Method for treating liquids with alternating electromagnetic field

Abstract

A method of processing a liquid by an alternating electromagnetic field includes: generating DC pulses by a pulse generator; and applying the DC pulses to a parallel oscillating circuit connected in parallel to the pulse generator. The parallel oscillating circuit includes an inductor connected in parallel to a capacitor. In response to the DC pulses, self-oscillations arise in the parallel oscillating circuit, the self-oscillations producing an alternating current in the inductor; and the inductor generates the alternating electromagnetic field for processing the liquid.

Claims

1. A method of processing a liquid by an alternating electromagnetic field, the method comprising: generating and outputting DC pulses by a pulse generator; and applying the DC pulses to a parallel oscillating circuit connected to the pulse generator, wherein a repetition rate of the DC pulses output by the pulse generator does not depend on a resonance frequency of the parallel oscillating circuit, the parallel oscillating circuit includes an inductor connected in parallel to a capacitor, and in response to the DC pulses: self-oscillations arise in the parallel oscillating circuit, the self-oscillations producing an alternating current in the inductor that has a frequency different from the repetition rate of the DC pulses output by the pulse generator, and the inductor generates the alternating electromagnetic field for processing the liquid.

2. The method of claim 1, wherein the liquid includes fuel.

3. An apparatus for processing a liquid by an alternating electromagnetic field, the apparatus comprising: a pulse generator configured to generate and output DC pulses; and a parallel oscillating circuit electrically connected to the pulse generator and configured to be subjected the DC pulses generated by the pulse generator, wherein a repetition rate of the DC pulses output by the pulse generator does not depend on a resonance frequency of the parallel oscillating circuit, wherein the parallel oscillating circuit comprises: a capacitor, and an inductor connected in parallel to the capacitor, wherein, in response to the DC pulses: self-oscillations arise in the parallel oscillating circuit, the self-oscillations producing an alternating current in the inductor that has a frequency different from the repetition rate of the DC pulses output by the pulse generator, and the inductor generates the alternating electromagnetic field for processing the liquid.

4. The apparatus of claim 3, wherein the liquid includes fuel.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 schematically shows representative component parts of an apparatus, according to an embodiment.

(2) FIG. 2 illustrates a self-oscillation process in a parallel oscillating circuit when exposed to DC pulses from a pulse generator according to an embodiment.

DESCRIPTION

(3) Embodiments provide for processing of liquids with an alternating electromagnetic field in order to change physical properties and improve consumer quality of the liquids. The technical solution is to use a device including of a pulse generator A1, e.g., a DC pulse generator, and a parallel oscillating circuit A2 connected to the DC pulse generator and including an inductor L having an inductance, and a capacitor C5 having a capacitance (FIG. 1). When a parallel oscillating circuit A2 is subjected to the DC pulses from a pulse generator A1, the inductor L of the parallel oscillating circuit A2 generates an alternating electromagnetic field which is used for processing of liquids. When exposed to each DC pulse from a pulse generator A1, the inductor L of a parallel oscillating circuit A2 accumulates energy, which, after the end of the impact of the DC pulse, is transmitted to capacitor C5. As a result, reactive energy arises, which circulates inside the parallel oscillating circuit A2: in one part of the period the energy of the magnetic field of the inductor L is converted into the energy of the electric field of the capacitor C5, in the other part of the period the reverse occurs. In parallel oscillating circuit A2 arise self-oscillations, which produce alternating current in an inductor L, and, as a result, the inductor L generates an alternating electromagnetic field. Due to the internal resistance of the circuit of the parallel oscillating circuit A2, the self-oscillation amplitude decreases in time in each period. Next, the next DC pulse comes from the pulse generator A1, and the process repeats, as shown in FIG. 2. As a result of the self-oscillation in a parallel oscillating circuit A2, the generating of an alternating electromagnetic field by the inductor L continues without the application of external energy, by using the energy accumulated in the parallel oscillating circuit A2. The frequency of self-oscillations of a parallel oscillating circuit A2 depends on the parameters of the components of its inductance and capacitance. The frequency of the pulse generator A1 does not depend on the frequency of self-oscillations in the parallel oscillating circuit A2. For maximum processing efficiency of liquids, the frequency of the pulse generator A1 is chosen such that the next DC pulse acts on the parallel oscillating circuit A2 before the end of its self-oscillations in the previous period.

(4) For exposure of alternating electromagnetic field directly on liquids, the inductor L of the parallel oscillating circuit A2 may be immersed in them. The inductor L, capacitor C5 of the parallel oscillating circuit A2 and the pulse generator A1 are connected in an electrical circuit. When it is difficult to become immersed in liquids, the inductor L of the parallel oscillating circuit may be placed directly on the external wall(s) of pipeline(s) and/or tank(s) made of dielectric materials. The inductor L and the capacitor C5 of the parallel oscillating circuit A2 and the pulse generator A1 are located both in one body, e.g., a housing, and separated into two circuits which are electrically interconnected.

(5) The embodiments differ from the related art by using a device capable of generating an alternating electromagnetic field resulting from self-oscillations in the parallel oscillating circuit A2 by application of the DC pulses from the pulse generator A1.

(6) As a result of an application of the method according to an embodiment, the liquid(s) show an enhanced fluidity. The conclusion about the enhanced fluidity of water processed according to the method of an embodiment is based on the results of the carried out experiment. At production of two identical samples, the concrete was used identical of the cement-sand mix and water from one source. The unprocessed water and water processed by the exemplary method was added to the first and second mix accordingly. To obtain the same viscosity of concrete samples, the water treated by the exemplary method required 15% less volume. The conclusion about the enhanced fluidity of the petrol is based on the results of the experiment with a car with a gasoline-powered internal combustion engine. The initial vehicle engine power characteristics were recorded by chassis dynamometer system. Gasoline was processed using a device that is used in the inventive method and was installed on the outer wall of the fuel hose laid to the car engine. After 1000 km logged, the control characteristics were recorded by the chassis dynamometer system. At the engine rpm speed in the range of 1500-2500 rpm, the 15-20% power ascension about initial characteristics was detected. At the engine rpm speed in the range of 2500-5000 rpm, the 8-10% power ascension about initial characteristics was detected. Based on the results, it was concluded, that after the processing via the exemplary method the petrol gains the enhanced fluidity, much better dissipates and combusts more completely in a compression chamber therefore enhancing the horsepower of the internal combustion engine.

(7) As described above, the device for processing of liquids with an alternating electromagnetic field is made of a pulse generator A1 connected to a parallel oscillating circuit A2. The parallel oscillating circuit A2 includes a capacitor C5, as a capacitance, and an inductor L, as an inductance. As an example, the pulse generator A1 may include a controller D1 type NE555. NE555 is an integrated circuit chip (IC chip) which can be used in different types of timers. For example, the pulse generator A1 further includes the following capacitors and resistors having exemplary values as follows:

(8) a first capacitor C1—2200 μF×25V;

(9) a second capacitor C2—0.1 μF;

(10) a third capacitor C3—0.1 μF;

(11) a fourth capacitor C4—0.1 μF; and

(12) a first resistor R1—57 kΩ; and

(13) a second resistor R2—1.5 kΩ.

(14) The value of the capacitor C5 may be 4.7 μF. The pulse generator A1 further includes a transistor Q1, for example, a MOSFET IRF3205.

(15) The pulse generator A1 may be a unipolar DC pulse generator with a low output resistance. The parallel oscillating circuit A2 is produced from the parallelly connected capacitor C5 and inductor L made of insulated wire. If the increase of the inductance value is required, an inductor L core may be used. In this case, the alternating electromagnetic field used for processing of the liquid is emitted from the poles of the core. At low natural frequency of the parallel oscillating circuit A2 fluctuations, a core is produced from low-coercivity materials such as iron. At high natural frequency of the parallel oscillating circuit A2 fluctuations, a core is produced from ferrite materials. The parallel oscillating circuit A2 and pulse generator A1 are parallely connected by the electric circuitry (FIG. 1). The pulse generator A1 is powered from an external power source, for example, a 12 VDC power source.

(16) In an embodiment, the pulse generator A1 generates DC pulses based on a timer NE555. 100 Hz frequency is used, adjusted by a series circuit made of a second capacitor C2 and a first resistor R1. The duration of the DC pulses used is 0.12 ms, adjusted a series circuit made of a fourth capacitor C4 and a second resistor R2. The first capacitor C1 is a polar capacitor that accumulates energy between the DC pulses. A MOSFET is used as a transistor Q1 with a low resistance in the open position. The inductor L is wound on a round core made of iron (d=8 mm, l=30 mm) using insulated copper wire (d=0.5 mm) and contains, for example, about 50 turns. All elements are electrically connected as shown in FIG. 1. For the processing of the liquids, the alternating electromagnetic field emitted by one of the inductor L poles is applied.

Method for treating liquids with alternating electromagnetic field

Assignee

Inventors

Cpc classification

Classification Explorer

B01J19/087

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

H03K5/003

ELECTRICITY

Classification Explorer

C02F1/487

CHEMISTRY; METALLURGY

Classification Explorer

C10G32/02

CHEMISTRY; METALLURGY

Classification Explorer

C02F2201/46175

CHEMISTRY; METALLURGY

Classification Explorer

B01J2219/0877

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

C02F1/48

CHEMISTRY; METALLURGY

Classification Explorer

C02F2201/4617

CHEMISTRY; METALLURGY

International classification

Classification Explorer

B01J19/08

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

H03K5/003

ELECTRICITY

Abstract

Claims

Description