FR2725870A1 - Solar powered electric fence triggered by proximity - Google Patents

Abstract

The electric fence control circuit has an astable multivibrator that emits pulses to activate a monostable multivibrator. The multivibrator controls activation of a high tension generator of the "fly-back" type, which has an electronic switch (2) in the primary of a transformer (3) that has its secondary connected in a diode voltage multiplier circuit (8,9,10,11). The output of the voltage multiplier is connected to a break-over device. The astable multivibrator has a current input that makes it operate as a current to frequency converter. The primary voltage of the transformer is rectified, filtered and applied to a comparator which has a reference input. The comparator output is applied to the astable multivibrator reset input.

Description

Presence-triggered solar electric fence
Solar electric fence triggered by presence detection.

The present invention describes a very energy efficient electric fence, powered by a solar recharged battery and the main ones
resident innovations:
on the one hand in the design of the high voltage generator particularly energy efficient
-on the other hand in the fact that the fence wire is normally isolated from the ground and from the high voltage (constantly present). II is instantly
connected to high voltage only when the fence wire is earthed by a non-insulating object or object.

-The average energy consumption of the fence according to the invention is at
almost independent of the length of the fence and the intensity of
landfills provided.

-As an example, this system, consuming around twenty milliwatts, can
provide dumps as powerful as a conventional fence which
should consume with identical performance 200 to 300 milliwatts and
even more.

Most high-voltage generators consume a few watts for
maintain a high voltage, even in the absence of any external load.

Since most of these devices are powered by the mains, this has not
of importance, because for a sector, a few watts is a consumption
negligible. If now we want to make these devices portable and / or
autonomous, such consumption becomes a serious handicap. Most
small portable lead batteries have a capacity of 0.75
amperexhours under 12 volts, or an available energy of six to seven wattsxhours, or it is such batteries that we propose to use.

The high voltage generator device described in the present invention
has an intrinsic consumption (ie in the absence of any load
external) less than twenty milliwatts and can provide a voltage of the order of
two to three kilovolts, which can then be increased by means of a
diode voltage multiplier. This gain in consumption, therefore in autonomy,
by a factor of around a hundred at the start is appreciable because without this, this
device can hardly be made portable and / or autonomous.

We will first examine a conventional high voltage generator and
analyze the why of its excessive consumption, which will help better
grasp the originality of the new system described.

A conventional high voltage generator is made up as can be seen
in FIG. 1, by a transformer 1 comprising a primary winding
twice N1 turns whose midpoint is connected to the most battery and a
secondary winding of N2 turns. The two ends of the primary are
alternately connected to ground by an electronic switch 2 which
induces an AC voltage on the secondary winding. The value of this secondary voltage is: Us = Ubx (N2 / N1), Ub being the battery voltage and Us the voltage at the secondary.

 The capacitor 3 of FIG. 1 represents the parasitic capacitance between turns which appears at the secondary and which is therefore found connected between the ends of the secondary.

To fix the idea, if you have 12 volts in primary and you want a voltage of 1 kilovolt in secondary, the ratio of turns N2 / N1 is then close to 100, which imposes a large number of turns secondary and therefore a significant capacity 3. At each alternation, the secondary voltage charges and discharges the capacitor 3. The energy stored by a capacitor is given by the expression: W = 1/2 CxV2 where V is the maximum voltage which appears at the terminals of the capacitor 3. If F is the switching frequency of the electronic switch shown schematically in 2, Figure 1, then the dissipated energy induced by the presence of the capacitor 3 will be proportional to
W = FxV2. If we reduce the number of turns, we reduce the capacity but we must increase the frequency and consequently the number of charges and discharges per second and conversely if we increase the number of turns we can reduce the frequency, but the capacity of the parasitic capacitor 3 is increased.

 We got out of the previous dilemma using the architecture shown in Figure 2.

 It is a "Fly back primary side" that can be translated by a coil type architecture of RUMKORPF with voltage control by the primary.

 By way of example, FIG. 2 shows a voltage doubler with negative output voltage produced with this technology.

 1 is a specialized integrated circuit dedicated to piloting and controlling such "Fly-back" systems.

2 is an electronic switch composed of an assembly of transistors
Power MOS and BIPOLAR capable of switching a maximum voltage of 1 Kilovolt, 3 is a transformer with air gap (or if you want a choke with a primary and a secondary coupled by the magnetic flux). The network 4, 5, 6, 7 constitutes a voltage divider which returns to monitor block 1 a measurement of the primary voltage, therefore an image of the secondary voltage intended to be compared with a fixed voltage. It can thus be seen that the operating voltage is regulated. 8, 9, 10, 11 and 12 constitute a voltage doubler.

For example, if we have a voltage of 600 volts at the primary of transformer 3 and 2.5 Kvolts at secondary, the transformation ratio
N2 / N1 is this time close to 4 and the number of turns in secondary school is therefore at least 20 times lower than with the system of the previous figure (which nevertheless requires much less know-how to be implemented than the fly-back).

 We have therefore already gained an important factor on consumption compared to the circuit in FIG. 1. We are however limited because integrated circuits of type 1 consume at least one hundred milliwatts. An example system like the one shown in Figure 2 can provide 4 to 5 watts maximum and consume around 150 milliwatts when empty, which is already a step forward. Its efficiency as a function of the power delivered then looks like the curve shown in FIG. 3.

 If we want a correct output at all powers, then we must block circuit 1 in Figure 2 at its maximum power and operate it all or nothing as in Figure 4. By increasing or reducing the relative working time ( duty cycle) the output power can be modulated, the capacitor 12 in fig 2 serving as a buffer tank to supply the current consumed by the use between two recharges by the generator.

This time the consumption of the device can vary from 20 milliwatts when empty to 5 watts when fully charged.

 By this process the electric fence consumes about 20 milliwatts.

 The architecture of the high voltage generator applied to the fence is shown in Figure 5. We only included the functional blocks without giving the detail of the diagram of these blocks, because to obtain these functions we used integrated circuits or circuit assemblies integrated of the trade.

It is the particular sequence of functions that ensures consistency,
The originality and performance of the system, whatever the technology used to perform these functions. These functions could even be programmed in a microcontroller.

 Block 15 is an astable circuit which sends regular pulses. Its input terminal 14 is a current control which, when used, makes it possible to accelerate the frequency of the pulses in proportion to the current which is injected into it. The circuit 15 is then transformed into a "current-frequency converter". This characteristic will not be used in the particular application of the fence.

 Circuit 30 is a monostable (which could also be a bistable) whose input 18 is the bome (set) or set to one and the inputs 19, 20 and 21 are (reset) or reset to zero. The output 23 of the circuit 30 controls the electronic switch 13 which energizes the high voltage generator when the monostable 30 is in the active position (set). Thus, the high-voltage generator now works in all or nothing, therefore at its optimal efficiency in accordance with the curve of FIG. 3.

 The image of the output voltage is collected from the primary of the transformer 3 on the voltage divider constituted by the resistors 6, 7, is compared to a fixed reference voltage 17 by the comparator 16.

When the voltage present on terminal 29 of comparator 16 is greater than the reference voltage present on terminal 17, the output of comparator switches, activates terminal reset 21 and resets circuit 30 to zero.

 We can now understand the operation of the high voltage generator in FIG. 5.

 For now, ignore components 22, 23, 24, 25, 26, 27 and 28 which are specific to the fence.

 Every second, in accordance with the standard for electric fencing, astable 15 emits one pulse out of 18. This pulse activates circuit 30 which energizes the high voltage generator which in turn recharges the output storage capacitor 12.

 As the voltage on 12 increases, the voltage 29 (at the input of comparator 16) which is the image also increases until it is equal to the fixed reference voltage 17. At this time, the output 21 of comparator 16 switches and deactivates circuit 30 which opens the electronic switch 13 and switches off the high voltage generator.

 At the next pulse of 'stable 15, the cycle resumes. As the high voltage diodes always have a slight leakage current, at each new cycle the high voltage generator regenerates the capacitor discharge 12.

 Each time the high voltage generator is activated, the LED 26 lights up for the duration of powering up of circuit 1. This is an indication of the operation of the device.

 We can now approach the role of components 22, 23, 24, 27 and 28 which are specific to the operation of the electric fence.

First of all, let's explain the primary role of spark gap 22:
If the fence wire was connected directly to the capacitor 12, this fine long wire brought to a high voltage would be subjected to the physical phenomenon of "power of the tips" and the ionization which would follow would discharge in a very sensitive way the capacitor 12 between two pulses of stable 15, which would considerably increase the overall consumption (an increase in consumption has been measured by a factor of at least 10).

We have therefore imagined a high voltage switch device which must meet the following criteria
-Isolate normally the closing wire of the capacitor 12 charged at high voltage and thus reduce the discharge of the capacitor which would be caused by the phenomenon of ionization of the air induced by this wire brought to a high voltage.

 -Connect the capacitor 12 "roughly" to the line in the event of an intrusion, so as to "benefit the user" from the energy released by the sudden discharge of the capacitor 12.

The spark gap 22 in FIG. 5 satisfies these two conditions:
-In normal time it isolates the line of capacitor 12.

 -In case of connection between earth and the output terminal of 'spark gap, the latter "bursts", suddenly transforming into a short circuit and "the user" is directly connected between ground and capacitor 12 without losing anything energy stored and supplied by the capacitor.

 The "use" current closes through the zener 23 with the capacitor 24 in parallel. The positive voltage thus developed on the zener 23 is fed back to the reset terminal 22 of the circuit 30 and resets the latter, thus preventing the high-voltage generator from activating again to recharge the capacitor 12 before a new signal given by the generator. rhythm 15. In this way it is impossible to generate a burst of pulses.

 The LED 28, (activated by electronics that have not been included to simplify the diagram) gives a burst when the capacitor 12 discharges, thus signaling a "presence" on the line. This LED can advantageously be replaced or associated with a buzzer or any other component thus providing an audible and / or light signal warning of a presence on the line.

 Advantageously, a spark gap will be chosen with a breaking voltage substantially lower than the "normal" voltage of the capacitor 12.

Suppose that the normal voltage of the capacitor 12 is 8 Kvolts and the breaking voltage of the spark gap 1.5 Kvolts and suppose that the energy stored by the capacitor at 8 Kvolts is 100 millijoules. This is the energy that a "stealthy" user will receive.

 If a branch or any other non-insulating object establishes permanent contact with the earth, at each cycle the capacitor 12 will charge up to 1.5 kilovolts (burst voltage of the spark gap) and will discharge in the line at the time of rupture of the spark gap. The energy stored by a capacitor is given by the expression: W = 0.5xCxV2. If at 8Kvolts this energy is 100 millijoules, at 1.5 Kvolts it is only 100x ((1.5) 21 (8) 2) = 100x (2.25 / 64) = 3.5 millijoules.

Thus we see that the device sends its energy only to "user" and goes into "sleeper" either on a permanent fault, or on absence of "presence"
Whatever happens, the device described always remains in energy saving.

These few figures show that at equal "useful" power, the size of the battery necessary for the operation of a conventional fence can be divided by more than twenty which would have performances almost identical to that described in the invention.

This gain in size allows the permanent recharging of the battery with a photocell of reasonable dimensions.

 In one embodiment, the solar cell has a power of 1 watt peak in amorphous silicon technology, its size is 15 × 15 centimeters. The battery used is a waterproof 12-volt lead battery with a capacity of 0.75 ampere-hours.

The overall consumption is <2 milliamps, or about 20 milliwatts.

 The "useful" discharge has an energy of 150 millijoules under 7 kilovolts.

A quick calculation shows that a conventional fence of good quality and which would have identical performances by providing spaced pulses in time of 1 second each, would consume around 300 milliwatts and would thus require for its supply a battery of 20 amperexhours and a solar cell '' at least 0.5 square meters.

Claims (17)

 1) Device designed to generate a high voltage with low no-load consumption, characterized in that it comprises an astable multivibrator 15 which emits pulses (18) which activate a monostable multivibrator 30 which controls the energization of a high generator "Fly-back" type voltage composed of a control circuit (1) and an electronic switch 13 which controls a gap transformer 3, the secondary of which activates a diode voltage multiplier, the high voltage output 12 of which is connected to a spark gap (22) in the case of an electric fence.  2) Device according to claim 1 characterized in that the astable 15 is provided with a current input (1) which makes it a current-frequency converter with a frequency response of the form f = fo + k * i or i is the intensity of the current injected at the input terminal 14 of stable.  3) Device according to claim 1 or claim 2 characterized in that the monostable (or bistable) 30 is activated by the output (18) of 'stable 15.  4) Device according to claim 1 or claim 3 characterized in that the monostable (or bistable) 30 is provided with at least three reset inputs.  5) Device according to claim 1 characterized in that the monostable or (bistable) (3) activates a contact 13 which can advantageously be a static contact, that is to say semiconductor. 6) Device according to claim 1 and claim 5 characterized in that the contact 13, when activated activates a voltage booster generator which can advantageously be of the "fly-back" type, but the fly-back topology is not limiting.  7) Device according to claims 1 and 6 characterized in that the control of the generator voltage is advantageously of the "primairy side" type, namely, the control of the operating voltage is carried out from the information taken on the transformer primary, making the secondary isolated from the primary. But the tension control could also be done from the secondary.  8) Device according to claim 7 characterized in that the primary voltage of the transformer 3 is rectified, filtered and compared to a fixed reference voltage 17 by a comparator 16.  9) Device according to any one of claims 8 or 1 characterized in that the output of the comparator 16 is injected into a reset input of the astable (or monostable) circuit 30.  10) Device according to claims 8 or 9 characterized in that the  secondary of transformer 3 is galvanically isolated from primary and electronics.  11) Device according to any one of claims 1 or 10 characterized in that the secondary of the transformer 10 supplies a voltage multiplier with diodes whose output can be negative.  12) Device according to any one of claims 1 or 1 1 characterized in that the voltage provided by the diode multiplier is advantageously negative.  13) Device according to any one of claims 1,10,11 or 12 characterized in that the high voltage output of the electronics is separated and isolated from the fence wire by a spark gap.  14) Device according to claim (13) characterized in that this spark gap can be constituted by a gas spark gap, a static spark gap such as a thyristor or a triac, a car spark plug, simply two ends of wire kept at an adequate distance or any normally insulating system which transforms into a non-destructive short circuit (under conditions of use) when it is subjected to a voltage exceeding a certain threshold, and which automatically returns to the open state when the cause which put it in our circuit has disappeared.  15) Device according to claim 14 characterized in that the ignition voltage of the spark gap is at least three to four times lower than the nominal voltage of the fence.  16) Device according to claim (14) characterized in that the earth current caused by the burst of the spark gap (22) closes through a zener associated with a capacitor in parallel.  16) Device according to claim (16) characterized in that an electronic circuit controlled by the voltage of the zener 23 is used to visually and sonically signal "presence" on the line.  17) Device according to claim (16) characterized in that the fault display circuit can be replaced or associated with a sound device.