DE4115630A1 - Electrified pasture fence monitoring circuit - acts cyclically with protection pulses and indicates low resistance condition of electrified fence compared to undisturbed high resistance condition - Google Patents

Abstract

The circuit arrangement (10) determines those current and/or voltage fluctuations, which differently shape a protection pulse according to the condition of the pasture fence (8) at this or the electrified fence unit (1). The evaluation circuit compares one or more characteristic values (t0-t1) of at least one of the half waves (a,b,c) of the oscillations with one or several normal values (tm,tu), which are maintained in the undisturbed condition of the pasture fence (8). The evaluation circuit (11-14) controls the indicating unit (15), with a deviation of the characteristic value(s) from the assigned normal value(s), for delivering a signal.

Description

The invention relates to a circuit arrangement for Surveillance of a pasture fence by a in particular having a low output impedance, Electric energizer cyclically charged with herding impulses is, with an evaluation circuit and Display device in the faulty state of the Electric fence emits a signal.

In addition to electric fencers with high Output impedance, those with low output impedance. With such energizers with lower Output impedance is the maximum power output at a fence impedance of 500 ohms, for example. Such Electric energizers come with an electric Pulse generator circuit with charging capacitor and one Control device for monitoring the Minimum fence voltage equipped. These The minimum fence voltage is 2 kV according to VDE regulations.

Such powerful energizers with lower Output impedance is also suitable for long-term operation Pasture fences. They offer even in poorly insulated Pasture fences or vegetation are still high Guard security. The minimum voltage of 2 kV the Herding impulses is even with partial ground contact of the  Pasture fence still guaranteed.

The disadvantage of such powerful Energizers that the user at most receives insufficient information about the fence condition. In practice, for example, the case may arise that cattle partially touching the fence can break out. Because the user recognizes it Not touching the fence because of the Minimum fence voltage of 2 kV persists and the Control device indicates this. These facts are especially for powerful energizers disadvantageous because they are used in long pasture fences and with these the probability of Impurities or touching the floor increases.

In DE 34 39 015 C2 is an electric fence device with described low output impedance. To be quick feasible test for a minimum impedance value to allow the connected fence is between the Pulse generator circuit and a display device Circuit part provided with which the impedance of the Can temporarily increase energizer.

In DE-OS 23 23 212 is an electric fence device with a Display device for the operating state and Functional safety of the fence described. It will be here evaluated the voltage amplitude of the charging capacitor. For energizers with low output impedance such a circuit is unsuitable.

In CH-PS 6 37 000 (DE-OS 28 09 392) is a Electric energizer described, in which the pasture fence one Fence loop forms, the fence wire with both its beginning as well as its end to that Energizer is connected. It will be the one in the end existing fence tension measured. A wire break can clearly be seen.  

However, touching the ground can hardly be evaluated.

The object of the invention is a circuit arrangement to propose of the type mentioned at the outset compared to the undisturbed, high-resistance state indicates the low-resistance condition of the pasture fence.

According to the invention, the above object is achieved in that the Circuit arrangement those current and / or Detects voltage vibrations that affect one Depending on the condition of the pasture fence this or on the energizer different design that the evaluation circuit one or more Characteristic values of at least one of the half waves of the Vibrations with one or more normal values compares who in the undisturbed state of the Electric fences are adhered to, and that the Evaluation circuit the display device at a Deviation of the characteristic value (s) from the assigned one Normal value or the assigned normal values for delivery controls the signal.

Measurements have shown that each herding pulse of the Electric fence device for current and voltage vibrations on Pasture fence and in the energizer leads. It was found that the shape of this current and Voltage vibrations depend on the impedance that the respective pasture fence or the condition of the respective Pasture fence forms. With different states of the Electric fences are correspondingly characteristic different current and voltage vibrations. This detects the circuit arrangement. Theirs Evaluation circuit is based on one or more normal values of the half-waves that occur as long as the Electric fence is not low impedance due to a disturbance. The Evaluation circuit compares these normal values with one or several characteristic values of the respectively occurring Half wave. In the disturbed, low-resistance state, it gives way  or the characteristic values of the normal value or values characteristic. The display device then enters Signal off.

This circuit arrangement is not based on the evaluation the amplitude of the vibrations. Leave with her other characteristic values of the half-waves are recorded. In preferred embodiment of the invention compares the Evaluation circuit by means of at least one of the half-waves of a timer with a normal time value, which at a certain current and / or voltage threshold is present. It is also possible to change the polarity and number of the half waves. The normal values can also Current or voltage normal values. Furthermore can also change the phase of the current and Voltage half-waves can be evaluated.

Overall, due to the circuit arrangement Electric energizers with low output impedance one reliable detection of a ground contact of the pasture fence possible. In addition, it can also be recognized whether the Pasture fence a predominantly ohmic or predominantly represents capacitive load. It can also be seen whether the Electric fence connected to the energizer at all is.

The circuit arrangement can either be on the pasture fence or on the secondary or primary side to the Energizer must be connected. The Circuitry can be placed in the energizer be integrated. However, you can also use your own device form that in addition to a known Electric fence device then on this or the pasture fence can be connected.

Advantageous refinements of the invention result from the subclaims and the following description of embodiments. The drawing shows:  

Fig. 1, an electric fence device with a connected electric fence schematically, wherein the circuit arrangement detects the primary current of the energizer,

Fig. 2 shows an alternative to Fig. 1, wherein the circuit arrangement detects the fence current on the secondary side of the energizer,

Fig. 3 shows a further alternative to Fig. 1, wherein the circuit arrangement detects the current on the fence side of the fence,

Fig. 4 shows the course of the oscillations of the primary current and the fence voltage at a low, troubled fence low capacity - so recently fence,

5 shows the current-voltage curve corresponding to FIG. 4 is lower in a high-impedance undisturbed fence capacity.,

. Fig. 6 shows the current-voltage curve corresponding to Figure 4 with high low-impedance, degraded fence capacity - so long fence,

Fig. 7 shows the current-voltage curve corresponding to Fig. 4 with high impedance high undisturbed fence capacity,

8 shows the course of the vibrations of the fence and the fence current voltage at a low impedance, low capacitance disturbed fence -. So short fence,

Fig. 9 shows the current-voltage curve of FIG. 8 lower in a high-impedance, undisturbed fence capacity,

Fig. 10 shows the current-voltage curve of Figure 8 high at a low, disturbed fence capacity -. So long fence,

Fig. 11 shows the current-voltage curve of FIG. 8 high at a high impedance undisturbed fence capacity,

Fig. 12 shows a circuit arrangement for monitoring the primary current or the fence current by evaluating the first positive half wave,

Fig. 13 shows a circuit arrangement according to Fig. 12 for additional analysis of a negative half-wave and

Fig. 14 is a circuit arrangement of FIG. 12 for additional monitoring a second positive half-wave.

An electric fence device ( 1 ) is shown only schematically in FIGS. 1 to 3. In the example, a mains-operated energizer with a low output impedance was used to determine the current-voltage profiles according to FIGS . 4 to 11, as is known on the market, for example, under the type designation S 8000 (AKO).

The electric fence device ( 1 ) has a transformer ( 2 ), on the primary side of which a charging capacitor ( 3 ) is connected in parallel. When an electronic switch ( 4 ) is closed, the charging capacitor ( 3 ) discharges via the primary winding ( 5 ) of the transformer ( 2 ) and the switch ( 4 ). This creates a primary current (Ip) as shown in the current profiles according to FIGS. 4 to 7.

The secondary winding ( 6 ) of the transformer ( 2 ) is connected to a pasture fence ( 8 ) at a terminal ( 7 ). In addition, the secondary winding ( 6 ) is connected to an earth terminal ( 9 ). The ohmic resistance and the capacitance which the pasture fence ( 8 ) forms are represented by R and C, respectively. With a primary current (Ip) in the primary winding ( 5 ), a fence current (Iz) is established in the secondary winding ( 6 ) or in the pasture fence ( 8 ), as is shown in the current profiles of FIGS . 8 to 11. The fence voltage (Uz), which is shown in the voltage profiles of FIGS . 4 to 11, is present at the pasture fence ( 8 ).

An undisturbed, well-insulated pasture fence ( 8 ) has a high resistance. Its resistance (R) is of the order of 1 MOhm (cf. FIG. 5, FIG. 7, FIG. 9, FIG. 11). If the pasture fence ( 8 ) is disturbed, for example, by vegetation or by touching the earth, then it has a low resistance. Its resistance may in this case be approximately 500 ohms (see. Fig. 4, Fig. 6, Fig. 8, Fig. 10). The fence voltage (Uz) does not drop below the minimum voltage of 2 kV provided by VDE regulations.

If the pasture fence ( 8 ) is comparatively short, then its capacity (C) is low. A short fence (8) of 1 km in length, the capacitance (C) is about 10 nF (see. Fig. 4, Fig. 5, Fig. 8, Fig. 9). The capacity (C) increases with longer pasture fences ( 8 ) by about 10 nF / 1 km. For long fences when calculating the energizers fence with capacities of up to 1 F (see. Fig. 6, Fig. 7, Fig. 10, Fig. 11) is calculated.

In the exemplary embodiments, a circuit arrangement ( 10 ) is provided which detects at least one current half-wave of the oscillation of the current (Ip or Iz), which occurs when a herding pulse is generated by closing the switch ( 4 ). According to Fig. 1, the circuit arrangement (10) detects the primary current (Ip). According to FIGS. 2 and 3, the circuit arrangement (10) detects the fence current (Iz). In this case 2, the circuit arrangement (10) detects the embodiment according to Fig. Fence current (Iz) at the secondary winding (6), thus in the electric fence device (1). In the embodiment according to FIG. 3, the circuit arrangement (10) detects the fence current (Iz) on the electric fence (8). It can be constructed as an additional device to the electric fence device ( 1 ).

A comparison of the current profiles of the primary current in FIGS. 4 and 5 shows that the first half-wave of the primary current (Ip) with a low-resistance pasture fence ( 8 ) (see FIG. 4) clearly differs from the course of the first positive current half-wave with a high-resistance one , undisturbed fence (see Fig. 5) differs. According to FIG. 4, the first current half-wave - apart from its higher amplitude -. Time substantially longer than in Figure 5 the same (see Figures 8 and 9...) Of the fence current is obtained when comparing the first positive half-waves. This characteristic difference is evaluated in the circuit arrangement according to FIG .

A comparison of the courses of the primary current (Ip) in a pasture fence ( 8 ) with a large capacity (0.5 F to 1 F), i.e. a long pasture fence, shows that in the low-resistance (500 Ohm), ie disturbed state (cf. Fig. 6) the first positive half-wave of the primary current (Ip) differs only slightly from that in the undisturbed state (see FIG. 7). However, in the undisturbed case (see FIG. 7), a characteristic, negative half-wave (b) occurs after the first positive half-wave (a). A second positive, characteristic half-wave (c) also occurs after this.

In the circuit arrangement according to FIG. 13, the primary current (Ip) is additionally monitored for the occurrence of the negative half-wave (b). In the circuit arrangement according to FIG. 14, the primary current (Ip) is additionally monitored for the occurrence of the second positive half-wave (c). The same results when comparing FIGS . 10 and 11 for the fence current (Iz). Here too, the undisturbed state occurs after the first positive half-wave (a), the negative half-wave (b) and the second positive half-wave (c). Accordingly, the circuit arrangements according to FIGS . 13 and 14 are also suitable for monitoring the fence current (Iz).

The circuit arrangement ( 10 ) is connected to a measuring resistor (Rm), via which either the primary current (Ip) (see FIG. 1) or the fence current (Iz) (see. FIG. 2, FIG. 3) flows. An input of a comparator ( 11 ) is connected to the measuring resistor (Rm) and is formed, for example, by an operational amplifier as a threshold switch. A threshold voltage (Us) is applied to the other input of the comparator ( 11 ). On the output side there is a timing element ( 12 ) and an AND gate ( 13 ) on the comparator ( 11 ). The timer (12) is also connected to the AND gate (13) and overlying an RC element consisting of a capacitor (C 1) and a resistor (R 1) to a reset input (R) to a memory member (14), which is formed, for example, by a flip-flop. The AND gate ( 13 ) is located at its set input (S). Its Q output is connected to a display device ( 15 ), for example an illuminated display.

The RC element (R 1 , C 1 ) generates a differentiated pulse, which resets the memory element ( 14 ) at the beginning of each fence pulse, at which the threshold value (Us). Without the RC element (R 1 , C 1 ), "H" signals can be present at the reset input (R) and at the set input (S) at the same time and thus lead to a malfunction of the memory element ( 14 ).

The timer ( 12 ) creates a measurement window within which an event must take place. When the threshold value (Us) on the comparator ( 11 ) is exceeded, it switches to "L" and thus starts the timer ( 12 ), the output of which then becomes "H" for the time (tm). If the state of the comparator output changes during the time (tm), this has no influence on the time (tm). The timer is therefore "not retriggerable". After the time (tm) the output of the timer ( 12 ) becomes "L". If the comparator output is "L" beyond the time (tm), then the output of the timing element ( 12 ) remains "H" for as long.

The mode of operation of the circuit arrangement according to FIG. 12 is approximately as follows:

At the time (t 0 ) - at the beginning of the herding pulse (see FIG. 4, FIG. 5), the measurement voltage (Um) derived from the primary current or fence current exceeds the threshold voltage (Us). As a result, the non-retriggerable timer ( 12 ) is started for a time (tm) that forms a normal value for the undisturbed fence state. The time (tm) is such that it is longer than the time between the times (t 0 and t 1 ) (cf. FIGS. 4, 5), the time (t 1 ) being the time at which the first Half wave (a) in the undisturbed state falls below the threshold value (Us) again. In any case, the time (tm) is shorter than the time between the time (t 0 ) and the time (t 2 ) (cf. FIG. 4) in which the first half-wave (a) falls below the switching threshold (Us) in the disturbed state .

Simultaneously with the start of the timing element ( 12 ), the memory element ( 14 ) is reset via its reset input (R) via the timing element ( 12 ) and the RC element (C 1 , R 1 ). As a result, the display device ( 15 ) initially lights up per se. However, this alone does not form the actual signal for a faulty condition of the pasture fence ( 8 ).

In the case of an undisturbed, high-resistance fence, the first current half-wave (a) and thus the measurement voltage (Um) falls below the voltage threshold value (Us). This time (t 1 ) is within the time period (tm) of the timer ( 12 ). At time (t 1 ) the comparator output is "H" and the AND gate ( 13 ) sets the memory element ( 14 ) via its input (S), so that after this short time, for example 0.05 ms, the display device ( 15 ) goes out. During this short period of time, the lighting of the display is not perceived as a signal. However, it can be used for a test of the function of the circuit arrangement.

The memory element ( 14 ) remains set until - after, for example, 1.2 s - the next herding pulse occurs.

However, if the pasture fence ( 8 ) has a low resistance, then the primary current (Ip) or the fence current (Iz) and thus the measuring voltage (Um) does not fall below the threshold voltage (Us) within the time period (tm) of the timer ( 12 ), then lies at the end of the time period (tm) at the output of the timer ( 12 ) and thus at one input of the AND gate ( 13 ) "L" potential, so that the memory is not set via its set input (S) even if later "H" potential occurs at the time (t 2 ) at the output of the comparator ( 11 ). The memory element ( 14 ) is therefore not set, so that the display device ( 15 ) continues to light up. The user receives a signal that the pasture fence ( 8 ) has a low resistance, for example because it is disturbed by touching the ground.

In the circuit arrangement according to FIG. 13, which monitors not only the half-wave (a) but also the half-wave (b), comparators ( 16 , 17 ) are provided in addition to the circuit arrangement according to FIG. 12, one of which has inputs at the measuring resistor (Rm) lie. The other input of the comparator ( 16 ) is connected to a further threshold voltage (Us2). The other input of the comparator ( 17 ) is connected to a further threshold voltage (Us1). Another comparator ( 18 ) is connected downstream of the comparator ( 17 ) and is set to a time duration (tu). Its output is connected to an AND gate ( 19 ), on which the comparator ( 16 ) is also located. The AND gate ( 19 ) lies together with the AND gate ( 13 ) via an OR gate ( 20 ) on the memory element ( 14 ).

The timer ( 18 ), like the timer ( 12 ) described above, cannot be retriggered. When the threshold value (Us1) on the comparator ( 17 ) is exceeded, the comparator switches to "L" and starts the timer ( 18 ) with the time (tu). The time (tu) is dimensioned such that it is longer than the time between the times (t 01 and t 4 ) (cf. FIG. 7), where t 01 is the time at which the first half-wave (a) occurs high capacity - i.e. long fence - exceeds the threshold (Us1). t4 is the time when the negative half wave (b) becomes "0". The time (tu) is thus measured so that it is long enough to make an optical or acoustic signal clearly recognizable for the user, but ends before the next herding pulse occurs.

The additional mode of action is essential the following:

In the case of a high-resistance fence of very large capacity (cf. FIG. 7), the threshold value (Us) is not undershot during the time (tm), the memory ( 14 ) is not set, and since the display continues to light up, an incorrect display would occur. However, this is prevented by the circuit expansion according to FIG. 13.

At time (t 01 ), the positive half-wave (a) exceeds the threshold value (Us1) of the comparator ( 17 ), so that the timer ( 18 ) is started with the time (tu). At time (t 3 ), due to the high-impedance fence, the negative half-wave (b) of the primary current (Ip) exceeds the threshold value (Us2), and the output of the comparator ( 16 ) becomes "H" within the time (tu). As a result, the condition of the AND gate ( 19 ) is fulfilled and the memory element ( 14 ) is set via the OR gate ( 20 ), so that the display device ( 15 ) goes out.

This short glow of the display device ( 15 ) is barely perceptible to the user, but can be used for test purposes. If the display device ( 15 ) does not light up, the user is informed that the pasture fence ( 8 ), which has a high capacity (C), for example 0.5 F to 1 F, is undisturbed.

If, on the other hand, the pasture fence ( 8 ) has a low resistance, ie is disturbed, the threshold value (Us2) of the comparator ( 16 ) is not reached during the period (Tu) of the further timing element ( 18 ). The memory element ( 14 ) thus remains reset, so that the display device ( 15 ) continues to light until a new herding pulse occurs.

This circuit device is therefore suitable for monitoring both a short and a long pasture fence. The same applies to the circuit arrangement according to FIG. 14.

In the circuit arrangement according to FIG. 14, in addition to the comparator ( 11 ), a further comparator ( 21 ) is provided, on which a threshold voltage (Us3) is applied. On the output side, the comparator ( 21 ) and not the comparator ( 11 ) is located on the AND gate ( 13 ). The RC element is located at the output of the comparator ( 11 ).

In this circuit arrangement, the primary current (Ip) or the secondary current (Iz) is additionally monitored for the second positive half-wave (c). The display device ( 15 ) remains illuminated only when the second positive half-wave (c) does not exceed the threshold value (Us3).

The mode of action is as follows:

At time (t 0 ) the threshold voltage (Us) is exceeded (cf. FIGS. 5, 7), the output of the comparator ( 11 ) becomes "H" and the RC element (C 1 , R 1 ) becomes the storage element ( 14 ) reset via its reset input (R). As a result, the display device ( 15 ) initially lights up per se. However, this alone does not form the actual signal for a faulty condition of the pasture fence ( 8 ).

At time (t 1 ) (cf. FIGS. 5, 7) the threshold voltage (Us) is undershot, the output of the comparator becomes "L" and thereby starts the timer ( 12 ), the output of which for time (tm 1 ) " H "is. The time (tm 1 ) is measured from the time (t 1 ) to the time (t 6 ), where t 1 is the time at which the half-wave (a) falls below the threshold value (Us) in the undisturbed state and t 6 is the time to which the primary current (Ip) or the fence current (Iz) has decayed in the disturbed as well as in the undisturbed state.

For the function of the circuit arrangement, it is irrelevant whether the RC element (C 1 , R 1 ) is connected to the output of the comparator ( 11 ) or to the output of the timing element ( 12 ). In the first case, the memory element ( 14 ) is reset at time (t 0 ), in the other case at time (t 1 ).

In the case of the undisturbed high-resistance fence, the threshold (Us3) is exceeded at time (t 5 ) (cf. FIGS. 5, 7), the output of the comparator ( 21 ) becomes "H", and the condition of the AND gate ( 13 ) is fulfilled and via its output the memory element ( 14 ) is set via its input (S), so that the display device ( 15 ) now goes out after this short time.

The threshold value (Us3) is dimensioned such that it is not reached by the amplitude of the positive half-wave (a) with a fence load (see FIG. 5), but by the amplitude of the positive half-wave (a) (see FIG. 4) , 6) and the second positive half-wave (c) (cf. FIGS. 5, 7) is exceeded.

In the disturbed, low-resistance state, the primary current (Ip) of the second positive half-wave remains below the threshold voltage (Us3) (see FIGS. 4, 6), so that during the time (tm 1 ) the output of the comparator ( 21 ) does not "H "and thus the memory ( 14 ) is not set and the display device ( 15 ) continues to light.

For dimensioning the switching thresholds or Threshold values (Us, Us1, Us2) can be summarized hold tight:

The threshold value (Us) is such that it is exceeded by the amplitude of the positive half-wave (a) of the primary current (Ip) when the electric fence device is loaded with the fence (fence load) (cf. FIG. 5).

The threshold value (Us1) can be measured differently. To detect the capacitive fence load and its display, the threshold value (Us1) is dimensioned such that the amplitude of the positive half-wave (a) of the primary current (Ip) is not exceeded for a fence load in accordance with FIG. 4, but for a fence load in accordance with FIG . the primary current (Ip) is exceeded 6 on the amplitude of the positive half wave (a). The message "capacitive fence" is made by evaluating the switching state of the timer ( 18 ), which is followed by a switching stage, not shown.

If the message "capacitive fence" is omitted, then the threshold values (Us, Us1) can be dimensioned the same. The comparator ( 17 ) can then be omitted. The further timer ( 18 ) is then started by the comparator ( 11 ) as soon as its switching threshold (Us) is exceeded.

The threshold (Us2) is dimensioned such that it b not exceeded at a fence load according to Fig. 6 of the amplitude of the negative half-cycle (b) of the primary current (Ip) and at a fencing load claimed FIG. 7 of the amplitude of the negative half-cycle ( ) of the primary current (Ip) is exceeded. The specified threshold values also apply to the fence current (Iz).

Within the specified range, the Thresholds are varied, thereby reducing the Circuit arrangement to the conditions in the field on which the pasture fence is installed, can be adjusted.

Claims (11)

1.Circuit arrangement for monitoring a pasture fence, which is cyclically acted on by an electric fence device, in particular having a low output impedance, with herding pulses, with an evaluation circuit and a display device which emits a signal when the pasture fence is disturbed, characterized in that the circuit arrangement ( 10 ) detects those current and / or voltage fluctuations which, depending on the state of the pasture fence ( 8 ) on this or on the electric fence device ( 1 ), vary in response to a herding impulse that the evaluation circuit has one or more characteristic values (t 0 to t 1 ) compares at least one of the half-waves (a, b, c) of the vibrations with one or more normal values (tm, tu), which is or are maintained in the undisturbed state of the pasture fence ( 8 ), and that the evaluation circuit ( 11 to 14 ) the display device ( 15 ) in the event of a deviation of the characteristic value or values from the assigned normal value or the assigned normal values for emitting the signal. 2. Circuit arrangement according to claim 1, characterized in that the evaluation circuit ( 11 to 14 ) compares at least one of the half-waves (a) by means of a timing element ( 12 ) with a normal time value, which at a specific current or voltage threshold value (Us) is present. 3. Circuit arrangement according to claim 1 or 2, characterized in that the normal value is set so that the display device ( 15 ) emits the signal at a low-impedance against the undisturbed state pasture fence ( 8 ). 4. Circuit arrangement according to one of the preceding claims, characterized in that the evaluation circuit ( 11 to 14 ) a first on the pasture fence ( 8 ) or in the electric fence device ( 1 ) occurring positive current half-wave (a) by means of a comparator ( 11 ) and a timing element ( 12 ) which starts for the duration of a time normal value (tm) when a threshold value is exceeded at the comparator ( 11 ) and that the evaluation circuit ( 11 to 14 ) controls the display device ( 15 ) to emit the signal when this half-wave ( a) - with a disturbed, low-resistance pasture fence ( 8 ) - lasts longer than with an undisturbed, high-resistance pasture fence ( 8 ). 5. Circuit arrangement according to one of the preceding claims, in particular claim 4, characterized in that the evaluation circuit ( 11 to 14 , 16 to 20 ) following the first positive current half-wave (a) negative current half-wave (b) by means of a further comparator ( 17 ) and evaluates a further timing element ( 18 ) which starts for the duration of a time normal value (tu) when a threshold value (Us1) has been exceeded at the further comparator ( 17 ) and that the evaluation circuit controls the display device ( 15 ) to emit the signal, if the negative half-wave (b) does not exceed another threshold value (Us2). 6. Circuit arrangement according to one of the preceding claims, characterized in that the evaluation circuit evaluates a second positive current half-wave (c) by means of a further comparator ( 21 ) and controls the display device ( 15 ) for emitting the signal when the second positive half-wave (c) does not occur. 7. Circuit arrangement according to one of the preceding claims, characterized in that the evaluation circuit ( 11 to 14 ) has a memory element ( 14 ) which controls the display device ( 15 ) and which via the comparator ( 11 ) at every first positive current half-wave (a) a herding pulse is reset, and that the memory element ( 14 ) is set afterwards in the undisturbed state of the pasture fence ( 8 ) and remains set until the next herding impulse and the memory element ( 14 ) remains reset when the pasture fence ( 8 ) is in a disturbed state. 8. Circuit arrangement according to one of the preceding claims, characterized in that the evaluation of the current half-waves (a) or the current half-waves (a, b, c) of the primary current (Ip) of the energizer ( 1 ) or the fence current (Iz) via a measuring resistor (Rm) takes place. 9. Circuit arrangement according to claim 8, characterized in that the measuring resistor (Rm) is located at one input of a comparator ( 11 ), at the other input of which a threshold value (Us) is set, that the comparator ( 11 ) has a timer ( 12 ) on the output side. and an AND gate ( 13 ) is connected, at the other input of which the timing element ( 12 ) is connected, that the AND gate ( 13 ) is located at the set input (S) of a memory element ( 14 ) whose reset input (R) is via an RC Member (C 1 , R 1 ) is connected to the timing element ( 12 ), and that the storage element ( 14 ) is followed by the display device ( 15 ). 10. Circuit arrangement according to claim 8 and 9, characterized in that the AND gate ( 13 ) via an OR gate ( 20 ) at the set input (S) of the memory element ( 14 ) is that the OR gate ( 20 ) another The AND gate ( 19 ) is connected to which a further comparator ( 16 ) and a further comparator ( 17 ) are connected via a further timer ( 18 ), and that the further comparators ( 16 , 17 ) are connected on the one hand to the measuring resistor (Rm) and on the other hand are due to further threshold values (Us2, Us1). 11. Circuit arrangement according to claim 8, characterized in that the measuring resistor (Rm) is at one input of a comparator ( 11 ), at the other input a threshold value (Us) is set, that the comparator ( 11 ) on the output side of a timing element ( 12th 1) connected to the reset input (R) of a memory element (14)) and via an RC element (C1, R, that the timer (14) via an aND gate (13) to the set input (S) of the memory element ( 14 ) is that another comparator ( 21 ) is connected to the other input of the AND gate ( 13 ), which is connected on the input side to the measuring resistor (Rm) and to another threshold value (Us3), and that the memory element ( 14 ) the display device ( 15 ) is connected downstream.