DE633251C - Circuit arrangement for combined fire alarm and AC alarm systems - Google Patents

Description

The invention relates to a circuit arrangement for combined systems to fire reporting and alarm purposes, for which the usual street detectors The alarm clock and the alarm clock arranged in their apartment to call the firefighters are in the same loop. Of the There is now a disadvantage of the previously known circuit arrangements of this type that messages could be lost if z. B. a detector was pulled during the AC period, whereby the operational safety, which predominantly determines the value of such systems, is considerably reduced will. A complicating factor is that in some fire alarm systems the Alerting can be done manually and therefore uncontrollably long, so that negligently or even deliberately one or more MeI fertilizers by the in the fire alarm center busy surveillance personnel can be lost.

In order to eliminate this disadvantage, other systems have already been equipped with detectors which have a locking device which prevents the detector type disc from running during the alarm and thus preventing the message from being lost. Apart from the additional effort caused by these blockings, however, these fire alarm systems also have the disadvantage inherent in the aforementioned systems that the message is not transmitted to the control center immediately, but only after an often considerable amount of time has elapsed. Since such encryption 3b delays, can bring with immediate notification to be avoided with damage to a large, in particular, since the delay time is also here uncontrollable at hand success forming alarms, such systems satisfy the conditional not by the practice demands.

In circuit arrangements for combined fire alarm and AC alarm systems, in which with direct current operated alarm and alternating current devices, such. B. alarm clock, lie in the same loop, with an AC control relay, which during the AC period is controlled in such a way that it alternates between the DC power source and the alternating current source connects to the common detector and alarm loop, these become Disadvantages avoided by having the messages from during the alternating current period triggered detectors are transmitted to the loop when the direct current source is switched on. The control of the AC alarm control relay is either energized and de-energized by two alternately Relays with a contact controlled by them or by a surge device with voter or one or more types

The patent seeker stated as the inventor:

Wainö Holmsten in Hohen Neuendorf b. Berlin.

disks causes: - In the further course of the invention, contacts in the primary circuit of the alternating current are used to relieve the contacts of the alternating current control relay ^; transformer exposed to the influence of a relay energized with the AC control relay at the same time, which is de-energized faster than the AC control relay.

ίο There are two examples in the drawing Embodiments of the circuit arrangement according to the invention shown. In the embodiment according to Fig. Ι are for controlling the AC control relay, two relays with one of them influenced Contact provided, while in the embodiment of Fig. 2 one of Type disk device operated by a selector to control the alarm control relay is used.

In the detector and alarm loop 5, fire alarms F with a mechanical drive, type disk and contact device for making contact when the drive is started, and alternating current alarm clock W with a safety device are arranged. In the case of fire alarms F, the type disks driven by the drive control a lever which connects the contact spring connected to the loop either with a break contact or with an impulse contact or an earth contact. Between these two end positions, the contact spring, under the influence of the lever, can assume a central position causing the current SS 'to be interrupted. The safety device for the alarm clock W consists in a known manner of two windings, of which one winding with low resistance allows the loop current to pass, while the other winding is branched off from the middle of the first winding and connected to earth via a blocking capacitor for the direct current. This second winding (safety device for the alarm clock) is there so that the alarm clock can work above ground in the event of a line break. The safety devices for the individual fire alarms essentially consist of a grounded contact each, which connects the loop S to the ground at the moment of the impulse. The contacts H ₁ to A _{6 of} the alarm control relay H are connected between the detector loop 6 ″ on the one hand and the lines leading via the relay A ₁ B to the direct current source C and the lines leading to the transformer U of the alternating current source Y on the other hand. Two contacts h _a , hi can Instead of loop 5 ″, a resistor V can be connected to battery C via relays A, B. A line leads from the middle of the battery cell row C to earth. Of the relays A and B connected between the direct current source C and the loop lines, the Re-'ofajs A controls the contacts a _x to a ₄ and the relay B. ■ rii'e contacts b _x to & ₄ . The contacts a ₃ and a ₂ as well as 5 ₃ and b ₂ are connected to wire break switches D _r . Of the-

sen lead lines after the windings of the relay D ₁ G with the contacts (I ₁ to d _& and gi to g _s . The contacts of these relays D ₁ G again become relays J ₁ K with contacts I ₁ to i _a and k _x to k ₃ is controlled. of the contacts of the relay J, K is a respective spring contacts I ₁ and k _x with the 'positive pole connected. a contact g ₄ has connection to the winding of a relay M ₁ whose other winding end to the negative terminal of power source is placed. This Rel.ais JII controls two contacts, of which the contact Jw ₁ to the positive pole and the contact ^ ^to the negative terminal have. from a respective spring of the contacts i and k _{3 3} a line goes to the winding of the Relay N as well as via the contact M ₁ after the winding of the relay O and from here after the winding of the relay /. The relays N and O control each other by means of the contacts O ₁ M ₁ , while the relay N with the contact M ₂ influences the circuit of the alternating current control relay H and a relay E. One each The spring of the contacts d ₅ and g ₅ is connected to the positive pole, while the opposing springs of these contacts are connected to the negative pole via the winding of a relay Z. One spring of the contact 3 controlled by the relay Z is connected to the positive pole, while the other spring of this contact leads a line to the contact spring X _{2 of} a switch X with contacts X _x to X ₃ . A relay L is connected with one end of the winding to the contacts a ₄ , b ₄ and with the other end of the winding to the negative pole. The relay L controls a contact device which makes the contact / closes after three switching steps caused by current surges. One spring of this contact / is connected to the negative pole and the other spring to the windings of the relay / and K. The contacts h _s and h _e are connected to the secondary winding of an alternating current transformer U , the center of which is connected to earth. The primary side of this transformer U is connected to the alternating current source Y via the contacts e _v e »of the relay E. The relay B is designed in such a way that it has two contact pieces with an adjustable iron core and a cross member attached to it, insulated on it, through movable lines with the primary side of the transformer U in

Are connected, when tightening the iron core puts against two contact pieces that are connected to the alternating current source Y. The relay E is connected on the one hand to the winding of the relay H and on the other hand to the negative pole.

In the embodiment according to Fig. 2, the two relays N and 0 with their contacts 0, M ₁ and K ₂ are missing. Instead, the following device is provided: The relays A, B are each equipped with a further contact a ₅ or b _s . These contacts (Z _{5, s} b are in a circuit, composed of a battery C and the winding of a rotary selector P. From the abrasive brush of this rotary selector P a line leads to the positive terminal, while the individual sliding contacts via a rush current device type discs Q Has connection to the connecting line / between H and E. A starting relay T for the drive motor R of the impulse device with the type disks Q is controlled by the contacts I ₃ and k _{3 of} the relay J ₁ K.

^a 5 The mode of operation of the fire alarm and alarm system designed according to the new circuit arrangement according to Fig. 1 is as follows: In the rest position of the system, the loop S is fed with direct current from the battery C via the contacts Zi ₁ and h _2. When the fire alarm P is activated, the alarm circuit C ₁ A ₁ , A ₁ , F, W etc. ha, B ₁ C is interrupted at short intervals. The relays .4, B alternately release their armatures and then pull them back on in time with the current surges caused by the detector. Normally, ie without a wire break, the two relays A, B work synchronously, while in the event of a wire break only one of the two is always actuated. When the contacts a ₃ , b ₃ close, the following circuits are closed: +, Wi ₁ , a _s , D ₁ Ot ₂ , - and +, Ot ₁ , b ₃ , G, ot ₂ , - · The relays D and G pull open their anchors

⁴ ^ the contacts d _v g _t and close their remaining contacts. This closes the following circuit: -j-, Wi ₁ , d ₃ , D ₁ » ₂ > - \ + > ^m i>gs> G ₁ W ₂ , - ■ and + , Ot ₁ , d ₂ , J, I , -; -j-, Ot ₁ , g ₂ , K ₁ I ₁ -. The first two circuits are so-called holding circuits for the relays D and G. The relays /, ^ do not pick up immediately when the contacts d ₂ , If ₂ close, but only after contact / through three current surges in the circuit -, L, b ₄ , Ot ₁ , + has been closed by means of the relay L. When the relays / and K ' are excited, the following holding circuits are closed: +, I ₁ , J ₁ I ₁ - and - \ -, Jt ₁ , K ₁ I ₁ -. When the fire alarm is over, the relay M is energized in the following circuit: - > Mj gi> d _A , a _v b _u Ot ₁ , +. The relay M draws its anchor and thereby open "the contacts Ot ₁ and Ot _second are so energized relays D, G and M, while the relay / and K. continue to be excited in their holding circuits. For de-energizing the relay D ₁ G and M , the contacts d _u gi, Ot ₁ and Ot _{2. The} relay O is excited in the following circuit: -f, Ot ₁ , g _1; k ₃ , n _v O ₁ I ₁ -. Parallel the contacts d _v i _{a are} connected to the contacts g _t , k _s . The relay 0 picks up its armature and closes the contact 0. This has the excitation of N in the circuit -, I ₁ o, N ₁ k _s > gi > f%> +. At the same time, the relay H and the relay E connected in parallel receive current (+, Ot ₁ , d _t , i _s , n ₂ , H ₁ i _s , Ot ₂ , - and +, Wi ₁ , d _t , I ₃ , M ₂ , E ₁ -). By opening M ₁ , however, the circuit of relay 0 is interrupted again and contact ο is opened. When opening 0 , N is de-excited and M _{2 is opened} and closed from M _1. 0 draws so again at anchor. In this way the relays N and 0 switch each other on and off continuously and cause short current surges in the aforementioned circuits of the relays // and E , which alternately cause the two relays H and E to be energized and de-energized. Both Reiais H and E tighten their anchors at the same time. Since the relay H is provided with a copper jacket, its de-excitation is delayed somewhat, so that it always only releases its armature after the relay E has interrupted the primary circuit of the transformer U by opening its contacts e _v e _2.

The mains or an alternating current generator Y is used as the alternating current source. This is connected to the primary winding of the transformer U with the two lines via the contacts e _ls e _{2 of} the relay E. The secondary winding of the transformer U is connected to the signaling and alarm loop 6 via the contacts Jt ₆ and h _{s of} the relay H The resistor V _{connected to the contacts A 3} , A ₄ corresponds to the resistance of the loop S and is activated when the loop is connected connected to the alternating current transformer U with the direct current source C separated from ω of the loop ^ via the relays A and B. This avoids de-energizing relays A and B during the alarm current period. The different types of de-excitation of the relays H and E serve to relieve the contacts A ₅ , h _{e of} the relay H. The inevitable spark formation when the AC lines are disconnected from the loop S does not occur in the secondary circuit at the contacts h _B and h _e , but in the primary circuit of the transformer U at the

formation of less sensitive contacts e _x and e ₂ of relay E.

In order to be able to send the alarm current into the loop, if necessary, without a fire alarm F being set in motion, a manual switch X and a relay Z connected to its contacts are provided. A spring of the contact X ₁ is connected to the winding of the relay H and a spring ίο of the contact X _{2 is connected} to the winding of the relay N and to the contacts η%, n ₂ . The other spring of contact X ₁ is connected _{to the negative pole via Ot 2} , while the other spring of contact X _{2 can be} connected to the positive pole via contact ζ. The contact is only open if the relay Z is energized when a fire alarm F is activated in the circuit -, Z, g- ₅ , + or -, Z, dg, +. If the relay D ₁ G is deenergized, Z is also deenergized. If the hand switch X is now turned to the right during the time in which no fire alarm is activated, the following circuit is closed: +, Z ₁ X ₂ , %, O ₁ X ₃ , -. Relays O and N begin to work by turning each other on and off. Every time the contact M _{2 is} closed, the relay H in the circuit receives: +, Z ₁ X _2,. H ₂ , H ₃ X ₁ , Ot ₂ , - and the relay £ in the circuit: +, Z ₁ X ₂ , M ₂ , E ₁ - current. The relay H is thus excited and breathed again in the same cycle as in the processes following the shutdown of a set detector with the relay N by closing and opening the contact n _2. At the same time, the relay E relieves the contacts of the relay H and the OfF-. voltage spark when the AC circuit is interrupted moved to the primary circuit of transformer XJ .

If any detector F of the loop 5 "is set in motion during the alternating current supply , the circuit C ₁ A ₁ A ₁ , F ₁ W is switched through the type disk of the activated detector at the moment in which the relay H is de-energized etc., A ₂ , B ₁ C open, so that the relays A, B release their armature and the contacts a _v a ₂ , ^ ₁ , ' b ₂ open, the contacts a _s , a _it b ₃ , 6 ₄ on the other hand getting closed. D and G are excited in the circuits: +, Ot ₁ , a ₃ , D ₁ ni ₂ , - and +, Ot ₁ , b ₃ , G ₁ m ₂ , -. By closing the contacts d ₂ 1 SV, the relays D and G cause the relays 7 and Ιζ to be excited in the circuits: -j-, / 7Z ₁ , d ₂ , J ₁ x & - ■ or +, Ot ₁ , g ₂ , K ₁ X ₃ , - (when an alarm is triggered by hand switch X) and +, Ot ₁ , d ₂ , J ₁ I ₁ - or +, Ot ₁ , g ₂ , K, I ₁ - (when an alarm is triggered following a fire alarm after the third current surge in the circuit: -, L ₁ a ₄ , Ot ₁ , + of the relay L). When relay D or G is energized, the circuit is closed: -, Z ₃ d _s , + (-, Z ₁ g ₅ , +). If the switch X is thrown to the right, the circuit containing the positive pole and the contact X ₂ and thus the alternating current supply is interrupted. In the case of alternating current control following a fire alarm, these alternating current control processes are interrupted by opening the contacts d _v g _± with the aid of relays D and G, so that the fire alarm can be issued unhindered. The alternating current control then only takes place again after the termination of the message.

In the embodiment according to Fig. 2, the mode of operation is essentially the same as in the arrangement according to Fig. 1. The only difference is the generation of the current impulses acting on the excitation of the relays H and E. These are then not caused by relays N and O ₁ but by the impulse generator with the type disks Q. The direct current surges caused in the signaling circuit by the alarm set in motion are transmitted through the contacts a _s , i> ₅ to the circuit of the selector P , which is then set. As a result, a line from the positive pole via the grinding brush arm, a contact of the selector P _1, a contact of the type disks Q to the connecting line I between the windings of the relays H and E is established. From here the circuit is completed once via H ₁ i ₂ , m ₂ , -, the other time via E, -. The type disks Q of the impulse generator are driven by a motor R , which is set in motion by closing the contacts i _s , k _a (-, X ₃ , T ₁ i ₃ , d _t , Ot ₁ , + or -, x ₃ , T ₁ ft _S) g _v Ot ₁ , +). When the message is issued, the P selector is set by the direct current surges in the detector circuit. When the contacts i ₃ , k ₃ "are closed, the motor R is excited and sets the type disk Q in rotation. As a result, a certain number of current impulses is sent into the circuits of the relays H and E via the selected type disk Q of the impulse device. Both embodiments of the subject matter of the invention can also be used in connection with a fire alarm system with telephone stations in the loop line S whose call relays only respond to alternating currents of a certain number of periods the direct current in alternating current with the desired frequency

quenz converts. By regulating this machine, the frequency required for a specific telephone station in the message loop vS "can be set. The above-described alarm impulse using the relay N, 0, H, E or the current impulse device with the type disks Q only An alarm is triggered in the desired telephone station of the loop 5 * ίο The frequencies of the individual telephone stations are different among themselves and selected differently from the frequency to which the alarm clock W respond.

Claims (5)

Patent claims: i. Circuit arrangement for combined fire alarm and AC alarm systems, where detectors operated with direct current and alternating current devices, such as B. alarm clock, in the same Loop lying, with an AC control relay, which operates during the AC period is controlled in such a way that it alternates between the direct current source and the alternating current source connects to the common detector and alarm loop, thereby characterized in that the messages of triggered during the AC period Detectors are transmitted to the loop when the direct current source (C) is switched on. 2. Circuit arrangement according to claim i, characterized in that the control of the AC control relay (H) is effected by two alternately energized and de-energized relays (N, O) with contacts (n _v M ₂ , o) controlled by them. 3. Circuit arrangement according to An 4 "claim i, characterized in that the AC control relay (H) is controlled by a surge device with one or more type disks (Q) , the control of which is effected by a selector (P) connected to the detector circuit. he follows. 4. Circuit arrangement according to claim r, characterized in that to relieve the contacts (h ₅ , h _e ) of the AC control relay (Ji) contacts (e _x , e ₂ ) in the primary circuit of the AC transformer (U) the influence of an AC control relay (H ) are exposed to simultaneously energized relay (E) , which is de-energized more quickly than the AC relay (H). 5. Circuit arrangement according to claim i, characterized in that in ^ o the detector loop (S) at the same time telephone stations are arranged, each of whose call relays each responds only to a current with a certain number of periods. 1 sheet of drawings