DE1539765A1 - Electronic pasture protection device - Google Patents

Description

Electronic pasture protection device The invention relates to an electronic device for generating short high-voltage pulses at predetermined, variable intervals, depending on the load, particularly for use in To operate the device or circuit arrangement, one of its poles is connected to earth and the other pole to the pasture fence, which is isolated from earth and which limited.

The purpose of the invention is to create an automatic system with low energy consumption when idle. This is, especially with pasture fences, that cannot be fed from the normal power grid, but from their own energy sources, such as batteries or accumulators, which are also light in weight for transport must have, of particular importance.

According to the invention, the circuit arrangement consists of an electrical one Energy source, preferably a battery, an accumulator or a solar battery, those for converting the low battery voltage into a right-angled AC voltage with high potential to an electronic component from a first non-linear one Oscillator is connected. The transformer of the oscillator is designed in such a way that that the core, when excited by the oscillator voltage, vibrates and acoustically Emits waves that generate a sound signal to keep the Device display. The oscillator is monitored by a circuit that cycles it interrupts if the fence remains unaffected. There is also a second circle for Rectifying the AC voltage on the Output of the oscillator provided, which also has a capacitor with a greatly increased compared to the battery Voltage supplied. A third circuit discharges the capacitor, whose current is over a transformer is fed to the pasture fence, a #ed circle is also provided, which recovers the non-dissipated energy entered into the fence. A fifth Circuit controls the discharge of the capacitor when it has the desired voltage has reached which is fed to the primary winding of the transformer, its secondary winding is connected to the pasture fence.

If the fence is not touched, the circuitry sends up the line pulses at greater intervals than when touching the fence. Through this a minimal electricity consumption is achieved. There is less energy consumption both because the pulses have a lower pulse repetition rate and because Energy is recovered through the savings circuit that uses the unused dnergie used to recharge the capacitor. However, if the fence is through a Connection with earth-loaded, the pulse train is according to the 3circuit of the device higher.

The circuit arrangement according to the invention has the double CD The advantage is that the electrical power supplied to the fence is automatic is increased when the fence is touched, and that during operation a poor insulation of the fence (which would defeat the function of the device) is immediately indicated by the fact that the frequency of the transformer of the oscillator generated, monitoring, acoustic pulses gesteici Gert.

The transportade device according to the invention, particularly suitable for monitoring pastures, is described in more detail in the accompanying drawings and the following description, which are merely exemplary and not restrictive. Fig. 1 shows a block diagram. Fig. 2 shows the circuit ## eleven. Zitn # -. Tc-list is getting nasty. 1 Mlit ß is2t ## die n -. # It (7.5 V) net the non-linear transistor oscillator. C is the step integrator fed with energy from the oscillator output via a diode, the integrated voltage increasing in steps up to a limit close to the peak voltage of the oscillator. The discharge circuit for utilizing the energy stored by the integrator is denoted by D. E is the output circuit in which the total energy stored by the integrator capacitor is discharged directly to an induction circuit with a rising output. This circuit has an instantaneous power of about 1.2 kW, which is fed into the fence and supplies the voltage to the interrupter circuit. F is the savings circuit that recovers the residual inductive energy and returns it to the step integrator C. G is the ignition circuit, which has the task of supplying pulses to the discharge circuit when the integrated voltage is close to the peak value. H denotes the circuit breaker, which delivers a number of voltage pulses to the fence, depending on whether it is slowed down in waiting mode or accelerated when an animal touches the fence. In this way the circuit automatically regulates the pulse repetition frequency. Economical energy consumption in waiting mode and maximum effectiveness when the fence is touched by an animal is achieved. Fig. 2 shows the oscillator with the transistor Tl in a Meissner circuit. The circuit is controlled in such a way that it works in blocking mode. The inductance Ll (TR1) determines the time that Tl conducts, while L2 forms the feedback that leads to the base of the transistor Tl. The resonance frequency of the oscillator is determined by Rl-R2-R3-R4-C2-L2. Apart from a reaction through the secondary winding L3 , the base circuit of the transistor Tl is closely coupled to the automatic breaker control. The relevant details to which these latter elements must correspond will be described later. The operating frequency of the oscillator is selected from the point of view of good audibility of the sound signal generated by the core of the transformer TR1, the availability of favorable transmission and the particular structural shape of the support of the TR1, which makes it very easy to achieve audible acoustic monitoring that indicates the correct operation of the device, eliminating the need to illuminate a control lamp or any other energy-consuming indicator. The step integrator emits impulses in a chronological sequence in order to generate high-energy discharges which, however, do not entail the risk of physical injury to the animals touching the fence. For this purpose, a generator with low power is used, which is formed by the oscillator b , the energy output of which is stored in waiting mode in order to be able to have increased power at the moment the fence is powered. The integrator is formed by the capacitor C1 , which is charged with the positive pulse from the oscillator. These pulses are picked up from the secondary winding L3 via the diode D1. At the beginning of the integration, the empty capacitor C1 represents a very Load for the oscillator, so that the voltage at L3 -, - "r is low. Db integrated voltage of. C1 represents a Schi "iellwert for the pulses supplied by the oscillator, the size of which grows until Cl has been charged up to the peak value of the voltage supplied by L3 . The size of the capacity of Cl is a balance between storable energy and the time required for charging The output circuit and the charging circuit are as follows: Cl is connected in parallel with L5 (TR2) by the controlled diode DP3 (discharge circuit) towards the end of the charging process and forms an oscillator circuit which oscillates freely with an initial energy of 1/2 C, V2.

D4 allows the oscillator circuit to have a single oscillation. Because of the shortness of the free period of oscillation, the value of the fence increases given performance to an extremely high degree.

The mechanism is as follows: Cl discharges through the ignited, controlled diode DP3 to L5 (TR 2); part of the initial energy of Cl is transferred to the fence connected via L6; a part remains as magnetic flux in L5.

During the second quarter of the free oscillation period, the energy from L5 is partially transferred to the fence; partially is Cl With; recharged in reverse polarity.

At the end of the second quarter of the period, the current through DP3 ceases, causing an interruption. The charged capacitor Cl can discharge again through D4 (13parkreis) on L5, causing the third quarter of the free oscillation period is initiated. The energy remaining in L5 , of course minus that transferred to the fence, charges Cl with positive polarity.

The process stops if DP3 is not energized.

The voltage recovered at Cl means a saving insofar as the oscillator Cl no longer has to charge e from zero. The savings are significant when the fence is unencumbered.

The output transformer (TR2) has windings designed in such a way that the voltage on L7 (breaker) is reduced to negligible values when the secondary winding L6 is loaded. Therefore, a transformer with increased dispersion is selected (apart from the slight saturation of the core due to the increased value of the instantaneous power).

The winding L6 is arranged so that it forms a magnetic screen between L7 and L5 . Indeed, the flux created with the current flowing in L6 makes it impossible for that of L5 to reach winding L7 . In order to reduce energy losses to a minimum, a ferrite core is chosen, while the special arrangement of the windings of the transformer TR2 allows a simple construction that does not exclude a high degree of operational reliability.

The ignition circuit consists of L4, D2 and the battery B. For the best utilization of the Zhergie stored by Cl is It is essential to keep the DP-7 diode blocked until the condensation Sator Cl has reached a voltage which is close to the peak voltage is at L3 . For this it is necessary to activate the ignition of DPj expediently to delay, for which purpose the :-) 'tax circle of DP.) wit-a constant th threshold voltage, namely with the de: c battery B, applied. The diode D2 usually has the task of keeping DPj in front of J "iin, # iir- protection from. :) voltage in the opposite direction (i.e. before the already mentioned threshold voltage and the negative selyvings on Lik) and the introduction of a control voltage to the automatic 3 to effect control of DPj. The impulsive voltage on the 39 outer winding L3 (and thus on L4) is shown in a step-by-step increase in latitude, controlled by the limiting effect of the au- Current tension on Cl Tjähi: "2n # -1 of the integr, -ation! 3vorgan, # - #, r-, s. At the beginning of the integration process the Z-, iveiL Cl Dl forms one Short circuit against Lj (the capacitor is loaded - t). During the first pulse generated by Lj , a first load is performance level for Cl determined. The amplitude peak of the charging Impulses can almost be one of the first integrated voltage levels achieve the same voltage value. The second positive impulse from L3 initially holds (without supplying energy) on a cl # 3r ampli tude of the first stage same level; the remaining part of the Impulse causes a further load initiation for Cl (two th stage). At every instant in time, the integrated 3voltage e of Cl represents a threshold value for Dl , so that the passage of current is only possible Lich is when the voltage amplitude on L_3 this threshold value exceeds. This creates a new one, similar to the previous one Peak reached (equal to the threshold plus the amplitude of the new level). When the voltage on Cl reaches the voltage spike on L3, is No-load condition given for the transformer TR1. Since the voltage on L4 is the same as the voltage on LJ there is an ignition delay of the diode DP3, urfi the 1.7ntli (lung of the capacitor Cl , when it has stored the desired energy.

Ignition is impossible as long as the gradual increase in voltage on L4 of the ,, D ignition circuit supplies voltage values that are below the threshold voltage (the voltage of the battery). When the voltage at L4 exceeds the 3 threshold value, the flow of current begins in the control circuit of DP3. With a favorable dimensioning of the transformation ratio in relation to the winding Lil on the transformer TR1, the voltage value required and necessary for ignition is reached shortly before the end of the charging of Cl and that is, when the integrated energy has reached the maximum possible value. The interrupter circuit used in the circuit for the purpose of economic operation consists of a chain of reactions, beginning with the output in such a way that the oscillator is periodically interrupted depending on the energy consumed by the consumer. The operational interruptions are long when the output is not loaded and short when the "output is loaded, i.e. when the protective conductor is touched by an animal, the maximum available energy being completely consumed. This is made possible by the." Feedback circuit L7 -D5-Cl- R2 - R3 - R4 enables the voltage at the output and the voltage on winding L7 of transformer TR2 is limited by the decrease in power on winding L6 . In no-load operation, the voltage on L7 reaches a maximum As a result, Cl is charged via D5 , which extinguishes the polarization of Tl, which blocks it for a fairly long time. You then have to wait for C2 to be almost completely discharged so that the oscillator assumes the re-ignition state. The 3circuit allows: 1. to prevent C2 from limiting the oscillator during the operating time so that no power is lost and 2. to enable the capacitor C2 to cooperate sufficiently (with a negative voltage for the base of T1) to prevent the Lock transistor of the oscillator. In order to further obtain a certain accu- racy in the continuity of the lockout period, in the discharge circuit of C2, a positive voltage is introduced which is supplied to the distribution across R3 from the battery to R2. In this way, the voltage given to the base of Tl passes through zero, with a sufficiently steep slope that has moved away from the asymptote of the transition.

R4 decouples C2 sufficiently from the function of R2 (automatic regulation of the control current of the base during normal oscillator operation). The ratio between R4 and R2 determines the part of VC 2 allotted to R2 for stopping the oscillator operation.

The resistor R3 also has the purpose of initial polarization the base of Tl to allow the oscillator to self-excite.

, -A load on the protective conductor, the voltage at L7 drops to very low values, which is due to the special properties of the output transformer TR2. As a result of this, the voltage applied to C2 drops, whereby the operating breaks of the oscillator are reduced to a minimum. Under these circumstances, the circuit arrangement delivers its maximum performance.

Of course, the various circuit elements can go through other equivalent circuit elements can be replaced with other components without that this leaves the scope of the invention.

Claims (2)

P A T EN T A N 3 PR Ü C H E 1. Electronic generator circuit for generating pulses, in particular for the protection and monitoring of pastures, characterized in that the circuit short electrical pulses of high voltage in predetermined and varying distances depending on the Stress generated, and with recovery of unused energy. 2. Electronic generator circuit for generating Iinpulsen according to claim 1, characterized in that the high voltage electrical pulses follow at long intervals when the output or the protective conductor is unloaded, and at short intervals when it is loaded. 3. Electrical generator circuit according to claim 1, optionally claim 2, characterized in that it contains an element which emits sound signals when switched on, this element consists of a transformer with a core with iron dimensioned in such a way that cyclic acoustic vibrations are emitted when the circuit is engaged, and variable depending on the load. 4. Circuit arrangement for building the generator circuit according to claim 1 and 2 and optionally claim 3, characterized in that it contains the following circuit elements in combination: A power supply group with a battery or an accumulator, a non-linear oscillator with a transistor, a capacitive integrator, which is from Oscillator is fed via a diode, for which the integrated voltage has a stepped course, from a discharge circuit of the integrator to the output circuit, from a recovery circuit not used. needed electrical "nerrie, if the Aus-ano- el -, - k-trisch not. Czi (Z) CD loaded x - tird, by a circle to control the discharge of rIes inter- grators when it has reached the desired tension, and from a circle to interrupt the impulses.