Cold Drinks and Milk
*Introduction* The era of cold drinks began in
1952 but the industrialization in India marked its beginning with launching of
Limca and Goldspot by parley group of companies. Since, the beginning of cold
drinks was highly profitable and luring, many multinational companies launched
their brands in India like Pepsi and Coke. Now days, it is observed in general
that majority of people viewed Sprite, Fanta and Limca to give feeling of
lightness, while Pepsi and Thumps Up to activate pulse and brain.
*Theory* Cold drinks of different brands are composed of
alcohol, carbohydrates, carbon dioxide, phosphate ions etc. These soft drinks
give feeling of warmth, lightness and have a tangy taste which is liked by
everyone. Carbon dioxide is responsible for the formation of froth on shaking
the bottle. The carbon dioxide gas is dissolved in water to form carbonic acid
which is also responsible for the tangy taste. Carbohydrates are the naturally
occurring organic compounds and are major source of energy to our body. General
formula of carbohydrates is CX (H2O)Y. On the basis of their molecule size
carbohydrates are classified as:- Monosaccharide, Disaccharides and
Polysaccharides. Glucose is a monosaccharide with formula C6H12O6 .It occurs in
Free State in the ripen grapes in bones and also in many sweet fruits. It is
also present in human blood to the extent of about 0.1%. Sucrose is one of the
most useful disaccharides in our daily life. It is widely distributed in nature
in juices, seeds and also in flowers of many plants. The main source of sucrose
is sugar cane juice which contain 15-20 % sucrose and sugar beet which has
about 10-17 % sucrose. The molecular formula of sucrose is C12H22O11. It is
produced by a mixture of glucose and fructose. It is non-reducing in nature
whereas glucose is reducing. Cold drinks are a bit acidic in nature and their
acidity can be measured by finding their pH value. The pH values also depend
upon the acidic contents such as citric acid and phosphoric acid.
*Aim*
Comparitive Study and Qualitative Analysis of
different brands of Cold Drinks available in market.
*Apparatus*
Test Tubes Test Tube Holder Test
Tube Stand Stop Watch Beaker Bunsen Burner pH Paper Tripod Stand China Dish
Wire Gauge Water Bath
*Chemicals Required*
Iodine Solution Potassium Iodide
Sodium Hydroxide Lime Water Fehling’s A & B Solution Concentrated Nitric
Acid Benedict Solution Ammonium Molybdate
*Detection Of pH*
Experiment Small samples of cold
drinks of different brands were taken in a test tube and put on the pH paper.
The change in colour of pH paper was noticed and was compared with standard pH
scale. Observation Sr. No. Name Of The Drink Colour Change pH Value 1 Coca Cola
Pinkish 2 – 3 2 Sprite Dark Orange 3 3 Limca Light Orange 4 5 Fanta Orange 3 –
4 Inference Soft Drinks are generally acidic because of the presence of citric
acid and phosphoric acid. pH values of cold drinks of different brand are
different due to the variation in amount of acidic content.
*Test For Carbon Dioxide*
Experiment As soon as the bottles
were opened, one by one the samples were passed through lime water. The lime
water turned milky.
Inference
All the soft drinks contain dissolved carbon dioxide in water. The carbon
dioxide (CO2) dissolves in water to form carbonic acid, which is responsible
for its tangy taste.
Chemical Reaction Ca(OH)2 (s) + CO2 (g) → CaCO3 (s) +
H2O(l)
*Test For Glucose* Experiment Glucose is a reducing sugar acid. Its
presence is detected by the following test:- 1.Benedict’s Reagent Test Small
samples of cold drinks of different brands were taken in a test tube and a few
drops of Benedict’s reagent were added. The test tube was heated for few
seconds. Formation of reddish color confirmed the presence of glucose in cold
drinks. Observation Sr. No. Name Of The Drink Observation Conclusion 1 Coca
Cola Reddish Colour Precipitate Glucose is Present 2 Sprite Reddish Colour
Precipitate Glucose is Present 3 Limca Reddish Colour Precipitate Glucose is
Present 4 Fanta Reddish Colour Precipitate Glucose is Present Inference All the
samples gave positive test for glucose with Benedict’s reagent. Hence all the
drinks contain glucose. 2. Fehling’s Solution Test Small samples of cold drinks
of different brands were taken in a test tube and a few drops of Fehling’s A
solution and Fehling’s B solution was added in equal amount. The test tube was
heated in water bath for 10 minutes. Appearance of brown precipitate confirmed
the presence of glucose in cold drinks. Observation Sr. No. Name Of The Drink
Observation Conclusion 1 Coca Cola Reddish Brown Precipitate Glucose is Present
2 Sprite Reddish Brown Precipitate Glucose is Present 3 Limca Reddish Brown
Precipitate Glucose is Present 4 Fanta Reddish Brown Precipitate Glucose is
Present Inference All samples gave positive test for glucose with Fehling’s (A
& B) solutions. Hence all the cold drinks contain glucose.
*Test For
Phosphate* Experiment Small samples of each brand of cold drinks were taken in
separate test tubes and Ammonium Molybdate followed by concentrated Nitric Acid
(HNO3) was added to it. The solution was heated. Appearance of canary-yellow
precipitate confirmed the presence of phosphate ions in cold drinks.
Observation Sr. No. Name Of The Drink Observation Conclusion 1 Coca Cola Canary
Yellow Precipitate Phosphate is Present 2 Sprite Canary Yellow Precipitate
Phosphate is Present 3 Limca Canary Yellow Precipitate Phosphate is Present 4 Fanta
Canary Yellow Precipitate Phosphate is Present Inference All the soft drinks
samples gave positive test for phosphate ions. Hence all the cold drinks
contain phosphate.
*Test For Alcohol* Experiment Small samples of each brand of cold drinks were taken in separate test tubes and Iodine followed by Potassium Iodide and Sodium Hydroxide (NaOH) solution was added to each test tube. Then the test tubes were heated in hot water bath for 30 minutes. Appearance of yellow coloured precipitate confirmed the presence of alcohol in cold drinks. Observation Sr. No. Name Of The Drink Observation Conclusion 1 Coca Cola Yellow Precipitate Alcohol is Present 2 Sprite Yellow Precipitate Alcohol is Present 3 Limca Yellow Precipitate Alcohol is Present 4 Fanta Yellow Precipitate Alcohol is Present Inference All the cold drinks samples gave positive test for alcohol. Hence all the cold drinks contain alcohol.
*Test For Alcohol* Experiment Small samples of each brand of cold drinks were taken in separate test tubes and Iodine followed by Potassium Iodide and Sodium Hydroxide (NaOH) solution was added to each test tube. Then the test tubes were heated in hot water bath for 30 minutes. Appearance of yellow coloured precipitate confirmed the presence of alcohol in cold drinks. Observation Sr. No. Name Of The Drink Observation Conclusion 1 Coca Cola Yellow Precipitate Alcohol is Present 2 Sprite Yellow Precipitate Alcohol is Present 3 Limca Yellow Precipitate Alcohol is Present 4 Fanta Yellow Precipitate Alcohol is Present Inference All the cold drinks samples gave positive test for alcohol. Hence all the cold drinks contain alcohol.
Chemical Reaction CH3CH2OH
+ 4I2 + 6NaOH → CHI3 + HCOONa + 5NaI + 5H2O
*Test for Sucrose* Experiment 5 ml
samples of each brand of cold drinks were taken in separate china dishes and
were heated very strongly until changes occur. Black coloured residue left
confirmed the presence of sucrose in cold drinks. Observation Sr. No. Name Of
The Drink Observation Conclusion 1 Coca Cola Black Residue Sucrose is Present 2
Sprite Black Residue Sucrose is Present 3 Limca Black Residue Sucrose is
Present 4 Fanta Black Residue Sucrose is Present Inference All the brands of
cold drinks contain sucrose. But amount of sucrose varies in each brand of
drink. Fanta contains highest amount of sucrose.
*Result*
After conducting several tests, it was concluded that the different brands of cold drinks namely: 1. Coca Cola 2. Sprite 3. Limca 4. Fanta All contains glucose, alcohol, sucrose, phosphate and carbon dioxide. All cold drinks are acidic in nature. On comparing the pH value of different brands Coca Cola is the most acidic and Limca is least acidic of all the four brands taken. Among the four samples of cold drinks taken, Sprite has the maximum amount of dissolved carbon dioxide and Fanta has the minimum amount of dissolved carbon dioxide.
Some of the precautions which need to be taken care of are – Concentrated solutions should be handled with immense care. 2. Hands should be washed thoroughly after performing each experiment. 3. If possible, one should wear hand gloves to prevent from any possible damage. 4. If chemicals come into contact with your skin or eyes, flush immediately with copious amounts of water. 5. Never leave burners unattended. Turn them off whenever you leave your workstation. 6. Never point a test tube or any vessel that you are heating at yourself or your neighbour.
*Conclusion*
DIS-ADVANTAGES OF COLD DRINKS
1. Soft drinks are little more harmful than sugar solution. As they contain sugar in large amount which cause problems in diabetes patients.
2. Soft drinks can cause weight gain as they interfere with the body’s natural ability to suppress hunger feeling.
3. Soft drinks have ability to dissolve the calcium so they are also harmful for our bones.
4. Soft drinks contain “phosphoric acid” which has a pH of 2.8. So they can dissolve a nail in about 4 days.
5. For transportation of soft drinks syrup the commercial truck must use the hazardous matter place cards reserved for highly consive material.
6. Soft drinks have also ability to remove blood so they are very harmful to our body.
USES OF COLD DRINKS
1. Cold drinks can be used as toilet cleaners.
2. They can remove rust spots from chrome car humpers.
3. They clean corrosion from car battery terminals.
4. Soft drinks are used as an excellent ‘detergent’ to remove grease from clothes.
5. They can loose a rusted bolt.
*Result*
After conducting several tests, it was concluded that the different brands of cold drinks namely: 1. Coca Cola 2. Sprite 3. Limca 4. Fanta All contains glucose, alcohol, sucrose, phosphate and carbon dioxide. All cold drinks are acidic in nature. On comparing the pH value of different brands Coca Cola is the most acidic and Limca is least acidic of all the four brands taken. Among the four samples of cold drinks taken, Sprite has the maximum amount of dissolved carbon dioxide and Fanta has the minimum amount of dissolved carbon dioxide.
*Precautions*
Some of the precautions which need to be taken care of are – Concentrated solutions should be handled with immense care. 2. Hands should be washed thoroughly after performing each experiment. 3. If possible, one should wear hand gloves to prevent from any possible damage. 4. If chemicals come into contact with your skin or eyes, flush immediately with copious amounts of water. 5. Never leave burners unattended. Turn them off whenever you leave your workstation. 6. Never point a test tube or any vessel that you are heating at yourself or your neighbour.
*Conclusion*
DIS-ADVANTAGES OF COLD DRINKS
1. Soft drinks are little more harmful than sugar solution. As they contain sugar in large amount which cause problems in diabetes patients.
2. Soft drinks can cause weight gain as they interfere with the body’s natural ability to suppress hunger feeling.
3. Soft drinks have ability to dissolve the calcium so they are also harmful for our bones.
4. Soft drinks contain “phosphoric acid” which has a pH of 2.8. So they can dissolve a nail in about 4 days.
5. For transportation of soft drinks syrup the commercial truck must use the hazardous matter place cards reserved for highly consive material.
6. Soft drinks have also ability to remove blood so they are very harmful to our body.
USES OF COLD DRINKS
1. Cold drinks can be used as toilet cleaners.
2. They can remove rust spots from chrome car humpers.
3. They clean corrosion from car battery terminals.
4. Soft drinks are used as an excellent ‘detergent’ to remove grease from clothes.
5. They can loose a rusted bolt.
Read more at: http://projects.icbse.com/chemistry-281
Introduction
Milk is a complete diet as it contains
in its Minerals, Vitamins Proteins, Carbohydrates, Fats And Water. Average
composition of milk from different sources is given below: Source Water Mineral
Protei Fats Carbohydra of milk (%) s (%) ns(%) (%) tes (%) Cow 87.1 0.7 3.4 3.9
4.9 Human 87.4 0.2 1.4 4.0 4.9 Goat 87.0 0.7 3.3 4.2 4.8 Sheep 82.6 0.9 5.5 6.5
4.5 Caesin is a major protein constituent in milk & is a mixed
phosphor-protein. Casein has isoelectric pH of about 4.7 and can be easily
separated around this isoelectric pH. It readily dissolves in dilute acids and
alkalies. Casein is present in milk as calcium caseinate in the form of
micelles. These micelles have negative charge and on adding acid to milk the
negative charges are neutralized. Ca2+-Caesinate +
2CH3COOH(aq)^Caesin+(CH3COO)2Ca AIM To study the quantity of Casein in
different samples of milk.
> Beakers (250 ml) > Filter-paper > Glass rod > Weight box > Filtration flask > Buchner funnel > Test tubes > Porcelain dish > Different samples of milk > 1 % acetic acid solution > Ammonium sulphate solution Theory Natural milk is an opaque white fluid Secreted by the mammary glands of Female mammal . The main constituents of natural milk are Protein, Carbohydrate, Mineral Vitamins,Fats and Water and is a complete balanced diet . Fresh milk is sweetish in taste. However , when it is kept for long time at a temperature of 5 degree it become sour because of bacteria present in air . These bacteria convert lactose of milk into lactic acid which is sour in taste. In acidic condition casein of milk starts separating out as a precipitate. When the acidity in milk is sufficient and temperature is around 36 degree, it forms semi-solid mass, called curd.
2. The solution was filtered and transferred the precipitates in another beaker. Added about 30 ml of water to the precipitate. Only Caesin dissolves in water forming milky solution leaving fat undissolved.
3. The milky solution was heated to about 40oC and add 1% acetic acid solution drop-wise, when casein got precipitated.
4. Filtered the precipitate, washed with water and the precipitate was allowed to dry.
5. Weighed the dry solid mass in a previously weighed watch glass.
6. The experiment was repeated with other samples of milk. Visit www.icbse.com for more projects OBSERVATIONS CONCLUSION Different samples of milk contain different percentage of Caesin.
REQUIREMENTS
> Beakers (250 ml) > Filter-paper > Glass rod > Weight box > Filtration flask > Buchner funnel > Test tubes > Porcelain dish > Different samples of milk > 1 % acetic acid solution > Ammonium sulphate solution Theory Natural milk is an opaque white fluid Secreted by the mammary glands of Female mammal . The main constituents of natural milk are Protein, Carbohydrate, Mineral Vitamins,Fats and Water and is a complete balanced diet . Fresh milk is sweetish in taste. However , when it is kept for long time at a temperature of 5 degree it become sour because of bacteria present in air . These bacteria convert lactose of milk into lactic acid which is sour in taste. In acidic condition casein of milk starts separating out as a precipitate. When the acidity in milk is sufficient and temperature is around 36 degree, it forms semi-solid mass, called curd.
PROCEDURE Urn-
1. A clean dry beaker has been taken, followed by putting 20 ml of cow’s milk into it and adding 20 ml of saturated ammonium sulphate solution slowly and with stirring. Fat along with Caesin was precipitate out.2. The solution was filtered and transferred the precipitates in another beaker. Added about 30 ml of water to the precipitate. Only Caesin dissolves in water forming milky solution leaving fat undissolved.
3. The milky solution was heated to about 40oC and add 1% acetic acid solution drop-wise, when casein got precipitated.
4. Filtered the precipitate, washed with water and the precipitate was allowed to dry.
5. Weighed the dry solid mass in a previously weighed watch glass.
6. The experiment was repeated with other samples of milk. Visit www.icbse.com for more projects OBSERVATIONS CONCLUSION Different samples of milk contain different percentage of Caesin.
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Determination of antacid
strength via titration
Imagine
yourself as the Lead Analytical Chemist at Kaplan Industries. Your first big
assignment is to investigate the strength of several commercial antacids for
the Food and Drug Administration (FDA). They have sent five antacids to be
tested with a back-titration that works as follows:
• First, each antacid tablet is mixed with 40 mL of 0.1 M HClâ�"this
acidic solution is the same stuff that is in stomach acid, and one antacid pill
isn't anywhere near enough to neutralize all 40 mL of the acid.
• So, to see how much extra help each antacid pill needs to neutralize 40 mL of
0.1 M HCL, you add 0.05 M NaOH drop-by-drop to back-titrate the solution until
the pH is neutral.
• What this means is that, the stronger the antacid tablet, the less NaOH it
will take to help bring the acid to neutral. (In other words, the stronger
antacid tablets counteract more of the original HCl, leaving the solution
closer to neutral before the NaOH is added.)
Here are your results:
Maalox Tums Mylanta CVS brand Rennies
Mass of one dose
antacid 20.0 g 21.0 g 18.0 g 18.3 g 17.5 g
mL NaOH used in back-titration 24.1 mL 22.4 mL 20.0 mL 19.9 mL 24.4 mL
1. Which
is the strongest antacid, on a single-dose basis? Which is the weakest? Explain
and show your calculations.
2. Which are the strongest and weakest, on a by-weight (mass) basis?
3. When people do back titrations, they usually watch the solution for a color
change when the solution becomes neutral. What might you have used in the above
experiment to get this color change to happen in the solution? At what pH would
the solution have been neutral?
4. If you had walked into the lab, only to discover that you only had 0.1 M
sulfuric acid available to run your tests, how might this have affected your
calculations? Why?
5. In most of the antacids you tested, the active ingredient is Aluminum
Hydroxide. Here is an unbalanced reaction that shows how this chemical
neutralizes HCl (the main ingredient in stomach acid). Please provide a
balanced version of this equation:
Al(OH)3 + HCl --> AlCl3 + H20
6. The FDA requires that all of its reports be super-briefâ�"short
enough so that they can be sent via text message to all of its lab sites across
the country.. As you probably know, the word limit for text messages is very
small, so your goal here is to describe precisely what you did to test the
antacids in fewer than 150 words. In this brief report, you should provide the
FDA the major findings from your tests and let them know generally how you
performed your tests.
In the
past few decades, adulteration of food has become one of the serious problems.
Consumption of adulterated food causes serious diseases like cancer, diarrhea,
asthma, ulcers etc. Majority of adultrants used by the shopkeepers are cheap
substitutes easily available. For example, adultrants in fats, oils and butter
are paraffin wax, castor oil and hydrocarbons. Red chilli powder is mixed with
brick powder and pepper is mixed with dried papaya seeds. These adultrants can
be easily identified by simple chemical tests.
OBJECTIVE OF PROJECT
The main aim of this project is to study some of the common food adultrants present in different foodstuffs.
EXPERIMENT
1
AIM: to detect the presence of adultrants in fat, oil, and butter
AIM: to detect the presence of adultrants in fat, oil, and butter
REQUIREMENTS:
1) test-tube 2) conc. HCL 3) Furfural 4) Acetic anhydride 5) conc. HSO 6) Acetic acid 7) conc.HNO
1) test-tube 2) conc. HCL 3) Furfural 4) Acetic anhydride 5) conc. HSO 6) Acetic acid 7) conc.HNO
PROCEDURE
: Common adultrants present in ghee and oil are paraffin wax. Hydrocarbons, dyes and argemone oil.
: Common adultrants present in ghee and oil are paraffin wax. Hydrocarbons, dyes and argemone oil.
These are
detected below:
i) Adultration of vegetable ghee in desi ghee:- Take small amount of desi ghee in a test-tube and add to it 1ml of HCL and 2-3 drops of 2% alcoholic solution of furfural.
i) Adultration of vegetable ghee in desi ghee:- Take small amount of desi ghee in a test-tube and add to it 1ml of HCL and 2-3 drops of 2% alcoholic solution of furfural.
Shake the
contents vigorously:-. Appearance of red colour in the acid layer shows that
vegetable ghee has been mixed as an adultrant to desi ghee.
ii) Adultration of paraffin wax and hydrocarbon in vegetable ghee :- Heat small amount of vegetable ghee with acetic anhydride. Droplets of oil floating on the surface of unused acetic anhydride indicate the presence of wax or hydrocarbon
. iii) Adultration of dyes in fat:-Heat 1ml of fat with a mixture of 1ml of conc. Sulphuric acid and 4ml of acetic acid. Appearance of pink or red colour indicates presence of dye in fat.
iv) Adultration of argemone oil in edible oils :-To small amount of oil in a test-tube, add few drops of conc.HNO and shake. Appearance of red colour in the acid layer indicates presence of argemone oil.
ii) Adultration of paraffin wax and hydrocarbon in vegetable ghee :- Heat small amount of vegetable ghee with acetic anhydride. Droplets of oil floating on the surface of unused acetic anhydride indicate the presence of wax or hydrocarbon
. iii) Adultration of dyes in fat:-Heat 1ml of fat with a mixture of 1ml of conc. Sulphuric acid and 4ml of acetic acid. Appearance of pink or red colour indicates presence of dye in fat.
iv) Adultration of argemone oil in edible oils :-To small amount of oil in a test-tube, add few drops of conc.HNO and shake. Appearance of red colour in the acid layer indicates presence of argemone oil.
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