DISTILLED WATER - PREPARATION, GRADES, RISKS, STORAGE, PURITY, DETECTION OF IMPURITY, USES.pptx

DISTILLED WATER Dr. ASWIN ANANDH. M PG SCHOLAR HOMOEOPATHIC PHARMACY

CHEMICAL FORMULA - H₂O SYNONYMS - Aqua purificata, Aqua destillata or purified water Molecular weight: 18. pH: Neutral. Boiling point: 100 °C. Density at 4°C: Unit. Critical temperature: 374.2 °C. Note: Ordinary water may contain many organic and inorganic substances, therefore they are not fit for medicinal purposes.

Distilled water is water that has been boiled into vapor and condensed back into liquid in a separate container. Distilled water is steam from boiling water that’s been cooled and returned to its liquid state. Steam is then condensed back into pure liquid form. The impurities remain as residue and are removed. Some people claim distilled water is the purest water you can drink. Distilling rids water of all those impurities. It also removes more than 99.9% of the minerals dissolved in water. It is suitable for drinking, medical sterilization, and manufacturing processes where the buildup of minerals needs to be avoided.

PREPARATION Of Distilled water

For small quantity Distillation process Deionisation process For larger quantity Automatic water distillator

DISTILLATION process

APPARATUS REQUIRED Leibig's condenser: It consists of an inner tube surrounded by an outer jacket or a water tube. This outer jacket has 2 openings at both it's end for the entry and exit of cold water. The lower end is attached to a water tap through a rubber tube. The water enters from here, cools the inner tube and then finally comes out through the second, upper end. 2. Flask:One distilling, round bottomed flask, One receiving flask 3. Bunsen burner. 4. Wire gauge. 5. Tripod stand. 6. Rubber cork. 7. Thermometer. 8. Clamp and stand.

To prepare purified water by distillation process, water (1000 volumes) is distilled from a suitable apparatus (like Leibig's apparatus). provided with a glass collect the first 100 volumes and reject this portion. Then collect 750 volumes and keep the distilled water in glass-stoppered bottles that have been rinsed with steam or very hot water immediately before being filled. The first 100 volumes are discarded to eliminate foreign volatile substances found in ordinary water and only 750 volumes are collected, since the residue in the still contains concentrated dissolved solids. The steps to be followed are: The distillating flask containing ordinary water for distillation is put upon a wire gauge, which is placed upon a tripod stand and clamped. One end of Liebeg's condenser is connected with this distilling flask while the other end is introduced into the receiver flask; in which purified water is collected.

3. The mouth of the distilling flask is closed with a rubber cork. A thermometer may be inserted into the cork for noting the temperature of the issuing vapor. The flask may be kept in position with the help of a clamp and stand.

4. Compression distillation Light the bunsen burner below the distilling flask. In vapour compression still or Leibig’s condenser the feed water is heated in the evaporator to boiling. As the water boils, the issuing vapour passes through the inner tube, which is kept cold by a circulation of cold water through the outer jacket. The vapour produced in the tubes is separated from the entrained distilland in the separator and conveyed to a compressor that compresses the vapour and raises its temperature to approximately 224°F. It then flows to the steam chest where it condenses on the outer surfaces of the tubes containing the distilland; thereby the vapour is condensed and drawn off as a distillate while giving up its heat to bring the distilland in the tubes to the boiling point. Then, the distilled water is collected in the receiver. This is purified water. It may be redistilled, if necessary.

DEIONISATION PROCESS

By this process, water is freed of acids, alkalis. solids, minerals, etc. The major impurities in water are calcium, iron, magnesium, silica and sodium. The cations are usually combined with bicarbonate, sulphate or chloride anions. Hard waters are those that contain calcium and magnesium cations. Bicarbonates are the major impurity in alkaline waters'. Ion exchange (deionisation, demineralisation) processes remove most of the major impurities in water efficiently and economically. Ion-exchange resins are synthetic substances which exchange other cations and anions from a solution of hydrogen ions and hydroxyl ions respectively.

Hence, they are of two types: Cation-exchange Resins or Cation-exchangers: These are those resins which replace cations with hydrogen ions. Cation exchangers are commonly high molecular weight, they contain acidic mobile ions or functional groups such as sulphonated organic compounds (-SO,H), carboxylic group (-COOH) and phenolic group (-OH). E.g., ZeokarbH, Zeokarb 225 or Amberlite IR-120 resin.

2) Anion-exchange Resinsor Anion- exchangers: These are those resins which exchange anions by hydroxyl groups. Anion exchangers are hydroxyl compounds which are derived from high molecular weight organic amines and contain basic functional groups such as amino group (-NH,), quaternary ammonium group and halides. E.g., Amberlite IRA-400 or DeAcidite FF or Zeolite FF resin.

Apparatus Required: Cation exchanger. Anion exchanger. Procedure: Impure water containing salts like calcium, magnesium, etc. is passed through columns containing a cation exchanger. As the impure water passes through, all the metallic ions including alkali metal ions are replaced by hydrogen ions. Hence, an equivalent amount of acid is formed to the corresponding anions of the metal salts. Reaction of chlorides and sulphates of metals is as follows: CaCl2 + 2HR→ R,Ca + 2HC1MgSO4 + 2HR → R,Mg + H2SO4 where HR is the cation exchanger.

3. The water so obtained is entirely free from metal ions but is acidic and is hence not suitable for most purposes. 4. This acidic water is now passed through a column containing an anion exchanger to replace the anions of the acids with hydroxyl groups, forming water.The reaction taking place is: HCI + RNOH → RNCI + H₂O= H₂SO, + 2RNOH → (RN),SO, 2H,O, where RNOH is the anion exchanger (basic or hydroxide form). This passage of impure water through the cation and anion exchangers one after the other e produces pure water free from ions. This pure water is called deionised or de-mineralised water. It is as good as purified water for all e purposes.

AUTOMATIC WATER DISTILLATOR

Water is purified by this process for large scale commercial purposes. A stainless steel vessel known as 'still' is used. Here, the distillation and cooling are done by the same water. Procedure : A wide variety of commercially available stills are used to produce water. The end use of the product dictates the size of the still and extent of pretreatment of the water introduced into the system. In general, a conventional still consists of a boiler (evaporator) containing raw water (distilland); a source of heat to vapourise the water in the evaporator, a space above the level of distilland with condensing surfaces for refluxing the vapour and thereby returning non- volatile impurities to the a means for eliminating volatile impurities before the hot water vapour is condensed; and a condenser for removing the heat of vapourisation, thereby converting the water vapour to a liquid distillate.

Some of the cooling water goes through some holes into the heating chamber where steam is produced. This steam passes to the inner chamber through a passage on the top and then comes down for cooling. The cool water exits out through an overflow.

MULTIPLE EFECT STILL

The multiple-effect - still is designed to conserve energy. According to this principle, it is simply a series of single- effect stills running at different pressures. A series of upto 7 effects may he used, with the first effect operated at the highest pressure and the last effect at atmospheric pressure. Steam from an external source is used in the first effect to generate steam under pressure from raw water; it is used as the power source to drive the second effect. The steam used to drive the second effect condenses as it gives up its heat of vapourisation and forms a distillate. This process continues until the last effect when the steam is at atmospheric pressure and must be. condensed in a heat exchanger.

Ammonia : To 50ml, add 2ml of alkaline potassium mercuri-iodide solution and view in a Nessler cylinder placed on a white tile; the colour is not more intense than that given by 50ml of ammonia-free water with the addition of 2m1 of dilute ammonium chloride solution (Nessler’s) when tested under similar conditions. Oxidisable matter: Boil 100ml for 10 minutes with 3m1 of sulphuric acid and Iml of 0.01N potassium permanganate; the colour of potassium permanganate is not completely discharged.

GRADES OF DISTILLED WATER

TYPE 1 GRADE WATER Type I grade water, also known as Ultrapure Wat er, is the purest form of water to be produced. It's used for the most critical applications and advanced analytical procedures.This includes: Cell and Tissue Cultures Liquid Chromatography, including High Performance Liquid Chromatography (HPLC) Gas Chromatography Inductively Coupled Plasma Mass Spectrometry (ICP-MS) Molecular Biology Type I can also be used in applications that require Type II water. This is quite a common practice that can help to avoid the generation of by-products during applications.

TYPE 2 GRADE Type II water grade doesn't have the same pureness of Type I, but still maintains high levels of purity. It is a good feed water for clinical analyzers as the calcium build-up is reduced with this type. It can also be used in applications such as: General Lab Practices Microbiological Analysis and preparation Electrochemistry FAAS General Spectrophotometry It can also be used as feed water for Type I water production.

TYPE 3 GRADE Type III grade water, also known as RO water, is water produced through the purification technology reverse osmosis. Of all the pure water types it has the lowest level of purity, but is typically the starting point for basic lab applications, such as cleaning glassware, heating baths or media preparation. It can also be used as a feed water for Type I water production.

RISKS OF USING DISTILLED WATER

Experiments reviewed in the WHO study indicated consumption of pure distilled water led to increased urine output or diuresis of around 20% on average. This could lead to dehydration problems. The absence of important minerals in distilled water (sodium, potassium, chloride, calcium, and magnesium ions) led to the dilution of electrolytes dissolved in the body's water. The intestine requires these minerals and takes them from the body's reserves. This causes inadequate body water redistribution between which may compromise the function of vital organs. Symptoms at the very beginning of this condition could include exhaustion, weakness, and headache and can escalate to muscular cramps and impaired heart rate.

PH OF DISTILLED WATER

The pH of distilled water ranges from 5.8 to 7. Pure distilled water in a sealed system has a pH of 7, but as soon as it is exposed to the air it begins to absorb atmospheric gasses including CO2 and starts to become acidic. If any trace elements are left in the water after distillation, this can also alter the pH.For a pH definition, the simplest explanation is that the pH of water measures the degree of its acidity or basicity (alkalinity), and is expressed on a scale of 0 to 14. Water with a pH of 7 is neutral. "PH" less than 7 is acidic, with O the most acidic. More than 7 is basic or alkaline, with 14 the most basic. This graphic shows the pH levels of different types of drinking water.

IS IT SAFE TO USE DISTILLED WATER..?

It is safe to drink distilled water according to the 1980 guidelines by WHO. Distilled water is safe for drinking, but it can have negative taste characteristics and does not contain healthy minerals. The same report goes on to mention that distilled water is reported to be less thirst-quenching and that although this is not considered to be unhealthy, poor organoleptic and thirst- quenching characteristics may affect the amount of water consumed.

According to the Centers for Disease Control and Prevention (CDC), the distillation process is very effective at removing protozoa (such as cryptosporidium or giardia), bacteria (such as campylobacter, salmonella, shigella, E. coli), and viruses (including enteric, hepatitis A, norovirus, and rotavirus). Distillation also removes chemical contaminants, including arsenic, barium, cadmium, chromium, lead, nitrate, sodium, sulfate, and many organic chemicals, according to the CDC.

STORAGE OF DISTILLED WATER

Purified water must be filled at once into well-stoppered bottles that are thoroughly cleaned in hot water. Attention should be paid to proper storage of purified water, since it can often be contaminated by the materials of the containers. Hard glass containers may furnish boron, sodium, silica and traces of lead, arsenic and potassium, Pyrex glass qualifies well. Metal containers are also liable to attack by purified water. Polyvinyl chloride polythene, teflon and urethane containers are also good. However, a variety of compounds like antioxidants, surfactants and lubricants that are used in the manufacture of plastics may contaminate water, which may prove to be toxic.

PURITY OF WATER

Conductivity: Typically used for less pure water types (Type III and Type IV), conductivity measures the ease with which a water sample conducts electricity. Because electricity is conducted through ionic content in water, conductivity measures how much of this content is present.

Resistivity: Normally used for more pure water types (Type I and Type II), resistivity measures how difficult it is for electrical current to travel through a water sample. The more difficult it is (and the higher resistance), the less ionic content is in the water, making for a purer sample.

Total organic carbon (TOC): Totalorganic carbon is an efficient way to measure the amount of organic material present in water through carbon testing. As an aggregate reading, total organic compound provides an accurate general measurement of the purity of a water sample in terms of microorganisms and other organic material present.

Turbidity: Turbidity or water clarity is able to provide a rough sense of water purity in terms of contaminants and other material present. It is useful for the lower purity grades - Type III and Type IV.

DETECTION OF IMPURITY Purified water may be detected by its physical properties: It is a colourless, odourless, tasteless liquid. 2. pH should not vary more than 5.8 to 7. By boiling point, freezing point and density. Water leaves no residue on evaporation. Purified water may be detected by some chemical tests also. It gives no precipitate when treated with barium chloride or silver nitrate or hydrogen sulphide. CuSO4 (anhydrous copper sulphate) powder reacts with water to give a blue colour. Potassium reacts with water to give hydrogen which undergoes combustion.K+2H,O→KOH +H₂↑

Acidity or alkalinity: Boil 100ml in a flask made of boro-silicate glass until volume is reduced to 75ml and cool with precautions to exclude carbon dioxide. To 20ml. add 1 drop of phenol-red solution. If the solution is yellow, it becomes red on adding 0.1ml of 0.1N sodium hydroxide; if red, it becomes yellow on adding 0.1ml of 0.IN hydrochloric acid. Copper, iron, lead: To 100ml, add 0.05ml of sodium sulphide solution, the liquid remains clear and colourless.

Albuminoid ammonia: To 500ml, add 0.2gm of magnesium carbonate and distill 200m1. Reject the distillate, add 2mlof alkaline potassium permanganate solution and distill 100ml. To this distillate, add 4m1 of alkaline potassium mercuri-iodide solution; the colour produced is not deeper than that produced by the addition of 4ml of alkaline potassium mercuri-iodide solution to a mixture of 100ml of ammonia- free water and 4m1 of dilute ammonium chloride solution.

Non-volatile matter: Leaves not more than 0.001% w/v of residue when evaporated to dryness on a water bath and dried to constant weight at 105°

COMMON USES OF DISTILLED WATER

Medical tools and procedures. Hospitals clean equipment with it to help avoid contamination and infections. Kidney dialysis machines use ultra-pure water to filter waste from blood. Lab tests. Nothing in distilled water reacts with or affects the accuracy of lab experiments. Cosmetics. If water is an ingredient in your moisturizer, deodorant, or shampoo, it’s almost always distilled. Automobiles. Since it lacks minerals, distilled water won’t corrode metal engine parts or interfere with batteries.

Infant formula. Mix it with infant formula if your baby has weak immunity. Otherwise, tap water is fine. CPAP machine. Fill the water chamber for a CPAP humidifier if you use it for sleep apnea. Many manufacturers recommend distilled water to make the humidifier last longer. Neti pot. Use it with a neti pot to clear your sinuses. Iron. Use it in your clothes iron to prevent scale buildup. Shampoo your hair. Fluoride, chlorine, and other additives in the water from your shower may dull your hair.

HOMOEOPATHIC UTILITY OF DISTILLED WATER

Its tastelessness. freedom from irritating qualities and lack of pharmacological activity, makes water a unique vehicle in homceopathy. Pharmaceutics and Potentization: It is used for preparation of aqueous mother solutions of drug substances that are insoluble in alcohol, according to Class VA and Class VB. It may also be a part of the menstrum used to tinctures,according to the new method of preparation of mother tinctures. It is used to convert solid trituration potency (3C, 6X) into a liquidpotency for succussions (4C, 8X). It is used to prepare the mother solution for fifty millesimal scale.

B. External Applications: It is an ingredient for many external applications, like lotions,glyceroles, preparation of tincture of soap, gargles, mouthwashes,applications for instillation into the eye, like ear drops, eye drops,inhalations, vaginal and urethral injections, preparation of opodeldoes, plasters, hot fomentation, cold fomentation and ice packs.

C.Dispensing of Medicines It is a good vehicle for dispensing of homoeopathic medicines and placebo. The only disadvantage of water is that aqueous solutions are unstable and cannot be preserved for a long time.Medication of water and its importance. Dispensing of medicines in water has the advantage that it touches many nerves Excitable and hypersensitive patients respond better with the dose inwater. Deviated doses can be done only with water. Medicines prepared according to LM are dispensed only in water. Water is the vehicle of choice in comatose and unconscious patients and in small babies.

D. Miscellaneous: Water is used to prepare different strengths of alcohols. Water is used as water for injection. For cleansing of pharmaceutical utensils

THANK YOU

DISTILLED WATER - PREPARATION, GRADES, RISKS, STORAGE, PURITY, DETECTION OF IMPURITY, USES.pptx

About This Presentation

Slide Content

Tags

Categories

Download

Quick Actions

Statistics

Related Slideshows

DISTILLED WATER - PREPARATION, GRADES, RISKS, STORAGE, PURITY, DETECTION OF IMPURITY, USES.pptx

About This Presentation

Slide Content

Slide 1

Slide 2

Slide 3

Slide 4

Slide 5

Slide 6

Slide 7

Slide 8

Slide 9

Slide 10

Slide 11

Slide 12

Slide 13

Slide 14

Slide 15

Slide 16

Slide 17

Slide 18

Slide 19

Slide 20

Slide 21

Slide 22

Slide 23

Slide 24

Slide 25

Slide 26

Slide 27

Slide 28

Slide 29

Slide 30

Slide 31

Slide 32

Slide 33

Slide 34

Slide 35

Slide 36

Slide 37

Slide 38

Slide 39

Slide 40

Slide 41

Slide 42

Slide 43

Slide 44

Slide 45

Slide 46

Slide 47

Slide 48

Slide 49

Slide 50

Slide 51

Slide 52

Slide 53

Tags

Categories

Download

Quick Actions

Statistics

Related Slideshows

Pray For The Peace Of Jerusalem and You Will Prosper

Don_t_Waste_Your_Life_God.....powerpoint

VILLASUR_FACTORS_TO_CONSIDER_IN_PLATING_SALAD_10-13.pdf

Fertility awareness methods for women in the society

Chapter 5 Arithmetic Functions Computer Organisation and Architecture

syakira bhasa inggris (1) (1).pptx.......