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The world’s annual consumption of plastic materials has increased from around 5 million tons in the 1950s to nearly 100 million tones today.
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GLOBAL PROBLEM GLOBAL PROBLEM INDIAN SOLUTION INDIAN SOLUTION BIOPLASTIC TECHNOLOGYBIOPLASTIC TECHNOLOGY
MASTER BATCHMASTER BATCH
Add 5% Master Batch to your all HDPE Films and make it 100% Add 5% Master Batch to your all HDPE Films and make it 100% BIODEGRADABLEBIODEGRADABLE
BIOPLAST BIODEGRADABLE PLASTICSBIOPLAST BIODEGRADABLE PLASTICS
A SINCERE EFFORT TOWARDS ELIMINATING THE PLASTIC WASTE
LET US MAKE EARTH A BETTER PLACE TO LIVE FOR ALL
IMPACT OF PLASTIC WASTE ON OUR ENVIRONMENTIMPACT OF PLASTIC WASTE ON OUR ENVIRONMENT
The disposal of plastics products also contributes
significantly to their environmental impact. Because
most plastics are non-degradable, they take a long time
to break down, often several hundred years, when they
are land-filled. With more and more plastics products,
particularly plastics packaging, being disposed of soon
after their purchase, the landfill space required by
plastics waste is a growing concern.
The world's annual consumption of plastic materials has increased from around 5 million tones in the 1950s to nearly 100 million tones today.
The amount of plastic waste generated annually in the UK is estimated to be nearly 3 million tones. An estimated 56% of all plastics waste is used packaging, three-quarters of which are collected from households. It is estimated that only 7% of total plastic waste arising are currently being recycled.
Plastics consumption is growing by about 4% every year in western Europe.
PLASTIC WASTEPLASTIC WASTE
RECYCLING IS NOT ALWAYS THE ANSWER…RECYCLING IS NOT ALWAYS THE ANSWER…
THE ANSWER IS … BIODEGRADABLE BAGS!
Recycling can be an excellent way of handling waste - but not always. Some reasons:
• Recycling does not occur until somebody actually uses the material.
• Health concerns raise problems with using post-consumer recycled material for food.
• Consistent and reliable supply of the recovered material may pose problems. • Recycled material is often more costly to produce in terms of carbon footprint. The recycled product has to be broken down by machines, transported away and then re- machined all of which takes up a lot of energy/ carbon footprint.
BIODEGRADABLE TECHNOLOGYBIODEGRADABLE TECHNOLOGY
Biodegradation is the transformation and deterioration of polymers solely by living organisms (including the micro organisms excreted by them ). Due to active enzymatic reaction over the molecular structure of polyethylene. Biodegradable plastics undergoes biodegradation by biological processes during composting to yield carbon dioxide (Co2), water, inorganic compounds and biomass at a rate consistent with other compost able materials (like cellulose, wood, paper ) and leaves no visible, distinguishable or toxic residue.
BIODEGRADABLE TECHNOLOGY WITH ENZYME & BACTERIABIODEGRADABLE TECHNOLOGY WITH ENZYME & BACTERIA
ENZYME WITH POLYETHYLENE
Enzymes used in this product are regarded a catalysts, helping to change the chemical reaction of polyethylene accelerating the process of degradation. Autotrophic bacteria present in mineral salts mediums containing some form of nitrogen-energy supplying material are also used in this technology. Carbon is obtained from the added oxidation agents in this product. The PH values of this composition blended with polyethylene is 9.5 confirming its non-acidity characteristics. All the ingredients of our plastic products are food grade and non-toxic in nature.
COMPOSTING OF POLYETHYLENE
It is observed that soil contains at least 58% Carbon. The greater part of the Nitrogen content of the soil is closely linked to organic matter. As the organic soil matter gradually decomposes the nitrogen is converted into water or available forms of ammonia and nitrates. This moist soil reacts with the biodegradable polyethylene film making it susceptible to composting and the release of CO2. The enzymatic treatment is used at 4-6% dosage for Polyethylene (90% HDPE, 10% LLDE). The use of this product makes Polyethylene (HDPE LLDE) 100% Biodegradable. The cost of this process is extremely competitive as compared to any other technology prevalent in the world today.
HDPE
Rudra MasterEnzo Batch added inThe process & mfred
BAGS
GOES TO SOILand
COMPOST RELEASING
CO2
BIODEGRADEIN
180 DAYS
GIVING BACK TO MOTHER NATUREGIVING BACK TO MOTHER NATURE
HDPE VEST CARRIER BAGS NZYME COMPOUNDED HDPE VEST CARRIER BAGS NZYME COMPOUNDED
IDEAL BIODEGRADATION IN ENVIRONMENTAL CONDITIONSIDEAL BIODEGRADATION IN ENVIRONMENTAL CONDITIONS
BIODEGRADATION OBSERVED – 60% IN 105 DAYS
IDEAL BIODEGRADATION IN ENVIRONMENTAL CONDITIONSIDEAL BIODEGRADATION IN ENVIRONMENTAL CONDITIONS
BIODEGRADATION OBSERVED – 70% IN 140 DAYS(TWO SAMPLES)
PRODUCTS RECOMMENDED WITH ENZYME TECHNOLOGY FOR A CLEAN PRODUCTS RECOMMENDED WITH ENZYME TECHNOLOGY FOR A CLEAN ENVIRONMENT WITH VERY LESS COST ADDITION A MEANINGFUL APPROACHENVIRONMENT WITH VERY LESS COST ADDITION A MEANINGFUL APPROACH
VEST CARRIER BAGS IN THICKNESS FROM 7 TO 50 MICRONSVEGETABLE BAGSPRODUCE BAGS-ON-ROLLSFRIDGE BAGSDOMESTIC GARBAGE BAGSCOMMERCIAL GARBAGE BAGSINDUSTRIAL LINERSHOSPITAL WASTE GARBAGE BAGSTHIS ABOVE ALONE CONSTITUTES MORE THAN 50% OF THEMUNCIPAL WASTE WHICH IS DISPOSED CARELESSLY BY ALL OF US.
BIODEGRADATION WITH BACTERIABIODEGRADATION WITH BACTERIA
THE DEFINITION OF BIODEGRADABLE PLASTICS STATES THAT A DEGRADABLE PLASTIC IN
WHICH THE DEGRADATION RESULTS FROM THE ACTION OF NATURALLY OCCURRING
MICROORGANISMS SUCH AS BACTERIA, FUNGI AND ALGAE. AND OUR PRODUCTS HAVE BEEN
TESTED FOR ENUMERATION OF FUNGAL AND BACTERIAL COUNTS AT <10 CFU/GM OF
POLYETHYLENE FOR FUNGAL COUNTS AND 25 CFU/GM OF POLYETHYLENE FOR BACTERIA
COUNTS.
IT HAS ALSO BEEN FOUND THAT THE BACTERIAL COUNTS HAVE MULTIFOLD IN THE SOIL WITH
OUR BIODEGRADABLE BAGS. AS PER TEST REPORTS THE SIGNIFICANT INCREASE IN BACTERIAL
COUNTS AND WITH THE PRESENCE OF APPRECIABLE NO. OF SPECIES OF ALCALIGENES AND
PSEUDOMONAS INDICATE THE PROBABLE BIODEGRADATION OF POLYETHYLENE FILM TAKING
PLACE IN THE SOIL WHICH OTHERWISE WOULD NOT HAVE BEEN POSSIBLE IN A NORMAL SOIL.
THE METHOD OF TESTING WAS AS PER SOIL CHEMICAL ANALYSIS BY MR. M L JACKSON AND IS
5402 (AS CERTIFIED BY VIMTA LABS, INDIA) CFU/GM – COLONIEL FORMING UNITS OF BACTERIA
PER GRAM OF POLYETHYLENE.
60% BIODEGRADATION IN 130 DAYS60% BIODEGRADATION IN 130 DAYS
70% BIODEGRADATION IN 150 DAYS70% BIODEGRADATION IN 150 DAYS
80% BIODEGRADATION IN 170 DAYS80% BIODEGRADATION IN 170 DAYS
90% BIODEGRADATION IN 180 DAYS. BIO MASS HAVING 90% BIODEGRADATION IN 180 DAYS. BIO MASS HAVING BIODEGRADED POLYETHELENE SHOWNG GROWTH OF PLANTS BIODEGRADED POLYETHELENE SHOWNG GROWTH OF PLANTS
RATE DIFFERENCE OF NORMAL HDPE FILM RATE DIFFERENCE OF NORMAL HDPE FILM & BIODEGRADABLE FILM & BIODEGRADABLE FILM
HDPE FILM 100 KG @ 105/- Rs. 10500/-
MASTER BATCH RUDRA 5 KG @ 350/- Rs. 1750/-
TOTAL VALUE Rs. 12250/-
Rs 12250/- DIVIDED 105 KG = Rs 116.66 PER KG
DIFFERENCE 116.66 – 105/- = Rs 11.66 PER KG
HDPE CARRY BAGHDPE CARRY BAG
SIZE MICRON WEIGHT NO. OF PEICES PER KG
16 X 20 50 17.72 GM 56 PEICES
16 X 20 40 14.17 GM 70 PEICES
16 X 20 30 10.63 GM 94 PEICES
Tested & Certified ByTested & Certified By
A CLEANER & POLLUTION FREE ENVIRONMENT IS EVERYBODY’S RIGHT
INCLUDING ANIMALS & SPECIESINCLUDING ANIMALS & SPECIES
WITH NO ALTERNATIVE SECONDARY PACKAGING SOLUTION AVAILABLE AT A LESSER
COST THAN THE BIODEGRADABLE PLASTICS & WITHOUT DESTROYING MOTHER NATURE
THE NEED OF THE HOUR IS TO SHARE THE RESPONSIBILITY OF PROTECTING NATURE
ANDAND
START ADVOCATING THE USE OF BIODEGRADABLE PLASTICS.
CONCLUSIONCONCLUSION
ALL CHARITIES MUST BEGIN AT HOMEALL CHARITIES MUST BEGIN AT HOME
PRIDE OF INDIAPRIDE OF INDIA
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