FR2709225A1 - Electric fence apparatus. - Google Patents

Abstract

The invention relates to an apparatus for an electric fence comprising a smoothing capacitor (C1) and a switch (4) synchronized by a timer (T), which discharges the smoothing capacitor (C1), which is charged by a converter, via a fence transformer (3) to an electric fence which is connected to it on the secondary side. Device for electric fencing, characterized by a sensor (S) which senses the electric current or the voltage or a combination of both after a discharge pulse, this information being analyzed in a control element (St) mounted downstream so as to determine the nature and degree of charge of the fence, and the synchronized switch (4) being interrupted during the discharge process according to the charge of the fence when the energy in discharge has reached a previously given value.

Description

Description

  The present invention relates to an electric fence apparatus which is especially used in association with pasture fences. It presents a smoothing capacitor and a timer-synchronized switch, which discharges the smoothing capacitor, which is loaded by a converter, via a

  fence transformer to an electric fence connected to it on the secondary side.

  In general, when the device is controlled by battery or accumulator, the converter is a DC / DC converter, in the case of a device connected to the mains, it is usually a voltage doubler coupling comprising a rectifier. However, the concept of converter is not limited to the forms of

realization mentioned above.

  For example, there are known devices for electric fence of this

  kind by the documents DE 27 33 145 C2 and DE 30 09 838 C2.

  The purpose of the devices described above is primarily to save energy, while ensuring that animals are kept as well as possible. The problem of energy becomes obvious when one thinks that, in the countryside, electric fence devices are often not connected to the power supply network but

are powered by a battery.

  An internationally valid regulation sets a range of maximum values for voltage, pulse duration, maximum current per pulse, maximum discharge energy (see European Standard EN 61011). Each determined value is valid for the (animal) contact. Thus, the above-mentioned standard fixes the maximum value of the pulse voltage at around 10000 volts, the maximum duration of the pulse at 0.1 s, the maximum quantity of current per pulse at 2.5 mC, the maximum energy in impulse discharge at 5.0 J, the maximum intensity of the current at 10 A and finally imposes the duration during which the instantaneous value of the intensity of the current is

  greater than 300 mA does not exceed 1.5 ms.

  In practice, electric or pasture fences are subject to various operating conditions. In the ideal situation, the fence is without vegetation, with leakage resistances of the order of 100 kΩ or lying in the

domain of MQ.

  If the body of an animal comes into contact with the fence, it is estimated that the leakage resistance is 500 ohms. This corresponds to the situation in which the

  fence must fulfill its true function and develop its barrier effect.

  An electric fence with lots of vegetation such as grasses or bushes etc. has resistance values of the order of some 100 ohms. This shows the vast area in which the electric fence device that controls the fence must operate. In the past, attempts have been made to respect several operating points

  tolerated by the limit values by making more or less compromises.

  For safety reasons, we have always stayed well below the values allowed by the standards, for example with regard to the tension at the fence. This is because an allowable peak voltage of 10,000 volts for a fence without vegetation could never be reached without further action when the fence is vegetated, as the vegetation ensures the passage of the vegetation. much of the current from the fence to the ground. Conversely, it would of course be totally unacceptable to realize the electric fence device so that the 10000 volts are reached when the fence has a lot of vegetation. Without taking countermeasures, there would be a risk

  major electrocution at the fence if the vegetation disappeared.

  Therefore, for safety reasons, much of the potential of electric fencing that would still fall within the European standard is

  not exploited by traditional devices.

  More recently, however, there have been some attempts to solve this problem. Examples of such documents are EP O 543 621 A1 and DE 41 40 628 A1. All of these documents essentially describe an electric fence apparatus comprising a measuring member which captures an average value of the voltage of each pulse. in the fence. The measuring member is connected to a control element which in a certain way controls a charging circuit which actuates the smoothing capacitor. Thus, when the average value of the voltage is relatively high, it is assumed that the impedance of the fence is high and that it is therefore free or almost free of vegetation. Accordingly, the charging circuit is instructed to charge the smoothing capacitor with a charging voltage whose peak value is low. In the opposite case, so when the impedance of the fence is low (a lot of vegetation), we apply to the capacitor a voltage of

  load whose peak value is high.

  Unlike the operation of older devices, this way of proceeding allows to occupy almost entirely the framework released by the European standard, within which the operation is authorized. In other words, as explained above, this is achieved by the fact that the state of the fence is determined by a measurement and that the smoothing capacitor is loaded with a higher or lower voltage, in accordance with the state of the fence. Devices of this type are qualified as so-called intelligent devices, in so far as they can adapt their mode of operation to the state of the fence, which older devices could not

not to do.

  Although these devices are already well advanced, they have a serious disadvantage. Thus, the realization of the charging circuit for the smoothing capacitor C1 is technically very complex, and this, because the voltage level must vary very strongly. In the case of this type of energy regulation, the output of the converter mounted upstream must necessarily vary greatly, and optimal and constant adaptation of the converter is impossible, which increases the power consumption provided by the energy source. (battery / accumulator, mains). In view of this background, the object of the present invention is to remedy this defect of electric fence devices known. It is therefore necessary to create an electric fence device which adapts its mode of operation to each

  state of the fence, but avoids unnecessary power consumption.

  This object is achieved by an electric fence apparatus of the kind mentioned in the introduction, in which a sensor captures the electric current or the voltage or the combination of the two, this information being analyzed in a control element mounted downstream in such a manner. that the nature and degree of charge of the fence are determined, and the synchronized switch is open during the discharge process as a function of the load of the fence when the energy discharge has reached a previously given value. This instant is determined by the leakage resistance at the fence, which is transmitted by the sensor and, if appropriate, also by a previously given energy profile, which can be advantageously stored in a microprocessor, knowing that C1 sends by pulses a certain amount of energy previously defined according to the

leakage resistance.

  Unlike the electric fence apparatus according to DE 41 40 628 A1 for example, the smoothing capacitor is, in this case, always loaded at the same load voltage value, preferably at the maximum value, and this , for each determined state of the fence. According to the invention, the moment when the synchronized switch, for example a thyristor, is interrupted is controlled. Because C1 is always charged to the same voltage, the upstream converter, which converts the low supply voltage of 9 V into a voltage of about 300-400 volts for example, can be optimally designed. In this regard, it should be noted that the efficiency of the converter significantly influences the power consumption of the device. But besides the energy of the pulse, the power consumption is the reference quantity to evaluate an electric fence device, since it simultaneously determines the duration of use of the energy source such as the battery or the accumulator. The large variations in the output voltage of the converter of the previously known devices (according to DE 41 40 628 A1 or EP 0 543 621 A2) considerably reduce the efficiency of the converter and thus cause an unnecessarily high current consumption which the proposal according to the invention makes possible. avoid. In the case of devices connected to the mains, the smoothing capacitor C1 of the apparatus according to the invention can be connected directly or - as mentioned previously - through a voltage doubler coupling. On the other hand, in the case of the previously known process, it is necessary to provide a regulation loop between the

  sector and the smoothing capacitor because of the different voltage levels in C1.

  The fence apparatus according to the invention thus makes it possible to optimally exploit the "opening" provided by the European standard for the operation of such appliances and to ensure their effectiveness, while respecting the

safety requirements.

  The evoked sensor can be in the primary circuit of the transformer of the fence and be advantageously realized in the transformer in

  as a measuring coil having a small winding.

  But the sensor can also be located in the secondary circuit of the fence transformer. The sensor can then be advantageously mounted in parallel with respect to the impedance of the fence, or else be mounted in series, the impedance of the fence being usually represented by an ohmic resistance

and a capacitive element.

  According to a particularly advantageous improvement, the control element of the apparatus contains a microprocessor with memory. A different distribution profile of the discharge energy than the European standard NE 61011 can be stored in the memory. Depending on the load of the fence, the microprocessor can control a distribution profile of the discharge energy stored in the memory. It is therefore possible to literally "run" an energy distribution profile for each application case when the device is running or

  to adapt in a simple way the device to possible modifications of the norms.

  The synchronized switch is advantageously a blocking thyristor, namely a thyristor GTO (thyristor gate-turn-off), which can be blocked easily and in a targeted manner during the connection phase for the discharge. Thus, this tends to make the coupling less complex compared to the apparatuses according to the documents EP 0 543 621 A1 and DE 41 40 628 A1 already mentioned above with the operating modes

ordered at the time of the charge.

  According to another advantageous development of the invention, the sensor is a combination of a sensor in the primary circuit and a sensor in the secondary circuit, knowing that the latter is connected in parallel with the secondary winding of the closing transformer. or it can also be a combination of a sensor in the secondary circuit and a sensor in the primary circuit, knowing that the latter is connected in parallel with the primary winding of the

fence transformer.

  Finally, another improvement of the invention provides that the sensors are made for the purpose of analyzing the phase position between the pulse current and the pulse voltage and transforming it into control signals to block

the synchronized switch.

  The invention is described in more detail in support of some embodiments shown in the figures of the drawing. The figures show: FIG. 1 a principle coupling of the electric fence apparatus according to the invention in a first embodiment; Fig. 2 another principle electrical diagram of a second embodiment; Fig. 3 another principle circuit diagram of a third embodiment, and finally FIG. 4 yet another principle electric diagram of another embodiment

again.

  In the different figures of the drawing, the same elements comprise the

same reference signs.

  Fig. 1 shows a first electrical schematic diagram of the device

  for electric fence according to the invention.

  The smoothing capacitor C1 is charged via a converter (not shown) and a diode 2 to a certain value, preferably to the maximum value of the charging voltage of a power source (not shown ). A synchronized switch 4 which receives its connection pulses from a timer T is connected to the primary circuit at regular time intervals, for example at intervals of 1 s, for 0.1 to 0.3 ms, for example. During this short-duration pulse, the current flows from the smoothing capacitor C1 via the primary winding of the closing transformer 3 and the switch 4. The closing transformer 3 which has been chosen only for the value of the voltage load on the secondary side converts the voltage

at a higher voltage.

  The fence itself is a load impedance and is represented by the ohmic resistance Rz and the capacitor Cz. The impedance of the fence can evolve in a wide range. Thus, when there is a lot of vegetation, it is of the order of 100 ohms, when an animal comes into contact with the fence, it is about 500 ohms and when there is no vegetation which is the ideal situation, it is of the order of 100 kQ or MQ. It is clear that depending on the state of the fence and if the pulse voltage now converted into higher voltage is still constant, a secondary current is formed. Similarly, the state of the fence will influence the current ipr in the primary circuit of the device via the transformer 3. This situation is used to place a sensor S in the primary circuit, so that it captures the current ipr. The value captured in the downstream St control element is analyzed to determine the nature and degree of load of the fence. The control element St then interrupts the synchronized switch 4 by means of the timer T during the discharge process, and this, precisely when the energy discharge has reached a previously given value. As indicated above, the maximum value of the energy in discharge given by the European standard NE 61011 is 5 joules for a leakage resistance of 500 Q, therefore in the situation corresponding to the contact of an animal with the fence. But it can, for example, rise to 10 joules for a

  leakage resistance of 100 Q (a lot of vegetation).

  Depending on the state of the fence, the energy in discharge is therefore controlled so as to obtain the maximum barrier effect, while remaining within

safety limits.

  It is clear that the control element St may contain a memory microprocessor. A distribution profile of the energy in discharge can be stored in the memory (not shown). Depending on this profile and, of course, the state of the fence, a previously fixed impulse discharge energy is applied to the pasture fence. After the discharge energy has again reached a previously defined or selected value, the timer T opens to

again the switch 4.

  The principle coupling according to FIG. 2 differs from that according to FIG. 1 in that the sensor is mounted in the secondary circuit of the apparatus, and this, in

  series with the impedance of the fence formed by Rz and Cz.

  Fig. 3 shows an electrical block diagram in which the branch for determining the value of the secondary current is also on the secondary side. Here the sensor S is nevertheless in parallel with respect to the impedance of

fence.

  In fig. 4, the sensor S is again mounted in the primary circuit.

  The sensor S is here represented as a separate small winding in the closing transformer 3, in which the secondary side current is induced by a voltage which makes it possible to

follow the current.

  The advantage of the apparatus according to the invention is that - as indicated above - the smoothing capacitor CI always receives an identical voltage, preferably the maximum voltage, and the transformer 3 receives only this single voltage on the primary side. This makes it possible to choose a converter which is optimally adapted to the fixed voltage, so that it is possible to avoid unnecessary losses at the converter, which ultimately prolongs the life of the battery or

of the accumulator.

Claims (11)

claims   An electric fence apparatus comprising a smoothing capacitor (C1) and a timer-synchronized switch (4) (T), which discharges the smoothing capacitor (C1), which is charged by a converter, via a fence transformer. (3) to an electrical fence connected to it on the secondary side, characterized by a sensor (S) which picks up the electric current or the voltage or the combination of both after a discharge pulse, this information being analyzed in a control element (St) mounted downstream to determine the nature and degree of load of the fence, and the synchronized switch (4) being interrupted during the discharge process depending on the load of the fence when the energy in   discharge has reached a previously given value.   Electrical fence apparatus according to claim 1, characterized in that the sensor (S) is located in the primary circuit of the closing transformer. (3).   An electric fence apparatus according to claim 2, characterized in that the sensor (S) is formed in the fence transformer (3) in the form of a   separate measuring coil with a small winding.   Electric fence apparatus according to claim 1, characterized in that   the sensor (S) is in the secondary circuit of the fence transformer (3).   Electric fence apparatus according to claim 4, characterized in that   the sensor (S) is connected in parallel with the impedance of the fence.   Electric fence apparatus according to claim 4, characterized in that   the sensor (S) is connected in series with the impedance of the fence.   Electric fence apparatus according to one of claims 1 to 6,   characterized in that the control element (St) contains a microprocessor for controlling a distribution profile of the energy discharge in function   the fence charge (Rz / Cz).   Electric fencing apparatus according to one of claims 1 to 7,   characterized in that the switch (4) is a blocking thyristor (GTO thyristor).   An electric fence apparatus according to claim 1 or 7, characterized in that the sensor (S) is a combination of a sensor in the primary circuit and a sensor in the secondary circuit, knowing that the latter is mounted in   parallel to the secondary winding of the fence transformer (3).   An electric fence apparatus according to claim 1 or 7, characterized in that the sensor (S) is a combination of a sensor in the secondary circuit and a sensor in the primary circuit, knowing that the latter is mounted in   parallel to the primary winding of the fence transformer (3).   Electrical fence apparatus according to one of claims 1 to 10,   characterized in that the sensors are made for the purpose of analyzing the phase position between the pulse current and the pulse voltage and transforming it into   control signals for blocking the synchronized switch (4).