DE49025C - Circuit for fire and security telegraphs - Google Patents

Description

IMPERIAL

PATENT OFFICE.

For fire and security telegraphs, closed-circuit operation is used in most cases brought into use for the purpose of increasing reliability. One If the line is interrupted, it will immediately report itself automatically. But there can be more a line break, other errors occur, which are therefore more dangerous, because they do not report themselves' and you do not find out earlier in the Central Station, than until it's too late, respectively. a message has not arrived; it is then a sideline or earth fault in the line. For this reason, some circuits have been specified, which are partly with two separate wire loops, partly remedy this inconvenience with a simple wire loop. In order not to have to lose the advantage of the automatic display of line interruptions, The closed-circuit operation was also considered here. But these circuits had nor the deficiency that if reports came in from two bodies at the same time, they were mutually exclusive interfered with each other, but then also that the battery consumption was quite considerable maintenance costs required.

On the accompanying drawing, a circuit is now shown, by means of which this makes it possible messages from two different points in a loop line at the same time to receive.

In Fig. Ι the line was assumed to belong to a fire telegraph system, but it can of course be used for any other system.

Fig. 2 shows one of the automatic signaling apparatus (Fire alarm apparatus) in the idle state, which is switched on in the loop line, Fig. 1 and whose purpose is to automatically convey a telegraphic message to a central station.

In the central station there are two writing apparatus (Morse apparatus) 5 ¹ S ² , Fig. 1, also a galvanoscope G, a bell, a switch P, a magnetic inductor J, a lightning rod and two batteries B ¹ B ² . The magnetic inductor J can be switched on by switching the switch P from 6 to 5 in the branch L ¹ and by switching the switch P from 2 to 3 in the branch JL ² . This happens when a bell signal (as a sign of understanding) is to be given after a report has been received by the signaling apparatus in question, which, as will be explained later, connects the line to earth when reporting.

From one lamella of the lightning rod in the central station, the line leads to all signaling devices and goes back to the second lamella of the lightning rod in the central station. The two batteries Bl and B ² are turned against each other in the line, they ie cancel except for a slight, about which the battery B ² is stronger than B ¹ (B ¹ has, for. Example, six elements, B ² whose seven ), in their effects. While the two negative poles of batteries B ¹ and B ^{2 are} connected to each other and to earth, there is no further earth leakage in the entire circuit during the idle state, so that only the small current by which the battery ΰ ^{2 is} stronger than B ¹ is,

flowing through the line. The latter takes its way from the positive pole of the battery B ² through the writing apparatus »S ² , contact 6 of the changeover switch P, lightning rod through the line and the signaling apparatus, ¹ back to the central station, lightning rod, contact 2 of the changeover switch P, writing apparatus S ¹ , Galvanoscope G, battery Β ^Λ to the negative pole of battery B ² . This weak current is incapable of causing the armature and the electromagnets of the writing apparatus to be attracted, but the needle of the galvanoscope G is brought a little out of its zero position.

The establishment of a signal apparatus respectively. of a detector, which in such lines is to be switched is shown schematically in FIG.

This device, like the usual devices that have been in use for many years, essentially consists of a drive which is pulled up by a crank when signaling and then sets a type wheel T in rotation when it runs down, in the periphery of which the desired number of the signaling device is set Corresponding "Morse symbols are milled. With the help of a contact spring U, which rubs on the type wheel, the circuit is interrupted when reporting, according to the notches on the type wheel.

With these devices, the device is still in place, that by pulling the lever H ¹ through the eccentric H on ^{the contact screw c 5} when reporting, and holding it in this position by an arbitrarily arranged lock until the door is closed Apparatus or by hand, the lock is lifted and the lever H ^{1 is} pulled back into its rest position by a spring. The type wheel T carries a pin s, which in the rest position holds the lever H ² on the contact screw c ^s. When the type wheel T rotates, the pin s slides over the lever H ² and this, pulled by a spiral spring, lies against Contact c *. Lever H ² is pressed for a moment at c ³ by the pin s each time the wheel T is fully rotated, and in the rest position it rests firmly against this contact.

In the signal apparatus there is also a polarized relay, which can be used as a feedback. (AC) bell can be formed and its armature SN is held in place on contact screw c ¹ by a bolt B when the apparatus door is closed, FIG. 2.

A short circuit is attached to lightning rod A, which connects the exit and entry lamellas of the lightning rod when the door is closed (briefly closes).

When the door of the apparatus is opened, this short circuit is canceled. When a signaling device is activated, the line, as lever H ^{x is connected} to contact c ⁵ , is connected to earth. Since the negative poles of the two batteries B ¹ and B ^{2 are} also connected to earth in the central station, the loop line is transformed into two radial lines, each of which has a battery and the ends of which are on common ground. It arises how. As will be shown later, this also has the advantage that if the part of the line designated for reporting is already occupied by the simultaneous reporting from a reporting point closer to the central station, the set automatically switches itself to the unoccupied line. The same naturally also applies if there is an interruption or insulation fault (e.g. at J? ¹ , Fig. 1) in front of the reporting point.

The apparatus of Fig. 2 is intended in the manner shown for the left half of Fig. 1 of the loop line, for the right half of the loop line of Fig. 1 the role R ^{1 of} the polarized relay would have to be at c ² and R ² at c ¹ , or the line L ¹ at c ² and L ² at c ¹ .

The following cases can now occur when reporting: ■■

ι. Both halves. the loop line are unoccupied. When the door of the signaling apparatus is opened, the short-circuit on the lightning rod A is interrupted and the bolt B steps back from the armature SN of the polarized relay. The current effect is still zero now. By pulling up the drive, the lever H ^{1 is connected to the contact screw c 5} by means of the eccentric //, which sits on the pull-up axis, and thus the line is connected to earth and temporarily held (locked) in this position by a blockage.

Both roles of the polarized relay are traversed by the current in the same direction. The galvanic current goes from the positive pole of the battery B ² through the writing apparatus S ² , contact 6 of the switch P, lightning rod, line L ^x to the signal apparatus, Fig. 2, contact c ¹ , role R ^{1 of} the pole _T risirten Relay, Contactfeder U, Contact c ³ , Lever // ² , Lever // ¹ , Contact c ⁵ , Earth ,. Earth £ back to the negative pole of battery 5 ² ; furthermore, a current goes from the positive terminal of the battery B ¹ through the galvanoscope G, writing apparatus 5 ¹ J; Contact 2 des, changeover switch P, lightning rod, line L ² after the signaling device, Fig. 2, Contact c ² , role R ² , Morse button, type wheel T, spring U, Contact e ³ , lever H ² H \ Contact C ⁵ , Earth, earth E, negative pole of battery B ¹ . The effect on the armature 5 N of the polarized relay is zero. When the work comes to an end, that becomes

Type wheel 'X ¹ taken along. This wheel carries a pin s, which now controls the lever H ^2. running. The latter rests against the contact screw c ^4, pulled by a spiral spring. When the lever H ² passes from contact c ³ to c ^4, there is no interruption of the current, since the contact springs ^{on lever // 2} , before they leave contact c ³ completely, are already in ^{contact with c 4} and only then from c ³ exit. The positive current of the battery B ¹ now goes through the writing apparatus S ¹ J Contact 2 of the switch P, line L ² , enters the signal apparatus at Z. ² , Fig. 2, goes to contact c ² , role R ² , Type wheel T, contact spring U, roller J? ^1, Contact c ^1, armature 5 N, Contact c ^4, lever H ² H ¹ for the contact screw c ⁵ and the earth, the earth E, the negative terminal B ¹ and produces at R ² a south pole, wherein R ¹ is a north pole, the armature So SN is held in the position shown and the battery B ² is connected to earth ^{through L 1} , c ¹ , SN, c ⁴ H ² , H \ c ^5. Both anchors of the writing instruments S ¹ S ² are attracted. With the now following interruptions of the circuit in line -L ² by the type wheel T and contact spring U , the Morse device S ¹ writes down the Morse characters corresponding to the detector in question.

2. The line is occupied by a station further away from the central station. When the door of the signaling device is opened, the positive current coming from battery B ¹ flows through both rollers, the armature SN is held in the position shown and the effect is exactly as given under 1..

⁽ 3. The line is manned by a station closer to the central station. When the door of the detector is opened, the current coming from the battery B ² flows through the rollers R ¹ R ² in the opposite direction, as indicated under 1. and 2. above at R ¹ a south pole, at R ² a north pole; the armature 5 N is connected to contact c ^2. The apparatus is thus connected to line Z, ¹ , Fig. 1, and works with battery B ^2. line L ² , Fig. 2, is connected to earth ^{during reporting by c 2} , SN, c \ H \ H \ c ^5.

4. During the message, a station further away from the central station switches on. The station to report first is not disturbed. The station farther away from the central station automatically switches its apparatus into line L ¹ , as indicated under 3., if it usually belongs to L ² , Fig. 1. If this station is intended for line L ¹ , then the following applies the case 2. with interchanging the characters B ² with B ^{1 and} so on

. 5. During the message, a station closer to the central station switches on. Since with each revolution of the type wheel T the contact lever H ' ² is temporarily placed from c ⁴ to c ³ by pin s , the current of the battery B ² enters through L ¹ , goes through c ¹ , R ¹ , c ^s , H ² , H ¹ to earth and attaches the anchor SN to c ² . No current flows through role R ² because line L ² is connected to earth in front of the reporting point. After the pin s has left the lever H ² , R ² also receives electricity again, which, however, acts in the same way as the ^one flowing through R 1. The result is that the station continues its message on the other half of the line if it has been disturbed by switching on a station closer to the central station.

6. During the message, a station closer to the central station and one further from the central station switches on. The line will be connected to earth on both sides in front of the station. As can be seen from Fig. 1, the current of the magnetic inductor J, which can be switched on by the switch P either in the line L ¹ or L ² , is only delivered to one half each time, so that only those stations whose messages have arrived correctly are, the usual response ringing by a role of the relay designed as an alternating current alarm clock received ^one after the other, because after completion of the message, the roles jR 1 and R ² by c ^s , H ² , H ¹ , c ⁶ on. Lying on earth. In this case, the one reporting first. A station whose Morse code does not fully enter the Central Station does not receive an understood signal. Instructionsgema'fs will report this station again after a few seconds, and if one of the other two reporting stations has closed the device door, i.e. switched off the earth, this message will arrive at the central station (according to case 3, 2 or 1).

7. The line has a point closer to the central station than the reporting station an insulation fault. The effect is as described under 3; it's the same as if a station closer to the central station than the reporting station is already switched on, respectively reports.

8. The line has been located at a station more distant from the central station than the reporting station Spot an insulation fault. In this case, the process is as described under 2.

9. The line is interrupted at a point closer to the central station than the reporting station. When the detector is pulled up, lever H ¹ connects with contact c ^5; the current coming from the battery B ² flows through the roller R ¹ and applies the armature SN to contact c ² . The rest is known from the foregoing.

ίο. The line is at one of the central stations more distant than the reporting station interrupted. How easy to see this case is irrelevant.

If an insulation fault occurs, this is done by pulling both writing levers and keeping the local alarm clock in the. Centrale noticeable. If the line were destroyed, i.e. interrupted, the needle of the galvanoscope G would lie on the pin g, which is attached to the zero point, and make contact with the same, whereby the bell in the central station will sound.

3 and 4 show the mutual connection of the batteries in radial lines. A battery is connected behind the last station in FIG. 3, and the second battery behind the central station's Morse set. Both batteries almost cancel each other out in their effects; the galvanoscope has only a slight deflection. Each detector switches itself to earth when it reports, which means that battery B ² comes into effect while B ^{1 is} switched off. As soon as electricity flows through the line, the Morse device is triggered and the subsequent power interruptions generate the Morse symbols.

An insulation fault is indicated automatically, since in this case the Morse set is running and the bell in the central station sounds. An interruption in the line is reported again by the galvanoscope, since the needle of the same rests on contact pin g and sets the alarm clock to work.

Fig. 4 shows the central station lying in the middle of the line. Two batteries are still used here, but all four batteries cancel each other out except for a small amount. In the central station there is a polarized relay, the armature of which is provided with two springs that attach to the contact screws c ⁷ c ⁶ and hold the armature in the middle position. The lever s ¹ rests on the anchor with a piece of ebonite.

Assuming that the station M reports it. The same switches to earth. The battery B ¹ is switched off. As a result, the batteries B ² and jB ⁴ counteract the battery B ³ as connected in series. The positive current goes from battery B *, earth, detector M, line L ³ to the negative pole of battery J3 ² , positive pole of the same, galvanoscope G, Rollei? ^{3 of} the relay, contact c ⁷ , armature SN, contact c ⁶ , role jR *, positive pole from S ³ , negative poi from B ³ , line L ⁴ and back to battery B ⁱ . The countercurrent of the battery -B ³ is by far overcome by the current of the batteries B ² and B ^4. The relay R ³ R ⁱ places its armature on R ⁱ , whereby the contact at c ⁶ is released, and the lever s ¹ falls down and locks the armature SN in this position, forming the same contact at the same time. Now the positive current goes from battery B ² through galvanoscope G, roller R ³ , contact c ⁷ , anchor SN, lever s ¹ , writing device S, earth, detector M, line L ³ and back to battery B ² . The writing apparatus S is triggered and the subsequent power interruptions generate the message characters. After the message, the lever s ^{1 is} lifted again by hand and the anchor goes back to its rest position. The unoccupied line is switched off during a message.

The same happens with a message on line L *, only that the anchor SN is then firmly attached to c ⁶ and the contact at c ^{7 is released} .

Insulation faults and interruptions are also automatically reported here immediately.

Claims (2)

Patent Claims: ■ 1. With telegraph systems of all kinds for the purpose of immediate automatic notification of incoming Insulation faults, and line interruptions the application of against batteries connected to each other in such a way that they mutually support each other in the rest position up to a minor point in their effects, but parallel in the working state are connected to each other. 2. When using the device mentioned under 1. on loop lines, the automatic activation of the signaling apparatus after the unoccupied resp. fault-free line, caused by a polarized relay in the signal apparatus, which, depending on the current flowing through it in one or the other direction, places its anchor on contacts c ¹ and c ² and thereby switches the signal apparatus into the right or left half of the loop. For this purpose ι sheet of drawings.