Monday, February 27, 2012
Thursday, February 16, 2012
ClO2
Stabilized Chlorine Dioxide Pouch for Odor Control and Disinfection
Stabilized chlorine dioxide is widely known as a superior alternative to chlorine when it comes to sterilization, odor control, and tasks like mold and mildew elimination. Now, with the innovative AquaDry3000 pouch, smaller and medium size industrial and municipal operations can take advantage of all the benefits without the hassle and expense of producing it on-site. It offers unparalleled odor control for hydrogen sulfide (H2S) and other smells with much safer handling than other alternatives. Each pouch mixes with 5 gallons of water to make a solution of approximately 400 ppm of ClO2 which can remain stable for several weeks with proper storage. The blend has 4 times the oxidation power of chlorine and can be used in many capacities including as a biocide, viricide, fungicide, sporicide, disinfectant, sterilizer, and sanitizing agent. If you have wastewater compliance needs, this stabilized chlorine dioxide product can also assist in pH and viscosity stabilization as well as BOD and COD reduction.With these properties, AquaDry3000 easily eliminates the following microorganisms:
- E. Coli
- Legionella
- Pneumophilia
- Streptococcus Facalis Bacillus
- Clostridium
- Amoebae
- Giardia
- Cryptosporidium
- Pseudomonas
This level of versatility also makes it great for a variety of applications including:
- Municipal treatment plants
- Wastewater disinfection
- Water reuse and recycling
- Horticultural irrigation
- Corrugators and paper manufacturers
- Food processing plant sanitation
- Cooling towers
- Mold removal
- Bathroom sanitation and odor control
- Septic tank odor control
- Drinking water disinfection
- Agriculture
- Fruits & vegetable sanitation
- Oxidizing agent
If you’d like more information about our stabilized chlorine dioxide pouch, our Air Relief product for many odor control needs, or wastewater treatment products including our chlorine dioxide generator for larger operations, contact us today.
Sunday, February 12, 2012
CDS
This is a new formulation for MMS (28% sodium chorlite) which may be superior in some cases to the original Jim Humble's MMS formula. View the actual process at:
http://youtu.be/-t2V7NOsnJM
To summaraize this new process:
1) Mix 50cc of 28% sodium chlorite and 50cc of 50% citric acid in a glass (preferred over plastic) bottle which turns into a standard MMS solution (dark brown).
2) run a plastic tube from the MMS bottle over and into the bottom of 500 ml of an ice cold distilled water solution though the video suggess saline.
3) place hot (not boiling) water in a bath container and then place the MMS solution bottle in that hot bath to promote rapid generation of Chorline Dioxide gas.
4) let it generate for approx 30 minutes or until the gas stops bubbling through the tube into the cold (11* C or colder) distilled water solution. Both solutions will reach a similar light yellow color when it is about finished.
1cc of CDS = 3 drops of MMS
This is a way to formulate a weaker solution of MMS whithout having an acid in solution.
It is tasteless and much easier to tolerate than MMS.
Store in dark and refrigeration.
Jim Humbler writes:
To make a 28% MMS sodium chlorite solution from commonly sold 80% Sodium Chlorite Technical Grade powder, do the following. First, let me correct a common misconception here about the supposedly 28% strength of MMS. In reality, it is really 22.4% Sodium Chlorite. Not that it really makes a lot of difference in the general scheme of therapeutics. This discrepancy occurs because MMS is made from an 80% technical grade of Sodium Chlorite and Jim Humble really did not take this into consideration.
Ingredients mixed for a final 28% MMS (22.4%) Solution:
Mix 28 grams of 80% Sodium Chlorite into enough distilled water to get final volume of 100 ml.
Mix 70 grams of 80% sodium chlorite into enough distilled water to get a final volume of 250 ml.
Mix 140 grams of 80% powder into enough distilled water for a final volume of 500 ml.
Mix 280 grams of 80% powder into enough distilled water for a final volume of 1 liter (1000 ml).
------------------------
To make 50 cc or ml of 28% solution:
approx 14 grams of 80% powder in 44 ml of distilled water
----------------------
To make a percentage solution, one would add 28 grams of solute (sodium chlorite) to make 100 ml of solution. This will give a 28% solution. Note, one must first weight out the solute and then add enough water to make the target volume as the solute will itself take up some volume on its own.
The formla for a percentage solution is
Drug weight (X) / finished solution = % strength / 100
Thus, to make100 ml of 28% of sodium chlorite, your formula would be:
X / 100 ml = 28% / 100
X = 100 x 28 / 100
X = 2800 / 100
X = 28 grams to make 100 ml of solution by adding only enough water to make 100 ml
--------------------------------------
A setup which will produce a low concentration (<1000ppm) chemically pure chlorine dioxide solutions for use as instrument standard or for studies where the possibioity of any chlorine contamination must be avoided.
The reaction flask and gas scrubbing tower is filled with 500 ml of approx 2.5% sodium chlorite solution. Place 50 ml of 10% sulfuric acid solution into the reaction flask, 5-10 ml at one time). The reagent bottle in the ice bath is filled with 500-750 ml of deionized water.
Reaction in neutral or alkaline conditions will result in Chlorine Dioxide forming chlorite ion as by-product. Chlorite is the major inorganic by-product of the reaction of chlorine dioxide in water. Usually, the amount of chlorite formed will be 40-60% of the amount of chlorine dioxide which has reacted. For example, if 1.00 ppm of chlorine dioxide is added to water and 10 minutes later, 0.60 ppm remains as a residual, 0.40 ppm has therefore reacted. We can expect the chlorite to be 0.16 - 0.24 ppm
The scrubbing tower above is designed to remove free chlorine from the final CDS fluid. You possibly could only use MMS 1/4 strngth for the scrubber, and one only need senough volume to bubble through.
http://youtu.be/-t2V7NOsnJM
To summaraize this new process:
1) Mix 50cc of 28% sodium chlorite and 50cc of 50% citric acid in a glass (preferred over plastic) bottle which turns into a standard MMS solution (dark brown).
2) run a plastic tube from the MMS bottle over and into the bottom of 500 ml of an ice cold distilled water solution though the video suggess saline.
3) place hot (not boiling) water in a bath container and then place the MMS solution bottle in that hot bath to promote rapid generation of Chorline Dioxide gas.
4) let it generate for approx 30 minutes or until the gas stops bubbling through the tube into the cold (11* C or colder) distilled water solution. Both solutions will reach a similar light yellow color when it is about finished.
1cc of CDS = 3 drops of MMS
This is a way to formulate a weaker solution of MMS whithout having an acid in solution.
It is tasteless and much easier to tolerate than MMS.
Store in dark and refrigeration.
Jim Humbler writes:
To make a 28% MMS sodium chlorite solution from commonly sold 80% Sodium Chlorite Technical Grade powder, do the following. First, let me correct a common misconception here about the supposedly 28% strength of MMS. In reality, it is really 22.4% Sodium Chlorite. Not that it really makes a lot of difference in the general scheme of therapeutics. This discrepancy occurs because MMS is made from an 80% technical grade of Sodium Chlorite and Jim Humble really did not take this into consideration.
Ingredients mixed for a final 28% MMS (22.4%) Solution:
Mix 28 grams of 80% Sodium Chlorite into enough distilled water to get final volume of 100 ml.
Mix 70 grams of 80% sodium chlorite into enough distilled water to get a final volume of 250 ml.
Mix 140 grams of 80% powder into enough distilled water for a final volume of 500 ml.
Mix 280 grams of 80% powder into enough distilled water for a final volume of 1 liter (1000 ml).
------------------------
To make 50 cc or ml of 28% solution:
approx 14 grams of 80% powder in 44 ml of distilled water
----------------------
To make a percentage solution, one would add 28 grams of solute (sodium chlorite) to make 100 ml of solution. This will give a 28% solution. Note, one must first weight out the solute and then add enough water to make the target volume as the solute will itself take up some volume on its own.
The formla for a percentage solution is
Drug weight (X) / finished solution = % strength / 100
Thus, to make100 ml of 28% of sodium chlorite, your formula would be:
X / 100 ml = 28% / 100
X = 100 x 28 / 100
X = 2800 / 100
X = 28 grams to make 100 ml of solution by adding only enough water to make 100 ml
--------------------------------------
A setup which will produce a low concentration (<1000ppm) chemically pure chlorine dioxide solutions for use as instrument standard or for studies where the possibioity of any chlorine contamination must be avoided.
- CDS prep jpg.jpg (9.49 KiB) Viewed 143 times
The reaction flask and gas scrubbing tower is filled with 500 ml of approx 2.5% sodium chlorite solution. Place 50 ml of 10% sulfuric acid solution into the reaction flask, 5-10 ml at one time). The reagent bottle in the ice bath is filled with 500-750 ml of deionized water.
Reaction in neutral or alkaline conditions will result in Chlorine Dioxide forming chlorite ion as by-product. Chlorite is the major inorganic by-product of the reaction of chlorine dioxide in water. Usually, the amount of chlorite formed will be 40-60% of the amount of chlorine dioxide which has reacted. For example, if 1.00 ppm of chlorine dioxide is added to water and 10 minutes later, 0.60 ppm remains as a residual, 0.40 ppm has therefore reacted. We can expect the chlorite to be 0.16 - 0.24 ppm
The scrubbing tower above is designed to remove free chlorine from the final CDS fluid. You possibly could only use MMS 1/4 strngth for the scrubber, and one only need senough volume to bubble through.
Thursday, February 2, 2012
SELS DE SHUESSLER
Bref historique de leur utilisation
En 1872, un médecin homéopathe exerçant à Oldenburg, le docteur Guillaume Schuessler, commença à utiliser, dans sa pratique journalière, les 12 sels fondamentaux entrant dans la composition des tissus animaux et humains. Il estimait que la maladie s'accompagnait d'une carence dans l'un ou plusieurs de ces sels et que donc, l'apport, à l'organisme carencé, du sel manquant, pouvait l'aider à guérir.
Estimant qu'un apport en dose massive pouvait entraîner une intoxication de l'organisme, il décida d'utiliser ces sels en dilution à la sixième décimale, en trituration. Les sels de Schuessler agissent donc suivant le même mode que l'homéopathie (résorption par la voie perlinguale), mais uniquement au niveau organique et fonctionnel, étant donné qu'ils sont utilisés en basses dilutions (D6).
Les sels de Schuessler en D6, agissent donc au niveau 1 et 2. Il n'y a pas de composante psychosensorielle.
| Calcarea Fluorica | Voir la fiche  |
| Calcarea phosphorica | Voir la fiche |
| Calcarea sulfurica | Voir la fiche |
| Ferrum phosphoricum | Voir la fiche |
| Kalium muriaticum | Voir la fiche |
| Kalium phosphoricum | Voir la fiche |
| Kalium sulfuricum | Voir la fiche |
| Magnesia phosphorica | Voir la fiche |
| Natrum muriaticum | Voir la fiche |
| Natrum phosphoricum | Voir la fiche |
| Natrum sulfuricum | Voir la fiche |
| Silicea | Voir la fiche |
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