DK172169B1 - Apparatus for testing the earth connection of an electric fence - Google Patents

Description

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1 DK 172169 B1

The present invention relates to a soil testing apparatus for electric fencing.

The wiring in an electric fence usually includes one or more fence wires, an electric power supply unit or control means, and a return connection through ground. The fence wire is provided as an uninsulated electrical conductor, which is supplied by the power supply unit, which is connected to both an electrical power source, usually 230 V power supply network, and the nearest end of the fence wire, the power supply unit acting by changing the AC supply voltage to a pulsed voltage supply. The power supply unit is connected to the conductive fencing wire, and the return connection is usually provided through ground, although systems providing a return conductor as grounding are not unknown.

The simplified impedance network in the fence circuit includes a first series impedance (with reference numeral Z) representing the impedance in the actual 20 fence wire, a second shunt impedance (referred to as Zp) representing the shunt impedance between fences and ground, and a third series impedance ( with reference numeral Z £) which represents the impedance of the return connection through ground. It is desirable that the impedances ZL and Zp be very small relative to the shunt impedance

Zp, so that a maximum voltage drop across Zp is obtained, i.e. from fence to ground, with minimal voltage losses across the fence wire impedance Zp and over the ground impedance Zp. Of the latter two impedances, the last, 30 ZE, is the impedance which is most frequently subjected to an increase due to faults in the grounding system and related faults.

The ground impedance includes two series components: the actual impedance through the ground layer, ie. the impedance of 35 2 DK 172169 B1

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the ground layers by which a return connection is provided and the conduction impedance, i.e. the impedance of the ground conductor which provides electrical connection to the ground layer up to or in the area of the power supply unit. This ground conductor generally includes a number of posts which are inserted into the ground layers to provide an electrical connection therewith. The posts are electrically interconnected with wires, such as. fence wire, and are also connected to the power supply unit. The 10 best, ie. the least possible impedance to ground is obtained when the posts are placed in a humid ground area, thus being often spaced from the power supply unit. Nonetheless, earthing of the kind mentioned here, which is the most common, is particularly prone to defect, and it is equally important that the grounding be tested at regular intervals to ensure that the electric fence works correctly. For example, the connection to ground or another part of the ground system becomes defective, so as the impedance in the system increases, a greater part of the electrical voltage provided by the fence power supply unit will lie above the ground system, so that a smaller portion of the voltage drop reaches an animal. during operation of the fence provides connection between the ground and the fence, will exceed 25 animals, which will receive a correspondingly less electrical impact. If the soil system is severely damaged, this could mean that the fence is completely ineffective, which will allow the livestock stock to spread. Mistakes can be caused by changes in weather and condition of the soil layer, or by vegetation touching the fence wire, by changes in the pattern after which the fence is set up, where the fence includes a number of separate fence wires, by temporarily deteriorating components, etc.

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The usual method of testing electrical fencing grounding is to establish an immediate short circuit of the fence between ground and fence, with the fence wire and ground simultaneously being touched manually. If an electric shock is detected, the ground connection is considered insufficient, proving that the fence wire has a higher potential than the ground potential, regardless of the provision of the short circuit. The short circuit generally includes a few profile irons 10 which are mounted against the fence. The manner of this test procedure is largely insufficient, and in addition it is required that the person performing the test remembers to perform the test regularly. The test is based on the recording of a ground voltage to indicate a faulty ground connection, and since this is done by touch, the registration is unreliable. There is also a tendency on the part of the person making the tests to consider a single positive sample as a suitable indication that the soil system is functioning satisfactorily and that it will continue to do so for the rest of the life of the network.

From FR-Al 79 14190 an alarm system is known, which means that

grounding in an electric fence is monitored. In this system, a measurement is made of the voltage across the output terminal of the power supply and the grounding of the electric fence. 25 WO-A1 82/00936 also mentions an alarm system for testing, among other things. the grounding in an electric fence by measuring the voltage across the output terminals over the power supply, and the current in the electric fence by measuring voltage across two resistors inserted in the fence's connection 30 from the power supply to ground.

Said alarm systems can generally be referred to as internal systems which measure currents and the voltage in the ground relative to currents and voltages supplied to the system.

Thus, changes in grounding which are offset by changes in the power supply will not be recorded, for which an absolute size measurement is needed.

The object of the present invention is thus to provide an apparatus for testing the condition of the earth return system in an electric fence grid by an absolute measurement.

The stated object is achieved with an apparatus of the kind referred to in the preamble, which according to the invention is characterized by the design according to the characterizing part of claim 1.

10 The electric fence ground test device is designed to compare the potential difference between said ground return system in the electric fence with a secure ground connection.

It is preferred that the testing apparatus include an indicator for providing a quantitative representation of the potential difference between the fence's grounding and the safe grounding, and this indicator could suitably be a voltage input with differential input.

It is envisaged that the ground test apparatus could most conveniently be placed in a system with an electric fence and a power supply unit with one of the indicator's inputs connected to a fence ground terminal screw on the power supply unit and the other input of the indicator connected to a secure ground input on the power supply unit. .

By the term "safe soil" is meant, e.g. the ground connection or the zero wire in the power supply network, or the like, or any other ground connection, of which it is known that it is not thrown during variations of the ground protection, etc.

The invention provides an apparatus which monitors, more safely than in the prior art, the state of voltage in electric fences.

35 The apparatus for testing grounding of the invention is described in the following with reference to the drawing, in which: FIG. 1 is a diagram of the theoretical impedance network in an electric fence;

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DK 172169 B1 fig. Figure 2 is a block diagram of the preferred embodiment of the earth test apparatus provided by the invention; 3 is a circuit diagram of the preferred embodiment of the earth test device provided by the invention.

FIG. 1 shows the theoretical impedance grid in an electric fence. The grid includes the series impedance Z_ in the fence discharge and the ground return impedance ZE, as well as the 10 previously mentioned shunt impedance in the fence Zp. Under normal circumstances, Z and Z will be small and Z_ will be higher so that practically all of the output voltage from the power supply unit is above Z. When an animal standing on the ground, thereby establishing grounding, touches the fence, the fence impedance Zp is effectively short-circuited so that it then acts as the largest impedance component of the fence grid, so that virtually the entire power supply unit voltage is above this impedance component. Accordingly, the animal is subjected to an electric shock.

However, if the magnitude of the ground impedance Z_ increases significantly if, for example, the ground system becomes defective, a significant portion of the available voltage drop is due to an animal's touch of the fence and short circuit of the impedance Z, Γ above the ground impedance Z, such that the animal will be on-

G

printed a small shock. In the worst case, when the impedance of the faulty grounding is very large, the animal will receive only a very small, if at all, 30 surges.

In the invention, a test voltage VT is measured between ground and the return terminal of the fence power supply unit and a safe ground, such as the ground line or zero line in the 230 V power supply, as shown. Theoretically, the earth potentials for the fence and for the power supply

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DK 172169 B1 6 networks are the same so that there is no potential difference or voltage drop between them.

In practice, however, due to the inevitable increase in impedance in soil and return systems,. be a potential difference between the two earth connections.

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The soil testing apparatus provided by the invention is designed so that it can monitor the sample potential difference VT in such a way that if the potential difference becomes greater than a predetermined value, this will be recorded 0, indicating that the fence's soil return system is defective.

FIG. 2 is a block diagram of a preferred embodiment of the grounding test apparatus provided by the invention, which apparatus mentioned earlier is best suited to be inserted into an otherwise known electric fence power supply unit (although the grounding test apparatus could be provided as a separate portable unit, if predetermined). The ground input stage of the test apparatus includes isolation capacitors and C .g. a digital display means, a column display means with light emitting diodes, or indicators of the light emitting diodes or similar means (or the "display means" could even be provided as a printer), so that the quantitative magnitude of the potential difference between the fence grounding and a safe grounding, the latter also being provided to the indicator DIVI through the switch Si. It would be appropriate if the testing apparatus was located in a power supply unit, with

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The display means is included in the housing of the power supply unit so that the grounding status of the fence can be easily detected.

As previously mentioned, the voltage across the electric fence provided by the power supply unit is a pulsating voltage, so that any voltage drop across the ground system will be pulsating. Accordingly, the preferred embodiment of the testing apparatus includes a device PVMME for recording voltage maxima for monitoring variations in the ground's fencing, safe ground potential differences, and for recording the voltage peak level herein. This includes a suitable sample and retention circuit, whereby the 15 worst sample voltage levels are recorded and continuously updated. Thus, in the preferred embodiment of the invention, the worst test voltage will always be displayed, or will be available for display by the DIVI indicator, which would otherwise exhibit ground fluctuations as they are provided, which will only be displayed during each voltage pulse duration.

In the preferred embodiment of the invention, the testing apparatus is provided with a switch so that the potential difference between the output terminals of the power supply can be measured. In connection therewith, the testing apparatus includes a fence input stage with the insulation capacitors and, and the calibration resistance ϊ ^, which is connected to the fence terminal ΕΤρ of the power supply unit 30. This fence input stage can be connected to the differential input indicator DIVI through the switch SI as shown. If the grounding state is to be detected, the switch S1 is inserted into the position shown in FIG. 2 so that the fence voltage is shorted to the safe ground through

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And so that the potential of the safe ground will be transmitted to the input terminal of the indicator DIVI for comparison with the ground potential of the fence.

When the fence voltage is to be detected, the switch S1 moves into its opposite position, as shown punctured, so that the safe ground is no longer connected to the indicator and no longer shortens the fence voltage and so that the fence voltage is transmitted to the input of the indicator. Comparison with the fence's ground connection, whereby the indicator DIVI shows the available fence voltage. A means PVMMp for recording voltage maxima is again included in the fence voltage input stage.

FIG. 3 shows the overall circuit in the preferred embodiment of the earth test apparatus provided by the invention. The ground and fence input stages include the capacitors and resistors R1 and R5, the steps being constructed as shown in FIG. 2. Means PVMMEp and PVMMp for recording 20 ground voltage maxima and fence voltage maxima, respectively, are shown including the components framed in dotted lines, which also applies to the switch S ^. The DIVI indicator is shown as before.

The organs PVMMp and PVMMp for recording voltage maxima in the ground voltage and the fence voltage include the input operation amplifiers 0A1 and 0A2 and the diodes D1 and D2, constructed as shown, so that only positive and negative input pulses respectively can be continued. The capacitor and resistor R 1, respectively 30 Cg, and resistor R 1 are each provided as CR-circuits and the time constants of these circuits are such that some degree of equalization of successive impulses is provided, while the input stages can still be updated. rapidly when significant variations in the input pulse levels occur. The input pulses are transmitted through the electronic switches S2 and S3 to the input 172169 B1 9

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the storage capacitors CS1 and CSg, which act by storing the peak levels of the pulses. The charge stored in the capacitors CS7 and CSg can be "read" by the differential input voltage indicator DIVI at the appropriate setting of SI, as previously mentioned. Hegnsindgangsspæn-

D

the thing is passed through the resistor R ^, as previously mentioned, 'and the ground voltage through the operational amplifier OAg.

The operational amplifier OA ^ is provided as a comparator such that it converts the electronic switches S2 and S3 which it controls when the pulses are taken out, so that the level of the input pulses is recorded in the storage capacitors CS1 and CSg. When a fence voltage pulse exceeds a level provided by the voltage components built up by resistors Rg and R4, switches S2 and Sg are activated from OA2, whereby the voltage levels on the storage capacitor CSy and CSg can be updated, respectively. Resistor Rg is provided as shown, so that the ground voltage readings are updated even though the fence wire is shorted 20 to ground.

While switches S1 may be provided as any suitable switch, the switch in the preferred embodiment of the invention is of a type where manual capacity increase is provided, i.e., the switch is actuated by the user placing his finger on a switch plate. This kind of switches is provided with the plate recessed into the power supply housing because it is resistant to climatic influences. A manually operated switch must, over time, be assumed to be affected by wind and rain. The front plate of the switch is indicated by FPS1. The structure shown is such that the switch Si is normally in such a position that the safe ground is connected to the indicator DIVI.

35 10 DK 172169 B1 o

By activating the switch plate FPS1, the position of the SI changes, so that the fence voltage will be displayed on the indicator DIVI. The increased capacity of the switch plate FPS1 affects the output of NOT AND-PORT 5 G1 such that it shifts, thereby providing a shift in the JK multivibrator FF1, which in turn affects switch SI to switch. Gate G is provided with a DC feedback loop built up by resistors 1 * 12 'R13 ° 9 ** 14 capacitor Cg, which loop is constructed such that the state at the output of gate G1 is controlled by an oscillator built by NOT AND G2 and the resistor R ^ and the capacitor Cll 'as v ^ st * Un <^ are normal circumstances, the output of the gate Gi constantly switches between high and low. The G-15 entrance is kept low. The multivibrator (FF1) usually stays in one position. When the switch plate FPS1 is activated, the added capacity is such that the output of the oscillator provided at the gate G2 can no longer read the threshold value of G1, so its output will switch to high until its bias provided by its DC voltage feedback. loop, is changed so that the gate GI1's oscillations are resumed. However, the time constant in the DC feedback loop is such that a suitable time is provided for the capacitor C ^ to be charged through resistor R ^ g to the threshold level of NOT AND PORT G3, so the gate changes state accordingly. AND THE POP G4 and consequently on the multivibrator FF1, the switch S1 being rescheduled.

When the oscillations in gate G are resumed, capacitor C12 is discharged through diode D3 and the circuit assumes its original state, which will not change until the switch plate is actuated again.

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u DK 172169 B1

The position of switch SI, and thus the magnitude, either the voltage between fence ground and safe ground or the fence voltage shown on the indicator DIVI, is indicated by two light emitting diodes D4 and D5, which are driven directly from the multivibrator FF2 through resistors R ^ and R ^ g. , which in turn is operated by the multivibrator FF1.

Activation of the switch plate FPS1 thus causes a switching of the switch SI such that if e.g. If the potential difference was between fence soil and safe soil, the fence voltage would be shown and implemented. This size will continue to be displayed until the switch plate FPS1 is reactivated and the size displayed by the light emitting diodes and Dg.

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Claims (8)

12 DK 172169 B1 O Patent claims. An earth test device for recording the condition of an earth return system in an electric fence network, characterized in that the test device is designed to provide a comparison between the potential difference between the earth return system in the electric fence and a secure ground connection thereby: there is provided a voltage difference meter (PVMMp "PVMMe)" whose one input is connected to the fence terminal (ETp) of the power supply unit and the other of which is connected to the ground terminal (ETE) of the power supply unit and where an indicator (DIVI) is connected to the output of voltage difference meter (PVMMp, PVMMp). An earth test device according to claim 1, characterized in that the indicator (DIVI) produces a quantitative display of the potential difference between fence ground and safe ground. 20 An earth test device according to claim 2, characterized in that the indicator (DIVI) is a differential input voltage indicator. An earth test device according to claims 1 to 3, characterized in that the device 25 is included in an electric fence power supply unit. 5. An earth test device according to claim 4, characterized in that the input terminal of the safe ground is the power supply unit's connection 30 to the electrical supply network's ground wire or 0 wire. An earth test device according to claims 1-5, characterized by including a means (PVMMp, PVMMp) for recording voltage maxima, designed to monitor variations in the potential difference between fence ground and safe ground, and record increases in the maximum level thereof. 35 DK 172169 B1 o An earth test device according to claims 1-6, characterized in that switches (¾) can be made for comparing the potential differences between the live fencing wire in an electric fence network and the network fence ground. An earth test device according to claim 7, characterized in that the indicator (DIVI) 10 is designed to show the potential difference between the live fence wire and the fence ground when the earth test device is adjusted for this. 15 20 25 30 35