DE2755826A1 - Alarm loop monitoring circuit - has FET to allow check on amplitude of voltage in loop when supplied with DC and superimposed AC signal - Google Patents

Abstract

The monitoring of the condition of an alarm loop is effected by checking that the amplitude of the supply stays with predetermined limits. The signal generator (3) is supplied by a d.c. signal (131) onto which is superimposed an a.c. signal (132). A field effect transistor (32 operated as a dynamic resistance with the working contact (33). The receiver (11) has a measuring resistor (112) with a capacitor (111) to check that the voltage stays within limits. If the signal goes outside the specified limits, a signal trigger stake operates.

Description

The invention relates to a loop protection system according to

the direct-alternating voltage method according to the preamble of the main claim, The purpose of such loop security systems is to monitor objects and in the event of changes to cause a signal or alarm to be given to them. A measure of the quality of such Loop security systems are your security against being tricked.

This is generally higher, the greater for an unauthorized person the Expenditure of material, time and skill is to go along with any manipulation the reporting line for the purpose of unauthorized changes to the object to be monitored to prevent an alarm being triggered.

Simple loop protection systems have each as a message transmitter only one contact that interrupts or switches through a current loop to generate an alarm (Rest resp.

Working contact). A simple short-circuiting is sufficient here (bridging) or, a separation of the alarm line in order to put the message transmitter out of operation.

Loop security systems with a higher security value have besides passive components such as ohmic resistors and / or reactive resistances to the contacts at the message provider. They are looped in so that they are in the circuit of the signal line cause a certain quiescent current strength as a setpoint, which is from the message receiver is monitored for deviation from the setpoint.

In these systems, it is necessary to put the message transmitter out of operation only required by looping in at least two adjustable resistors into the reporting line, of which at least one in series and at least one in parallel to the Contacts and passive components, the current from Branch off the message generator and lead it past it.

I) The adjustable resistors looped in only need to do this are adjusted in opposite directions so that the current on the signal line is then constant remains when the reporter is removed from the system. The electricity on the reporting line only has to be monitored, which is possible with a simple ammeter. This manipulation can be carried out in a short time with relatively little effort.

The above also applies to loop protection systems that have been improved in comparison, in which the voltage feeding each signal line has a certain frequency and the monitoring for deviation from the target value of the loop current of this frequency is controlled accordingly so that only deviations of the loop current from the cause the setpoint present at the moment to trigger an alarm. To change the supply voltage can, for example, its amplitude by means of a special key pulse sequence or a clock can be changed in a controlled manner. This is also complete, for example easily achievable by adding an AC voltage to a DC supply voltage is superimposed. This is commonly referred to as the DC-AC voltage method.

The underlying task of the discovery, an unauthorized, on decommissioning target manipulation of the reporter to further complicate, without the costs and the cost of the security system will increase significantly, is due to the in the main claim characterized invention solved.

After this, a dynamic resistance is inserted in each message transmitter, which keeps the current flowing through the signaling device constant, although the supply voltage changes or varies.

Advantageous further developments of the invention are set out in the subclaims marked.

The advantage that can be achieved with the invention is, above all, that a shutdown of the 'signaling device along the reporting line is essential difficult. This deactivation is only possible if the dynamic Resistance is modeled exactly in terms of its characteristic curve.

In addition, this simulated dynamic resistance must immediately die full function of the dynamic resistance present in the message transmitter according to the invention take over. A slow adjustment is not possible because the tension and thus the dynamic resistance present in the message transmitter also change as a function of time. The simulated dynamic resistance must be sudden at the same time Interruption of the current coming from the message transmitter in a shorter time than the response time of the message recipient. This is just through electronic components possible, reducing the cost of material and time as well the demands on the ability and dexterity of the manipulator are essential rise. On the other hand, the additional costs of such a loop protection system are likely are only slightly higher than with systems of the same order of magnitude that have been used up to now.

The invention is illustrated by the exemplary embodiments shown in FIGS. 1 to 3 and details explained in more detail.

Fig. 1 shows the overall structure of the loop protection system according to the invention. As usual, it has a control center 1, at least one reporting line 2 and at least one message transmitter 3.

A is used to supply the loop protection system with direct current Power supply unit 121 for power failure protection and uninterruptible emergency power supply a battery 122 is connected downstream, which is buffered. The power supply 121 and the battery 122 are combined to form a power supply part 12.

A DC voltage generator is part of the power supply 13 of the message generator 131, an alternating voltage generator 132 and an amplifier 133. The sum signal of the DC voltage generator 131 and the AC voltage generator 132 is over put the amplifier 133 on the alarm line 2. Through this amplifier 133 is it is possible to control several message transmitters 3 in parallel.

The message transmitter 3 consists of a normally closed and / or normally open contact 31 and 33 (Fig. 1 and Fig, 2, only the message transmitter 3 shown in Fig. 2) is) as well as a dynamic resistor 32 inserted according to the invention. This can in the simplest case, as shown in FIG. 3, from a field effect transistor 321 and a source resistor 322. The resistance value of the voltage-proportional in particular dynamic resistor 32 changes in time with the applied alternating voltage in such a way that the resistance value increases with increasing voltage and decreasing with decreasing voltage Voltage the resistance value decreases, so that the one flowing through it Current remains constant within certain limits. This constant stream that flows back over the backward direction of the message line 2 to the message receiver 11 is generated at a measuring resistor 112 in the message receiver 11 a constant voltage drop. This voltage drop is monitored with a window discriminator 111.

If the amplitude of the voltage drop across the measuring resistor 112 is the falls below or exceeds the lower or upper threshold value of the window discriminator, this then leads to signaling by a signal generator 113.

Claims (4)

Loop protection system based on the direct alternating voltage method (4) Patent claims loop protection system according to the Glelch-Wechselp; LirnunE8 method with a signal generator designed as a contact and one looped into it ResistanceP of the quiescent current with a certain in the circuit of the alarm line Setpoint causes, and with monitoring this setpoint in the message receiver d a it is clear that this resistance is a dynamic resistance (32) is. 2. Loop protection system according to claim 1, characterized in that that this dynamic resistance (32) is proportional to the voltage. 3. Loop protection system according to claim 1 and 2, characterized in that that the dynamic resistor (32) consists of a field effect transistor (321, Fig. 3) and a source resistor (322), which are preferably in the main circuit. 4. loop security system according to claim 1 and 2, characterized in that that the dynamic resistance (32) through the message line (2) and the message transmitter (3) keeps flowing current constant as long as the amplitude of the supply voltage remains within certain limits.