WO2012144959A1

WO2012144959A1 - Colloidal silver production process and generator

Info

Publication number: WO2012144959A1
Application number: PCT/SK2012/000003
Authority: WO
Inventors: Ladislav SCHOBER
Original assignee: Schober Ladislav
Priority date: 2011-04-20
Filing date: 2012-04-11
Publication date: 2012-10-26
Also published as: CZ2013806A3; DE112012001784T5; DE112012001784B4; SK500192011A3; WO2012144959A4

Abstract

The principle of the Colloidal Silver production is a high frequency A.C. signal with a D.C. offset such that the minimal value of voltage lies above 0 Volts and the signal is amplitude modulated. The Colloidal Silver Generator (1) has inside its case (2) an Electronic Assembly (11) to amplitude modulate the signal between the electrodes (21,22).

Description

Colloidal Silver Production Procedure and Generator Field of the Application

The technique of the Colloidal Silver production is designed mainly for preparation nutritional supplements, disinfectants, antibacterial agents, antiviral agents, antifungal agents mainly in the form of drinks and it includes the design of the Colloidal Silver Generator.

Background to the Invention

Colloidal Silver is produced by electrolysis of distilled water using two electrodes one of which must be made of silver. The quality of Colloidal Silver depends on the purity of the silver electrode (among other factors), therefore silver electrodes of purity 99.99% are being used.

There are two traditional ways of making Colloidal Silver.

In the first case, constant voltage source is used during the electrolysis process while the D.C. current is rising with falling resistance of the distilled water due to the increasingly higher concentration of silver particles in the distilled water. Larger currents ripp out larger particles form the silver elctrode, which is a disadvantage of this method because the most beneficial size of the silver particles lies in a defined range of small to medium size. The health beneficial broad spectrum range lies in a mixture of small to medium size particles.

In the second case, a constant current source is used in the electrolysis and the voltage changes with decreasing resistance of the silver particle filled distilled water. Since the size of the silver particles depends on the amount of current between the electrodes and the the current does not change, the silver particles produced are all of similar size. That is a disadvantage of this method as the most health beneficial particle mix is in a defined range of small to medium size silver particles.

Another method of making Colloidal Silver uses A.C. voltage with zero D.C. offset with minimal voltage set at 0 Volts.

A known examlpe of a Colloidal Silver device, utility model DE 202004000770 UI, consists of a plastic cover of a distilled water vessel through which two electrodes

secured by fasteners protrude into the vessel and are connected by bipolar plug to a power source. The disadvantage of this device is that it uses only one of the already described methods for Colloidal Silver production, either the constant voltage method or the constant current method. Another known Colloidal Silver device, patent number AT 414533B, uses retractable electrode holders which can be retracted into the device case during inactivity periods. There is no description of any electrical signal associated with this device. .

Brief Summary

The technical principle of the invention supports the production of a defined range of silver particles and it is the basis of the Colloidal Silver Generator.

The shortcomings of the previous methods of Colloidal Silver production have been largely removed from the way the Colloidal Silver is made - electrolysis of distilled water by two electrodes at least one of which is made from silver of high purity with a modulated high frequency A.C. voltage and a D.C. offset such that the minimum value of the signal lies above 0 Volts.

The A.C. voltage has a constant frequency and amplitude or it has a constant frequency and changing amplitude. The amplitude changes in accordance with a low frequency signal.

The bulk of the Colloidal Silver manufacturing equipment is built into a case to which two demountable electrodes are connected. The case is connected to a power source via an adapter. Inside the case is an electronic assembly, which produces and modulates an electric signal between the main electrode and the secondary electrode. The electronic assembly contains a filter connected via a high frequency generator and an amplifier to the electrodes. The modulator on the electronic assembly is placed between the amplifier and the electrodes and it is also connected to a low frequency generator, which is connected to a filter.

There is an LED power on indicator on the case.

Brief Description of the Drawings

The Figures demonstrate the design.

Figure I shows the setup for the making of Colloidal Silver

Figure 2 shows the basic Block Diagram of the electronic setup

Figure 3 shows the Block Diagram of the Electronic Assembly with the Amplitude

Modulation circuit

Figure 4 shows the make-up of Amplitude Modulation signals Detailed Description of the Invention

Example 1

The Carrier

The carrier is a high frequency signal with a square, sine or triangle waveform and has a constant voltage of 12 Volts.

Example 2

The Amplitude Modulated Signal

The carrier amplitude takes the shape of the low frequency modulating signal waveform while keeping its high frequency. Both the carrier and the modulating signal have the same peak voltage. The shape of the modulating signal can be a sine or a triangular waveform.

Figure 4 is an example of Amplitude Modulation. The carrier is a square wave of frequency 100 Hz and the modulating signal is a triangular wave of frequency 5 Hz. The resultant amplitude modulated signal is a triangular waveform of frequency 5 Hz, which is made up of square wave of frequency 100 Kz.. One period of the triangular wave is made up of twenty periods of square wave.

Example 3

During the manufacturing of Colloidal Silver particles of silver start to get ripped out of the electrode into the distilled water at around 2 Volts and therefore it is inefficient to have the signal between the electrodes start at 0 Volts. It is more efficient to have the signal start at 2 Volts by providing a further D.C offset. This D.C. offset refers also to Example 1 and 2.

The advantage of using a signal with amplitude modulation lies in the fact that even at larger average currents, small particles are still being produced as one period of the signal contains a mixture of high and low voltages, which are proportional to currents by Ohm's Law. The D.C. offset saves time as the signal does not drop down to zero Volts. The ripping of silver particles into the water is very low or non existant between zero and two Volts and if the signal does not go below 2 Volts, silver particles are being produced all the time.

Claims

C L A I M S

1. Colloidal Silver Production Procedure using electrolysis of distilled water by two electrodes at least one of which is made of high purity silver characterized by a high frequency A.C. signal with a D.C. offset between the electrodes such that the minimum voltage of the signal is above 0 Volts and the signal is modulated.

2. Production procedure in accordance with Claim I, characterized by an A.C. signal with constant frequency and amplitude.

3. Production procedure in accordance with Claim I, characterized by an A.C. signal with constant frequency and changing voltage amplitude.

4. Production procedure in accordance with Claim 1 and 3, charakterized by a signal amplitude changing with a low frequency signal.

5. Colloidal Silver production equipment in accordance with Claim 1 to 4 built into a case (2) to which two demountable electrodes are connected a which is connected to a power adapter, characterized by the presence of an electronic assembly (II) inside the case, which modulates the signal between the main (21) and the secondary electrode (22) and which is minimally composed of a filter (I I I) connected via high f equency generator (112) and an amplifier (113) to the electrodes (21,22).

6. Equipment in accordance with Claim 5, characterized by a modulator (115) placed between the amplifier (113) and the electrodes (21,22) on the electronic assembly (I I) to which is connected a low frequency generator (114) and the generator is connected to a filter (I I I).

7. Equipment in accordance with Claim 5 or 6, characterized by and LED power on indication aperture (13) on the case (2).