DE2739785C3 - Arrangement for connecting two accident stations to one accident reporting device - Google Patents

Description

arrangement specified, with which two microphone units are connected to a common main line (exchange line) will. The contacts of the switch relay connect each participant with the Outside line that picked up his handset first while the other party through the same relay is disconnected from the American line.

The known circuit arrangement is for the connection of two accident stations to one common accident reporting device therefore unusable because the excitation winding of the changeover relay in the Exchange circuit and thereby increases its resistance. The resistance of the exchange circuit may however, do not exceed a prescribed value. This condition limits the length of the trunk and therefore the distance that the Accident stations when using the known circuit arrangement from the main telephone connection may have. Finally, the known circuit arrangement gives the subscriber who uses his handset takes off later, there is no possibility to choose between a line defect and the busy status of the different intercom.

The invention is based on the object of an arrangement for connecting two accident stations to a common accident reporting device, which does not increase the resistance of the exchange line and when picking up the handset of a call station the subscriber about the busy status the main connection and the other call station is informed.

This object is achieved according to the invention in that a digital semiconductor unit DEH is provided, which is fed from a separate supply source UB and whose first output A controls the excitation winding of the switch relay fed by the same supply source in such a way that if there is a binary zero at this output, the first Call station and with a binary one the second call station is connected to the accident reporting device, while a second and third output L 1, L 2 with binary ones an optical display device is switched on at the first and second call station and that when the handset of a call station is lifted its assigned input £ 1 or E2 of the semiconductor unit is assigned a binary one, with a binary one being applied to the third input £ 3 when the main connection is occupied and that the mode of operation of the semiconductor unit is determined by the following information:

a) A binary one at one of the first two inputs of the unit does not cause a change in the binary variables at the first output if the other input is already assigned a one.

b) The variable at the second output takes on the value one when the first input is one and in addition either the third or the first output is at one.

c) The variable at the third output then assumes the value one if the variable at the second Input assumes the value one and in addition either the third input to one or the first Output is at zero and the first input is at one.

By using a semiconductor unit for safety purposes, the arrangement according to the invention brings compared to the known arrangement implemented in relay technology, the main advantage is one lower energy consumption. In the event of an emergency power supply, the batteries provided for this purpose therefore less loaded than with an arrangement using relay technology.

The features of claim 1 put those skilled in the use of microcomputers into the Able to use a microcomputer as a semiconductor unit. The given meaning of the inputs and Outputs defines the external circuit characteristics of the microcomputer, while the program can be created according to the function specifications. Not always however, the use of a microcomputer will only be worthwhile for solving the task at hand. Hence give the subclaims, refinements of the arrangement according to claim 1 from individual modules. Based on Figures the invention is to be explained in more detail.

F i g. 1 is used for the overview The digital semiconductor unit DHE is fed by the supply source UB The inputs El and E2 are assigned to the two microphone units When the handset is picked up at a microphone unit, a binary one is present at the assigned input of the semiconductor unit, while the input E3 b ^ i is occupied Main connection is on one. A binary one at output A closes a switch that switches the current in the field winding of the changeover relay on and off. When the relay is in the idle state, the first intercom is connected to the accident reporting device. Binary ones on the outputs L 1 and L 2 are used to switch on the optical display devices at the first and second intercom stations via the subsequent switches F i g. 1.

Fig. 2 shows an arrangement of individual modules, through which the changeover relay is controlled via the first output A depending on the variables at the first two inputs £ 1 and £ 2. The input £ "1 of this switching mechanism is connected to the first input of a NAND gate CIl, the negative input of an AND gate G12 and via a delay element V to the clock input (C input) of a flip-flop FF , while the second input E2 leads to the second input of the gate GU, the non-negated input of the gate G12 and to the data input (D input) of the flip-flop FF. The reset input (7? Input) of the flip-flop is connected to the output of the gate CIl connected, while the binary value zero is constantly present at the set input (S input). The (^ output of the flip-flop and the output of gate G 12 are each led to an input of an OR gate G 13, which is connected to its output variable at Output A controls a switch. As long as the binary value zero is present at the two inputs E 1 and E2, the flip-flop is in the reset state, that is, because R = 1, the variable at the (J output has the value zero Output variable of the gate G 12 den We rt has zero, output A is also at zero and the switch remains in the position shown.

If the handset of the first call station is picked up first, a binary one is present at input £ 1. As long as the input £ 2 is not assigned a one, the flip-flop remains in the reset state, so that because the output of the gate G 12 continues to have the value zero, nothing at the output A changes. A subsequent one at the input £ 2 only sets the tf input of the flip-flop FF to zero. Because of S = O, the output variable of the Füd-FIods changes

and - as a result - the output variable of gate G13 is not. The switch and with it that Changeover relays also remain unaffected in this case.

If the handset at the second call station is first lifted, a binary one arrives at input E2, while input E1 remains at zero. The one at input E2 can pass the open gate G 12 and gate G 13 and close the switch following output A. The second intercom is now connected to the accident reporting device. A subsequent one on input El sets the /? Input of flip-flop FF and the output of gate G 12 to zero. Delayed briefly by the delay element V, when the zero-to-one transition at the C input of the flip-flop FF occurs, the one of the D input is transferred to the (^ output. The output variable of the gate G 13 thus remains unchanged and the position of the switch is unaffected .

F i g. 3 shows a variant of the arrangement according to claim 2 implemented as a switching network. The switching network consists of the two AND gates G21 and G22, one input of which is negated in each case. The output of each gate is connected to the negated input of the other gate, while the two non-negated inputs of the gates lead to the inputs E1 and E2. The output of the gate G 22 forms the output A of the switching network. If both inputs Ei and E2 are at zero, the outputs of the gates also carry a zero. The switch following output A is therefore open and the first intercom is connected to the accident reporting device. A binary one at input El sets the negated input of gate G 22 to zero and thus blocks this gate for a subsequent one at input E2. The variables at output A are not changed. If input E2 is first assigned a one, the ι switch at output A is closed and the second intercom is connected to the accident reporting device. At the same time, this one blocks gate G 21.

F i g. 4 shows an arrangement of individual modules with which the optical display devices are attached to the

ι «both microphone units can be switched on and off. A light signal at the first intercom should only be switched on if the handset has been lifted there - i.e. a binary one appears at input E1 - and the main line is busy or someone is speaking from the second intercom. The OR link of the last two conditions causes the gate G 31, whose inputs are controlled by the connections E3 and A. At output A of the circuit according to FIG. 2 or F i g. 3 there is only a one when speaking from the second microphone unit. The AND operation contained in the above-mentioned conclusion is carried out by gate G 34. A similar requirement for switching on the display device should also apply to the second intercom. At the output of gate G 32 it can be seen from a one whether the first call station is being used. The OR operation between this case and the case that the main line is busy is carried out by gate G 33. Finally, output L 2 only receives a one via gate G 35 if the handset was picked up at the second intercom station.

For this purpose 2 sheets of drawings

Claims (4)

Claims: ίο 15 20 25 30 35 1. Arrangement for connecting two accident stations to an accident reporting device with a changeover relay, characterized in that a digital semiconductor unit (DHE) is provided which is fed from a separate supply source (UB) and whose first output (A) comes from the same supply source energized excitation winding of the changeover relay controls in such a way that with a binary zero at this output the first call station and with a binary one the second call station is connected to the alarm device, while a second and third output (Li, L2) with binary ones an optical display device is switched on at the first or second intercom and that when the handset is lifted, e ^; ner speech station the input (E 1, E 2) of the semiconductor unit assigned to it is assigned a binary one, with a binary one being applied to the third input (£ 3) when the main connection is occupied and that the functionality of the semiconductor unit is determined by the following information: a) A binary one at one of the first two inputs of the unit does not cause a change in the binary variables at the first output, if the other input already has a one is occupied. b) The variable at the second output takes on the value one when the first input takes on One is and either the third or the first output is also one. c) The variable at the third output then assumes the value one if the variable am second input assumes the value one or, in addition, either the third input assumes the value one or the first output is at zero and the first input is at one. 2. Arrangement according to claim 1 of individual modules, characterized in that a switching mechanism with two inputs (Ei, E2) and an output (A) is provided for controlling the changeover relay, the two inputs (Ei, E2) each having an input NAND gate (G 11) are connected, the output of which leads to the reset input (R) of a flip-flop (FF) and that the first input of the switching mechanism (Ei) also with the negated input of an AND gate (G 12) as well is linked via a delay element (V) to the clock input (Ck) of the flip-flop, while the second input (E2) of the switching mechanism is also connected to the second, non-negated input of the AND gate (G 12) and to the data input (D ) of the flip-flop is connected, whereby a binary zero is constantly applied to its set input (SJ) and that the output of the AND gate (G 12) and the (? output of the flip-flop to the two inputs of an OR gate (G 13), the output of which is connected to output (A) dzs Rear derailleur is placed ^fi o. 3. Arrangement according to claim 1 made of individual modules, characterized in that a switching network with two inputs (Ei, E2) and an output (A) is provided for controlling the changeover relay, each input of the switching network having an AND gate (G2i or G22 ) is assigned with a negated and a non-negated input and 45 50 55 that the inputs of the switching network are led to the non-negated inputs of the gates assigned to them, while the negated input of each gate is connected to the output of the other gate and the output of the second gate is connected to the output (A) dzs switching network. 4. Arrangement according to claim 1 made of individual modules, characterized in that five gates each with two inputs (G 31 - G 35) are provided for controlling the optical display device at the call stations, the first gate (G3i) being an OR Gate, the second (G 32) is an AND gate with a negated input, the third (G 33) is again an OR gate and the fourth and fifth (G 34, G35) are AND gates and the first input (Ei) of the arrangement is led to an input of the fourth gate and at the same time to the non-negated input of the second gate, while the second input (E2) of the arrangement is connected to an input of the fifth gate and the terminal (A) of the Arrangement is coupled both to the negated input of the second gate and to an input of the first gate, while the other input of the first gate and an input of the third gate via a common third input (E3) binary inform ation received from the accident reporting device and that the output of the first gate is coupled to the other input of the second gate, the output of the second gate to the other input of the third gate and the output of the third gate is coupled to the other input of the fifth gate and the outputs of the fourth and fifth gate coincide with the outputs (Li, L2) of the arrangement. 40 The invention relates to a crash detection system, which is connected to a main terminal of the public telephone network. Such an accident reporting system is described, for example, in the German patent application DE-AS 12 99 047 and is then divided into an accident telephone station and an accident reporting device. The accident reporting system described is usually set up on roads for which no separate accident reporting network has been created. The accident station is located outdoors and contains a speaker device protected by a housing, which z. B. can be designed as a handset. The accident reporting device is housed within the building in which the telephone connection to which the accident reporting system is connected is located. In addition to a test device that tests the connection line of the main connection for its occupied state, the accident reporting device contains a dialing device. This facility gives z. B. after picking up the handset and with a free connection line automatically the number of a subscriber who is to be informed about a possible accident. If roads on which the system described is to be used have two lanes separated by a median, it is advisable, for safety reasons, to provide an accident station for each side of the road. In "instruction sheets (B) of the Deutsche Bundespost", 1959, No. 9, page 172, Fig. 10 is a circuit