RU2388212C1 - Duplex electric stimulator-destructor of biological objects - Google Patents

Abstract

FIELD: agriculture. ^ SUBSTANCE: invention relates to the field of electric biotechnologies and may be used in biology, medicine, agriculture. Device comprises a source of power supply, clock oscillator, pulse transformer, conductivity analyser, electronic switchboards, electrodes. Besides it comprises controlled capacitance accumulator, which is connected by the first inlet to the first terminal of power supply source and the first terminal of primary winding in pulse transformer. The second terminal of winding is connected to inlet of the first electronic switchboard. Clock oscillator by its outlet is connected to inlet of the first electronic switchboard and control inlet of capacitance accumulator, inverse outlet of which is connected to control inlet of the second electronic switchboard. Analyser of conductivity by its inlet is connected to the first outlet of the secondary winding of pulse transformer, by its outlet it is connected to inlet of the second electronic switchboard, by its control outlet it is connected to control inlet of the third electronic switchboard, inlet of which is connected to outlet of capacitance accumulator, and outlet is connected to outlet of the second electronic switchboard and the first electrode. Besides the second outlet of power supply source, outlet of the first electronic switchboard, the second terminal of pulse transformer secondary winding, the second inlet of capacitance accumulator and the second electrode are connected to common wire. ^ EFFECT: invention makes it possible to simplify design, reduce dimensions and weight, to produce high efficiency factor and wide range of application. ^ 1 dwg

Description

The invention relates to high-voltage pulse technology, covering the field of electrobiotechnology, and can be used in biology, medicine, agriculture for the destruction of weeds, pinching, normalization of the ion balance of the root system, the destruction or repelling of rodents, the manufacture of electrical shepherds, electrical stimulation of plants and animals.

A device for the destruction of weeds using electric current, containing two elements for determining the number of weeds and their characteristics. The outputs of these elements are connected to the corresponding inputs of the control system, which, depending on this information, generates signals that control the parameters of the electric power source (RU 2081581 C1, 1997.06.20).

The disadvantages of this device include the use of a large number of hardware and a limited range of use.

Also known is a piezoelectric plant stimulator-destructor containing a source of electrical energy (power source), consisting of a piezoelectric element and a drive, a voltage limiter, a rectifying diode, a storage capacitor, a protective diode, a starting element, an electronic switch, a pulse shaper and electrodes (RU 2289244 C1, 2006.12.20).

The disadvantages of this device are the limited frequency range of the output pulses, as well as the limited scope.

The closest analogue (prototype) of the present invention is a device for the duplex exposure of electric current to biological objects of plant and animal origin, containing an operating voltage source, an active electrode, a test pulse generator, a conductivity test analyzer, an operational conductivity analyzer and a control system (RU 2005122232, 2007.01. 27).

The disadvantages of this device are the complexity of the practical implementation of the circuit diagram and the high cost of manufacture.

An object of the invention is the creation of a duplex electrostimulator-destructor of biological objects with a simple design, small dimensions and weight, having a high efficiency and a wide range of uses.

This technical problem is achieved in that a controlled capacitive storage device is introduced into a duplex electrical stimulator-destructor of biological objects containing a power source, a clock generator, a pulse transformer, a conductivity analyzer, three electronic switches and electrodes, forming new additional connections.

The drawing shows a functional diagram and simplified diagrams of the current-voltage characteristics of a duplex electrical stimulator-destructor of biological objects. On the diagrams of the current-voltage characteristics, transient and oscillatory processes of voltages and currents are not shown.

The device contains a power source 1, the first output connected to the first input of the controlled capacitive storage 8 and the first output of the primary winding of the pulse transformer 3, the second output of which is connected to the input of the first electronic switch 2, a clock 5 connected directly to the control input of the first electronic switch 2 and the control input of the capacitive storage 8, an inverse output connected to the control input of the second electronic switch 6, the conductivity analyzer 4, the input is connected connected with the first output of the secondary winding of the pulse transformer 3, the output connected to the input of the second electronic switch 6, the control output connected to the control input of the third electronic switch 7, the input of which is connected to the output of the controlled capacitive storage 8, and the output is connected to the output of the second electronic switch 6 and the first electrode 9, and the second output of the power source 1, the output of the first electronic switch 2, the second output of the secondary winding of the pulse transformer 3, the second control input capacitive capacitive storage 8 and the second electrode 10 are connected to a common wire.

Description of the device

Duplex electrical stimulator-destructor of biological objects consists of a power source 1, three electronic switches 2, 6, 7, a pulse transformer 3, a conductivity analyzer 4, a clock generator 5, a controlled capacitive storage 8 and two electrodes 9, 10.

Generator 5 generates a sequence of clock pulses that control the operation of the entire circuit. The direct output of the generator 5 (a) is connected to the control input of the first electronic switch 2 and the control input of the capacitive storage 8. The inverse output of the generator 5 (b) is connected to the control input of the second electronic switch 6.

Pulse transformer 3 is an inductive storage of electrical energy. The first terminal of the primary winding of the transformer 3 is connected to the first terminal of the power source 1, the second terminal is connected to the input of the first electronic switch 2. The output of the first electronic switch 2 and the second terminal of the power source 1 are connected to a common wire.

The drive 8 is a controlled capacitive storage of electrical energy, the first input connected to the first output of the power source 1, the second input connected to a common wire.

The secondary winding of the transformer 3 with the second output is connected to the common wire, and the first output is connected to the input of the conductivity analyzer 4 (c), the output of which is connected to the input of the second electronic switch 6. The control output of the conductivity analyzer 4 (d) is connected to the control input of the third electronic switch 7 whose input is connected to the output of the capacitive storage 8 (e). The outputs of the second and third switches 6, 7 are connected to the first electrode 9 (f), the second electrode 10 is connected to a common wire. The impact on the biological object (not shown) is carried out using electrodes 9, 10.

In the initial half-life of the generator 5 (drawing, t0-t1) at its direct output (a), a high level signal (plot a) is formed, which puts the switch 2 in the open state. The primary winding of the transformer 3 is connected to a power source 1, as a result of which electrical energy is accumulated in it. At this moment, a voltage (plot c) is induced in the secondary winding of transformer 3, which is fed through the conductivity analyzer 4 to the input of switch 6. At the same time, a high-level signal at the control input of capacitive storage 8 allows the latter to be charged to power supply voltage 1 (plot c). Since the signal level at the inverted output of the generator 5 is zero (plot b), the switch 6 is in a closed state, breaking the circuit between the secondary winding of the transformer 3 and the electrode 9. Switch 7 is also closed, since at the control output of the analyzer 4 (plot d) there is zero potential. Thus, at the initial moment of time (t0-t1) between the electrodes 9 and 10, there is no voltage acting on the biological object, the current is zero (plot f).

At the end of the first half-cycle at time t1, a zero potential is formed at the direct output of the generator 5 (plot a), the capacitive storage 8 is disconnected from the power source 1, the switch 2 is closed, the current in the primary winding of the transformer 3 begins to decrease rapidly. As a result of this, a high voltage self-induction EMF appears in the secondary winding of transformer 3 (diagram c, t1-t2). The high-level signal generated at the inverse output of the generator 5 (plot b), at the time t1 puts the switch 6 in a conducting state, connecting the secondary circuit of the transformer 3 through the conductivity analyzer 4 to the electrodes 9, 10, to which the bioobject is connected. During the time t1-t2, the voltage at the electrodes 9, 10 sharply increases (plot c), however, the current flowing through the bioobject is very low and represents the leakage current of the bio-object’s own insulation (plot f, t1-t2). At point t2, a breakdown of the isolation of the biological object occurs, as a result of which a conductive channel is formed inside it, while the voltage of the secondary winding of the transformer 3 sharply decreases over time t2-t3 (plot c), and the current increases (plot f). At time t3, the current of the conducting channel reaches the optimum value (plot f), at which a high-level signal (plot d) arises at the output of the conductivity analyzer 4, which opens switch 7 by connecting a charged capacitive storage 8 (plot e) to electrodes 9, 10. The operational (power) impulse coming from the drive 8 through the open switch 7 to the electrode 9 is superimposed on the conductive channel formed by the discharge current of the transformer 3 (diagram f, t3-t4). Thus, the bioobject is subjected to duplex exposure from two energy sources: inductive 3 and capacitive 8. The first forms a conduction channel, and the second, at a given point of its characteristic, exerts a force effect, providing the desired result. The appearance of an operational impulse is possible in any phase of the formed conducting channel, since its current value is monitored by the conductivity analyzer 4. By the time t4, the action of the operational impulse ends (plot f). The voltage on the capacitive storage 8 takes a residual value (plot e, t4-t5) until the end of the full cycle (t0-t5) of the circuit.

The time of electric shock on the biological object t3-t4 is set by the duration of the pulse supplied to the input of the switch 7 from the output of the conductivity analyzer 4 (plot d). The energy of the operating pulse is determined by the voltage of the power source 1 and the capacity of the drive 8. During the active duplex exposure procedure t1-t4 (diagrams c, d, e, f), inductive 3 and capacitive 8 energy stores are disconnected from power source 1 (diagram a, low level). This mode of operation of the device provides security and protection of the power source 1 from a short circuit between the electrodes 9 and 10.

The proposed circuitry solution allows metering the energy supplied to the biological object in a wide range. If the energy of the operational impulse is large enough, then the object will be destroyed, otherwise the result of the exposure may be a stimulation or a slowdown in the growth of the biological object. Fundamentally, stimulation differs from destruction (destruction) in energy parameters, values of voltages, currents, frequency and duty cycle of pulses, since in the case of stimulation, destruction or damage to the cellular structure of a biological object by exposure pulses is unacceptable.

In practice, the voltage of the power source 1 can be 200 ... 500V, while the voltage on the secondary winding of the transformer 3, forming a conductive channel, reaches 12 ... 17 kV.

The maximum current (amplitude value) of operating pulses is in the range of 200 ... 250 A, the minimum value is determined by the activated storage capacity of drive 8 and is 1.5 ... 2.0 mA.

The repetition rate of electrical signals is in the range from 10 Hz to 70 kHz. The minimum duration of operational pulses in the absence of "tightened" fronts is 0.2 ... 0.5 ms.

The device can be used as an electric drive for killing weeds, pinching, normalizing the ion balance of the root system of plants, destroying or scaring away rodents, making electric shepherds, and stimulating plants and animals.

The device has a simple design, has small dimensions and weight, high efficiency and a wide range of uses. It does not violate the ecology of the environment and does not cause genetic or structural changes in biological objects.

Claims (1)

Duplex electrical stimulator-destructor of biological objects containing a power source, a clock generator, a pulse transformer, conductivity analyzer, the first, second and third electronic switches, the first and second electrodes, characterized in that a controllable capacitive storage device is inserted into it, the first input connected to the first output the power source and the first output of the primary winding of the pulse transformer, the second output of which is connected to the input of the first electronic switch, a clock generator, direct connected to the control input of the first electronic switch and the control input of the capacitive storage, inverted output connected to the control input of the second electronic switch, conductivity analyzer connected to the first output of the secondary winding of the pulse transformer, connected to the input of the second electronic switch, control output connected to the control the input of the third electronic switch, the input of which is connected to the output of a controlled capacitive storage, and you the stroke is connected to the output of the second electronic switch and the first electrode, and the second output of the power source, the output of the first electronic switch, the second output of the secondary winding of the pulse transformer, the second input of the controlled capacitive storage and the second electrode are connected to a common wire.