is connected to the bridge point B of the bridge W by a line 19, and the positive terminal is correspondingly connected to the bridge point D via a line 20. The bridge W is so continuously energized, and the relays 16 and 17 drop out when the bridge is de-energized to give an error signal.

The operation of the alarm system described is described below, the schematic Circuit diagram showing the same under normal operating conditions.

It should be noted that the positive potential in wire α is very low when the battery 11 is a 24 volt battery, since the resistance of the relay Ra is very high and in any case the majority of the voltage drop of the circuit α represents. The positive potential of the line b along the various groups is significantly higher with regard to the voltage drop through the relay Rb and the series resistance R and also depends on their mutual dimensions. However, the relative polarities of wires a and b are reversed when they are connected to the bridge by opening a switch S or thermal contact T. The line & then has a negative potential, since it is connected to the negative connection terminal of the battery 11 via the lines 15 and 19. The line α has a positive potential, so the rectifiers in series with the group resistors are conductive.

The requirements with regard to reliability in operation and sensitivity in the identification of the alarm point (interruption of both lines) are achieved by direct current-permeable impedances CI in the shunt, since the arrangement of rectifiers RT results in an essentially infinite resistance of the impedances as long as the system is in Normal state and the reversal of the polarity of the lines α and b after opening the two-wire • loop circuit essentially removes the blocking effect of the rectifier RT and the shunt path of each group thereby assumes its normal ohmic or inductive impedance and thus influences the group display through the action of the resistors .

While only ohmic impedances CI have been shown, it will be apparent that an inductive type such as iron core inductors or chokes can be used. The latter have the advantage that the long two-wire loop circuit can then be used for telephone or monitoring signals in one direction or the other from a department to the control center. It should be understood that a plurality of loops of the type described can be connected to a central station simultaneously and that various improvements or refinements in

with respect to the bridge trim resistor or other department display methods can without departing from the scope of the invention.

In order to reduce the effect of the resistances of the line groups, if the same are relatively long, the impedances CI can be chosen to be relatively large in relation to the resistance of the line compartments. Furthermore, a second power source of higher voltage can preferably be used, which is switched on with the aid of relays or manually when the alarming department is sought with the aid of the bridge W.

Claims (6)

Patent claims: 1. Control or alarm system with a normally closed two-wire circuit, which is connected as a loop over a direct current source in a central station, with shunt impedances, which are switched between the wires, the circle at points apart so that they the circuit in a number of Separate groups, with a relay arrangement in at least one of the two lines of the two-wire circuit, which is de-energized in the event of an interruption, and with means for connecting an end part of the two-wire loop circuit to a circuit, characterized in that the shunt impedances (C /) each consist of a DC-permeable impedance in series with a rectifier (RT) , which is designed in such a way that it blocks the flow of current through the impedance under normal conditions when the two-wire circuit is closed. 2. Control or alarm system according to claim i, characterized in that each DC-permeable impedance (CI) is an ohmic resistor. 3. Control or alarm system according to claim i, characterized in that the relay (Ra) in one of the lines of the loop circuit represents the main impedance of this line circuit and that the potential of the line is essentially that of the power source pole which is remote from the relay, a resistor (J?) being connected in the other line on the central unit and remote from its relay (Rb) , whereby the potential of the other line is higher than the potential of the first line, and that the rectifiers (RT) are designed so, that they can block a current flow through the direct current-permeable impedances from the other to one line. 4. Control or alarm system according to one of claims 1 to 3, characterized in that the devices for connecting an end part of the two-wire loop circuit contain means for reversing the relative polarities of the lines in the loop circuit and thereby the rectifier (RT) can be made conductive. 5. Control or alarm system according to claim i, characterized in that it has two-pole switches (S) which are attached at certain intervals along the two-line circuit and are arranged at the beginning of a plurality of groups connected in series, the lines next to each other to pass through protective location, and means are provided to maintain a normal potential difference between the lines over their entire length, and impedances are switched between the wires in the vicinity of each switch, which are the same with respect to the switches and the power sources, and where the rectifiers are connected in series with each shunt impedance and are designed so that they can block the flow of current with normal potential difference between the wires. 6. control or alarm system according to claim i, characterized in that the relays are connected to the corresponding lines at the opposite ends of the loop circuit and in addition to the relay means are provided which can cause a voltage between the wires along the loop circuit, wherein the relay contacts (i2 _a , i3 ₀ or I2 ₆ , 13 ^) contain which, when the relays drop out at the same time, become effective by breaking both wires of the loop circuit, in order to connect one or both ends of the two-wire circuit to a measuring circuit and at the same time the polarity difference reverse between the wires of the two-wire loop circuit. 1 sheet of drawings