RU2192121C1 - Apparatus for magneto-pulsed treatment of planting material - Google Patents

Abstract

FIELD: agricultural engineering, in particular, equipment for promoting plant growing and development by pulsed magnetization thereof. SUBSTANCE: apparatus has mains adapter, setting generator having output connected to input of frequency divider, whose outputs are connected to inputs of first commutator connected through its output with input of univibrator, voltage stabilizer with output connected to key input, digital indication unit, induction coil connected through its first lead with first lead of voltage indicator, second commutator connected through its first and second inputs to mains adapter output and positive terminal of accumulator battery respectively and through its output to voltage stabilizer input. Univibrator output is connected to first inputs of first, third and fifth AND elements. Timer output is connected to inputs of digital indication unit, NOT element and second input of first AND element, whose output is switched to S-shaped input of first RG-trigger. Output of NOT element is connected to second input of second AND element, whose output is connected to R-input of first RS-trigger with output connected to second input of fifth AND element and first output to second inputs of third and fourth AND elements. Output of third AND element is connected to input of first amplifier-former. Output of fifth AND element is connected to R-input of second RS-trigger. Output of fourth AND element is connected to input of second amplifier-former and to S-input of second RS-trigger. Output of control panel is connected through control bus to zero control inputs of timer, voltage doubler unit, first and second commutators. Apparatus may work in semi-automatic mode of operation under field conditions. EFFECT: reduced power consumption, safe, stable and steady-state operation within working range of magnetizing pulse frequencies and induction coil inductivity values. 3 dwg

Description

 The invention relates to agriculture, and in particular to means of stimulating the development and growth of planting material of plants by means of their pulsed magnetization.

 A device for magnetizing permanent magnets is known that contains a charge-discharge capacitance connected through one of two interconnected control keys and a limiting resistor to a network half-wave rectifier, and through the other key and a damping diode to an inductor (see Prilepsky A.N. A simple method magnetization of permanent magnets, "Automation-telemechanics-communication", 1975, 4, p. 37).

 The specified known device is imperfect, since it allows magnetization to be carried out only with manual control, sequentially operating with control keys, while the magnetization parameters are usually unstable and magnetization is impossible with a strict periodic sequence of magnetic pulses.

 A device is known, which consists of an electric current pulse shaper and a magnetic field emitter. The driver includes a power supply, a capacitor storage of electrical energy, a key unit and a key device control unit. The power supply unit is connected to the capacitor bank and the key block control unit, which is connected to the control input of the key block, and the capacitor bank and the key block connected in series to it are connected at the output of the driver to a magnetic field emitter made in the form of a solenoid. An alternating voltage of an industrial network of 220 V, 50 Hz is supplied to the input of the shaper. During the positive half-cycle, the key block is closed and the capacitor bank is charged through the power supply. In the negative half-period, the block opens the key block and the capacitor storage is discharged to the solenoid, which creates a magnetic field pulse in the emitter (see RF Patent 2083070, 1993, class A 01 S 1/00, B.I. 19, 1997 .).

 However, this device can operate only at one repetition rate of magnetic pulses — a network frequency of 50 Hz, in a narrow range of magnetic pulse durations, which is not always acceptable when processing planting material of plants.

 In addition, the device is energy-intensive and works only from an industrial network of 220 V, 50 Hz, which is unacceptable when working in the field.

 The closest technical solution from the known ones is a magnetizing pulse generator containing a power supply unit connected via a first key and a ballast resistor to a charge-discharge capacitance connected through a damper diode, an inductor and a second key with a common bus, and also containing a control signal generator, one the input of which is connected to the network power supply, and the other two to the control buttons of the start and end of the magnetization, respectively, "Start" and "Stop", while one of the two outputs of the signal conditioner board is connected to the control input of the first key, and the second is connected to the control input of the second key and the input of the display circuit, the output of which is connected to a digital board (see V.I. Kashin, M.T. Upadyshev, V.I. Donetsky, A. A. Tsymbal, GV Beshnov "Magnetic-pulse processing of cuttings of garden crops. Tractors and agricultural machines, 2000, 7, p. 12 - prototype).

 In this known device, an alternating voltage with a network frequency from the secondary winding of the power transformer of the power supply is supplied to the input of the control signal generator, which generates start pulses for the frequency divider from it. Rectangular pulses from the output of the control signal generator control the first and second keys. Through the open first key and a ballast resistor (incandescent lamp), a large capacitor is charged in a multiple of 5.12; 10.24 or 20.48 s to a voltage of 200-300 V. The subsequent discharge of the capacitor is carried out through a damper diode, inductor and a second key (thyristor) for a time of (1-6) ms. As a result of the fast discharge of the capacitor, a large magnetizing current flows through the inductor.

 The display circuit allows the digital display to count the number of magnetizing pulses of the inductor for the time interval between pressing the "Start" and "Stop" buttons.

 However, this magnetizing pulse generator is ineffective due to large power losses on the ballast resistor when charging a large capacitor, operates in a narrow frequency range with a maximum limited number of magnetic pulses in each of the three subranges, no more than 99. For its stable operation, careful coordination of parameters is necessary inductor with a charge-discharge circuit, since their variations can lead to the holding of the second key in the open state and malfunction. In addition, there is no synchronization of the beginning and end of magnetization with pulses that control the state of the second key. This eliminates the normalized charge and discharge of the large capacitor for the first and last magnetizing pulses of the packet, respectively, and also reduces the safety of the device due to the residual charge voltage of the large capacitor after the Stop command. Moreover, it is not suitable for work in the field.

 The problem to which the invention is directed, is to create a device with significantly expanded parameter values, high stability and suitable for use in laboratory, production and field conditions for periodic magnetic pulse treatment of planting material before planting, as well as in the process development and growth of plants.

 The problem is solved in that in a device for magnetic-pulse processing of planting material, containing a network adapter, a master oscillator, connected to the input of the frequency divider by the outputs, the outputs of which are connected to the inputs of the first switch, the output connected to the input of the one-shot, voltage regulator, the output connected to the key input, digital indication unit, inductor connected to the first output of the voltage indicator by the first output, an additional battery, a second commutator torus, timer, element NOT, first, second, third, fourth and fifth elements AND, first and second RS-flip-flops and amplifiers-drivers, delay element, DC-DC converter, voltage doubler unit, static DC switch and control panel, the second switch with the first and second input is connected, respectively, with the output of the network adapter and the positive output of the battery, and the output is connected to the input of the voltage regulator, the output of the one-shot is connected to the first inputs of the first, t of the third and fifth elements AND and the input of the delay element, the output of which is connected to the first inputs of the second and fourth elements AND, the timer output is connected to the inputs of the digital display unit, the element NOT and the second input of the first element AND, the output connected to the S-input of the first RS trigger , the output of the element is NOT connected to the second input of the second element AND, the output of the first RS trigger connected to the R-input, the second output of which is connected to the second input of the fifth element And, and the first output is connected to the second inputs of the third and fourth elements And, the output of the third element And is connected to the input of the first amplifier-driver, the output of the fifth element And is connected to the R-input of the second RS-trigger, the output of the fourth element And is connected to the input of the second amplifier-driver and S-input of the second RS-trigger, the first output connected to the control input of the key, the output of which is connected to the input of the DC-DC converter, the output connected to the input of the voltage doubler unit, the output of the positive polarity of which is constantly connected to the second input of the static switch of the current and the first output of the inductor, the second output of which is connected to the first input of the static DC switch, the zero output of which is connected with the negative polarity output of the voltage doubler unit, with the second output of the voltage indicator, as well as with the second outputs of the outputs of the first and second amplifiers-shapers, the first conclusions of the outputs of which are connected, respectively, with the third and fourth conclusions of the control inputs of the static DC switch, and the output of the control panel via the control bus Nia connected with zero control timer inputs, a voltage doubler unit, first and second switches.

 The technical result is that due to the introduction of the second switch, the battery, the DC-DC converter and the voltage doubler unit, it became possible to operate in the autonomous mode and use in the field, and the exclusion of the ballast resistor from the charge capacitor charge circuit significantly reduced power consumption of the device. In addition, the timer introduced into the proposed device, the element NOT, the first, second, third, fourth and fifth elements And, the first and second RS-flip-flops and amplifiers-shapers, the delay element and a static DC switch provided safety, stability and stability of its operation in a fairly wide range of frequencies of magnetizing pulses and inductance values of the inductor. This also made it possible to obtain a normalized charge and discharge of the charging capacitor synchronously with the beginning and end of the periodic periodic magnetization in a wide time range of exposures. The control panel introduced into the proposed device made it possible to organize a semi-automatic operation mode of the device.

 The novelty of the proposed technical solution lies in the new elements introduced into the proposed device, their electrical connections and electrical signal transformations.

 Our analysis of the prior art, including a search by patent and scientific and technical sources of information, and identifying sources containing information about analogues of the claimed invention, allowed us to establish the absence of a technical solution in the sources, characterized by signs identical to those of the proposed invention. The definition from the list of identified analogues of the prototype, as the closest in the totality of the features of the analogue, allowed us to establish a set of essential distinguishing features in relation to the technical result we see in the claimed device set forth in the claims.

 Therefore, the claimed invention meets the condition of "novelty."

 The results of an additional search for known solutions showed that the claimed invention does not contain features that match the distinctive features of the claimed device from the prototype.

 Therefore, the claimed invention does not follow for a specialist explicitly from the prior art, but is the result of the creative work of the inventors.

 Therefore, the claimed invention meets the condition of "inventive step".

 A device for magnetic pulse processing of planting material of plants is illustrated by drawings, in which Fig. 1 is an electrical block diagram of a device, Fig. 2 is a timing diagram of a device, and Fig. 3 is a circuit diagram of a static DC switch.

 A device for magnetic-pulse processing of planting material of plants contains a network adapter 1, the output of which is connected to the first input of the second switch 2, the second input of which is connected to the positive terminal of the battery 3. Voltage regulator 4, the input of which is connected to the output of the second switch 2, and the output connected to the input of the key 5. DC-DC converter 6, the input of which is connected to the output of the key 5, and the output is connected to the input of the voltage doubler unit 7, the output of the positive polarity of which It is connected to the first outputs of the voltage indicator 8, inductor 9 and the second input of the static DC switch 10, the first input of which is connected to the second output of the inductor 9. The master oscillator 11, the output of which is connected to the input of the frequency divider 12, m outputs of which are connected, respectively, cm inputs of the first switch 13. One-shot 14, the input of which is connected to the output of the first switch 13, and the output is connected to the input of the delay element 15 and the first inputs of the first, third and fifth elements And 16, 17 and 18. The output of the delay element and 15 is connected to the first inputs of the second and fourth elements And 19 and 20. A timer 21, the output of which is connected to the inputs of the digital display unit 22, the element NOT 23 and the second input of the first element And 16, and the output of the element NOT 23 is connected to the second input of the second element And 19.

 The first and second RS-flip-flops 24 and 25, while the S- and R-inputs of the first RS-flip-flop 24 are connected to the outputs of the first and second elements And 16 and And 19. The first output of the first RS-flip-flop is connected with the second inputs of the third and fourth elements And 17 and 20, and the second output is connected to the second input of the fifth element And 18. The output of the third element And 17 is connected to the input of the first amplifier-driver 26. The output of the fifth element And 18 is connected to the R-input of the second RS-trigger 25. The output of the fourth element And 20 is connected to the input of the second amplifier-driver 27 and the S-input of the second RS-trigger 25, the first output of which is connected to the control input of the key 5. Moreover, the first outputs of the outputs of the first and second amplifiers-shapers 26 and 27 are connected, respectively, with the third and fourth outputs of the control inputs of the static DC switch 10, and their second outputs are connected with its zero output, with the negative polarity output of the voltage doubler unit 7 and the second output of the voltage indicator 8. The control panel 28, the output of which is connected via the control bus to the zero control inputs of timer 2 1, voltage doubler unit 7, first and second switches 13 and 2.

 The device operates as follows.

Planting material (seeds, cuttings, etc.) is placed in the inductor 9 (for example, inside a cylindrical coil), then using the control panel 28, pressing its control buttons, specify:
- type of energy source (mains or battery);
- one of the m possible modes of magnetic pulse processing of planting material;
- exposure time.

After that, the device operation rocket is initialized by pressing the "Start" button on the control panel. In this case, the digital display unit 22 indicates the countdown of the exposure time, and a rectangular pulse of duration τ _e is formed at the output of the timer 21 (Fig. 2, item 1), equal to the exposure time selected when setting the modes on the control panel 28.

 A rectangular pulse from the output of the timer 21 is fed to the input of the element NOT 23 and is inverted by it (figure 2, position 2).

The pulses from the output of the master oscillator 11, through the frequency divider 12 with the appropriate division factor, come from its m outputs to the m inputs of the first switch 13. When you select one of the m modes of magnetic-pulse processing from the control panel 28 to the zero control input of the first switch 13 via the bus the control signal receives the selection enable signal, while it passes to its output pulses of only one of the m selected repetition periods - period T _s .

The single-shot 14 generates at its output a sequence of clock pulses of duration τ of the period T _s , and the delay element 15 carries out their delay for the time t _s = τ (Fig. 2, items 3 and 4), necessary to provide control over the operation of the static DC switch 10 and RS flip-flop 24.

Elements And 16 and 19 using clock pulses of the repetition period T _s arriving at their first inputs from the outputs of the single-shot 14 and delay element 15, convert rectangular pulses arriving at their second inputs from the outputs of the timer 21 and the element NOT 23 in their respective bursts pulses (figure 2, items 5 and 6).

The first pulse of the pack from the output of element And 16, received at the S-input of the first RS-flip-flop 24, sets it to state "1", and the first pulse of the pack from the output of element And 16, received at the R-input of the first RS-flip-flop 24, resets it to state "0". As a result, a rectangular pulse of duration τ _and is formed at the first output of the first RS-flip-flop 24, the leading edge of which is synchronized with the repetition period of clock pulses T _s , and the trailing edge is synchronized with clock pulses delayed by time t ₃ (Fig. 2, item 7 )

Elements I 17 and 20, using clock pulses arriving at their first inputs from the outputs of a single-shot 14 and delay element 15, convert a rectangular pulse of duration τ _and arriving at their second inputs from the first output of the first RS-trigger 24 into pulse trains with a number of pulses N ₁ = (τ _and / T _c ) +1 and N ₂ = (τ _and / T _c ), respectively (Fig. 2, items 8 and 9).

From the output of elements And 17 and 20, pulse packets with the number of pulses N ₁ and N ₂ are fed to the inputs of the first and second amplifiers-shapers 26 and 27, which form short control pulses of positive polarity at their first outputs, which are fed to 3 and 4 conclusions of the control inputs of a static DC switch 10, respectively.

As a static DC switch 10, a static DC switch made using thyristors is used (FIG. 3). In this circuit, thyristor VS1 is included in the circuit of inductor 9, and thyristor VS2 is auxiliary. When the control pulse from the output of the amplifier-former 26 is supplied to the control electrode of the thyristor VS1, the thyristor is turned on and the current flows through the inductor 9. The capacitor C is charged through the resistor R and the open thyristor VS1 to the power supply voltage with the polarity indicated in Fig. 3. When the control pulse from the output of the amplifier-former 27 is supplied to the control electrode of the thyristor VS2, it turns on the thyristor VS2, and the capacitor C is connected to the thyristor so that its positively charged lining is connected to the cathode of the thyristor VS1. This voltage turns off the thyristor VS1 and interrupts the current through the inductor 9, provided that the control signal to the control electrodes of both thyristors is not supplied simultaneously, but with a delay of one relative to the other for a time t ₃ (Fig. 2, pos. 8 and 9). The reverse diode VD connected in parallel to the inductor 9 (Fig.3) eliminates the self-oscillation of the current in it.

 Element And 18 with the help of clock pulses arriving at its first input from the output of the single-shot 14, converts the inverted rectangular pulse arriving at its second input from the second output of the first RS-trigger 24 into a packet of pulses (figure 2, item 10).

The second RS-flip-flop 25 is set to state "1" when the first delayed from N ₂ pulses of the packet from the output of the And 20 element arrives at the S-input and goes into state "0" when the pulse arrives at the R-input from the output of the And 18 element. At the same time, it forms at its first output a rectangular strobe pulse of duration τ _c (Fig. 2, item 11), which is fed to the control input of key 5 and opens it. As a result, the DC voltage from the output of the voltage stabilizer 4, through the public key 5, is fed to the input of the DC voltage converter 6 and activates its work in the time interval t _a (Fig. 2, item 12).

The amplitude of the alternating voltage of a high frequency (30-50 kHz) at the output of the DC / DC converter 10 will increase as the pair of series-connected capacitors of the rectifier filter of the rectifier block of the voltage doubler 7 is charged until time t = t _a (Fig. 2, item 12). The filter capacitors of the rectifier of the voltage doubler unit 7 are charged on the opposite halves of the high-frequency voltage period coming from the output of the DC-DC converter 6.

The voltage at the output of the voltage doubler unit 7 is made up of two charge voltages of two series-connected capacitors, which increases up to the time t = t _a (Fig. 2, item 13).

When choosing the magnetic pulse processing mode using a signal from the control unit 28 via the control bus to the zero control input of the voltage doubler unit 7, one of the m pairs of rectifier filter capacitors connected in series is connected. In this case, in each of the m processing modes, the value of the voltage amplitude at the output of the voltage doubler unit 7 at the time t = t _a remains the same.

 The output voltage of the voltage doubler unit 7 is applied to the static DC switch 10 through the inductor 9 to the first input and directly to the second input, as well as to the voltage indicator 8, which is used to control the presence of voltage.

At time t = t _a , from the first output of the first amplifier-driver 26, the second short pulse (Fig. 2, item 8), which opens the first thyristor VS1 of the static switch, enters the third output of the control input of the static DC switch 10 direct current 10 (Fig. 3) and a pair of series-connected capacitors of the voltage doubler unit 7 is discharged for a time t≤t _s (Fig. 2, item 13), which creates a current pulse through the inductor 9 (Fig. 2, item 14 ), causing the appearance of a magnetic impulse in it ktsii.

At time t = (t _a + t ₃ ), the second short pulse arrives from the first output of the second amplifier-driver 27 to the fourth output of the control input of the static DC switch 10 from the pulse train delayed by time t ₃ , which opens the second thyristor VS2 and there is a discharge of the capacitor C previously charged through the resistor R, which reliably closes the thyristor VS1 (Fig. 3), after which a new charge of the pair of filter capacitors of the voltage doubler unit 7 begins.

 The last pulse of the pack (figure 2, pos. 8) finally discharges the pairs of capacitors of the voltage doubler unit 7, and the strobe pulse (figure 2, pos. 11) simultaneously closes the key 5 with its trailing edge, interrupting the power supply to the DC / DC converter 6 , the process stops.

Thus, a packet with n = τ _and / T _c current pulses, causing n magnetic induction pulses with a repetition period of T _s , passes through the inductor 9 during the duration of the strobe pulse of duration τ _c (Fig. 2, item 11).

Claims (1)

 A device for magnetic-pulse processing of planting material, containing a network adapter, a master generator, connected to the input of the frequency divider by the output, the outputs of which are connected to the inputs of the first switch, the output connected to the input of the one-shot, voltage regulator, the output connected to the key input, digital indication unit , an inductor connected by a first output to a first output of a voltage indicator, characterized in that an additional battery, a second switch, a timer, the element is NOT, the first is the fifth element And, the first and second RS-flip-flops and amplifiers-shapers, a delay element, a DC-voltage converter, a voltage doubler unit, a static DC switch and a control panel, and the second switch with the first and second inputs respectively connected to the output network adapter and the positive terminal of the battery, and the output is connected to the input of the voltage regulator, the output of the one-shot is connected to the first inputs of the first, third and fifth elements And and the input a delay element whose output is connected to the first inputs of the second and fourth AND elements, the timer output is connected to the inputs of the digital display unit, the NOT element and the second input of the first AND element, the output connected to the S-input of the first RS-trigger, the output of the element is NOT connected to the second the input of the second element And, the output connected to the R-input of the first RS-trigger, the second output of which is connected to the second input of the fifth element And, and the first output is the second inputs of the third and fourth elements And, the output of the third element And is connected to the input the first amplifier-driver, the output of the fifth element And - with the R-input of the second RS-trigger, the output of the fourth element And - with the input of the second amplifier-driver and the S-input of the second RS-trigger, the first output connected to the control input of the key, the output of which is connected with the input of the DC-DC converter, the output connected to the input of the voltage doubler unit, the output of the positive polarity of which is connected to the second input of the static DC switch and the first output of the inductor, the second output of which is connected nen with the first input of the static DC switch, the zero output of which is connected to the negative polarity output of the voltage doubler unit, with the second output of the voltage indicator, as well as with the second outputs of the first and second amplifiers-shapers, the first outputs of which are connected respectively to the third and fourth the outputs of the control inputs of the static DC switch, and the output of the control panel via the control bus is connected to the zero control inputs of the timer, unit ud oitelya voltage, the first and second switches.

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