Detailed Project Report on surgical & nbr gloves manufacturing unit

Detailed Project Report on surgical & nbr gloves manufacturing unit

SURGICAL & NBR GLOVES MANUFACTURING UNIT

[CODE NO.3892] 

Gloves are single-use items and should not be washed or reused. Polythene: Thin and have a tendency to tear. They are not an appropriate choice for healthcare settings. Vinyl: Have been shown to be less effective than latex gloves in providing an impermeable barrier against microorganisms.

Disposable medical gloves are available in nitrile, latex and vinyl materials. Any gloves worn by health professionals should be free of powder, sterile, textured and coated for extra protection. Nitrile tends to be the most favored glove material for those working in the healthcare industry.

A disposable glove is commonly made from natural or synthetic rubber that covers the whole hand and is used to protect the wearer against harmful environmental influences and/ or used by caregivers in health care to protect themselves and patients from infections. As the name implies, disposable gloves are designed for single use only and should be disposed immediately after use.

Hand Protection- one of PPE’S

Appropriate selection of gloves is essential to protecting hands. Chemically protective gloves are one of the most important tools to minimize dermal exposures to chemicals in research laboratories. Gloves should only be used under the specific conditions for which they are designed, as no glove is impervious to all chemicals.

It is also important to note that gloves degrade over time, so they should be replaced as necessary to ensure adequate protection. Laboratory personnel should use the information below, and manufacturer compatibility charts (found under useful resources in the above right menu), to choose the type and style of glove.

Choice of gloves 

Because the fundamental function of gloves is to protect both the wearer and the patient against the transmission of infectious microorganisms, the most important criterion for selection of gloves for safe use should be barrier performance. With the onset of latex protein allergy affecting certain genetically predisposed individuals, the risk of sensitization and allergy-triggering reactions in these already allergic users should also be considered.

Properly manufactured NR latex gloves are known for their excellent barrier property, high strength, good elasticity, tactile sensitivity, comfort, fit, and durability. This is particularly so with powdered gloves. Over the years, manufacturers of synthetic gloves have attempted to simulate these NR properties. It is not unreasonable to say that today, these properties are still unsurpassed (in full) by any of the synthetic gloves currently manufactured.

Natural rubber latex is the oldest and most familiar material used in disposable gloves. In recent years it has increasingly been supplanted by nitrile and to a lesser extent vinyl gloves, but it remains popular in many uses, especially medical applications.

Natural rubber latex is obtained from the Hevea Brasiliensis tree when it’s bark is tapped.  It is a milky fluid comprising 30-40% of rubber hydrocarbon particles suspended in a serum together with a few percent of other non-rubber substances such as proteins, lipids, carbohydrates, sugars and some metals (non-rubber fractions).  The remaining major component is water. 

Natural rubber latex is obtained from the Hevea Brasiliensis tree when it’s bark is tapped.  It is a milky fluid comprising 30-40% of rubber hydrocarbon particles suspended in a serum together with a few percent of other non-rubber substances such as proteins, lipids, carbohydrates, sugars and some metals (non-rubber fractions).  The remaining major component is water.

Manufacturers use a variety of machines and processes to produce both surgical and examination gloves. The most popular style of machine for the production of examination gloves, and to some extent surgical gloves, is the continuous chain or drag-line machine.

Powdered gloves are typically produced by means of an on-line powdering process in which the gloves are dipped into a slurry made from modified cornstarch. Some manufacturers have used off-line processes in which the gloves are washed, dried, and powdered. The powdering can be accomplished by either a wet or dry process. 

The most widely used method for the production of powder-free gloves is subjection of the gloves to a chlorination process. Chlorine is used to chemically modify the NR surface. This modification reduces the surface tack of the rubber and allows the glove to be donned without the use of powder. However, this treatment is not sufficient to allow the glove to be donned when the user’s hand is damp or wet. 

This shortfall in the performance of the gloves led to the development of polymeric coatings, which when applied to the rubber surface, allowed the user to don the gloves not only with dry hands but also with damp or wet hands. This feature is particularly important for surgical gloves because intraoperative changes may be necessary.

The coatings are made from a variety of materials. Acrylates, urethanes, and even nitriles have been used as surface coatings for medical gloves. The methods of application to the rubber surface range from on-line coatings to off-line washing processes.

Medical Exam Gloves are used to protect the health of the patient and caregiver. They offer a protective barrier between any contagions that the caregiver may be carrying as well as what the patient may have. This barrier reduces the risk of infection. There are three different types of medical gloves in common use--latex, vinyl, and nitrile. Latex is made from rubber, a natural material. Latex is most often used in medical procedures. Vinyl is a synthetic man-made material made of plastic from ethylene and chlorine. It is a low-cost option often used in food handling. Nitrile is also a synthetic material but is made from acrylonitrile and butadiene. It is highly elastic, resistant to punctures, resistant to chemicals, and easily conforms. It is used in medical procedures, maintenance, gardening and a host of other uses because of its durability. Each glove type has its own advantages and disadvantages. 

COST ESTIMATION

Plant Capacity                                      160000./Day

Land & Building (7500 sq.mt.)            Rs. 4.87 Cr

Plant & Machinery                                 Rs. 9.70 Cr

Working Capital for 1 Month              Rs. 88.76 Lacs

Total Capital Investment                      Rs. 16.26 Cr

Rate of Return                                       40%

Break Even Point                                   37%


  • INTRODUCTION
  • HAND PROTECTION- ONE OF PPE’S
  • CHOICE OF GLOVES
  • PROJECT LOCATION-WEST BENGAL
  • CLIMATE
  • DISTRICT MAP OF WB:-
  • TRANSPORT
  • BRIEF HISTORY OF RUBBER
  • JOSEPH LISTER AND SURGICAL ASEPSIS
  • THE HISTORY OF DISPOSABLE GLOVES
  • 1889
  • 1894
  • 1965
  • 1992
  • MID-1990S
  • TODAY
  • TYPES OF DISPOSABLE GLOVES EXIST
  • USES & APPLICATION OF THIN NITRILE GLOVES
  • 1) MEDICAL GLOVES
  • THE BASIC ELEMENTS OF EN455 ARE:
  • 2) INDUSTRIAL, LABORATORY AND PHARMACEUTICAL GLOVES
  • 3), WITH A CATEGORY 2 GLOVE WHICH DOES NOT FALL INTO THE 
  •         CATEGORIES 1 OR 3
  • MECHANICAL PROPERTIES
  • MECHANICAL PROPERTIES OF RUBBER LATEX GLOVE FILM AFTER DIPPING MOLD
  • TYPES OF GLOVES
  • GLOVE TYPES THE RUBBER GLOVES CAN BE DIVIDED BASICALLY 
  •     INTO 4 DIFFERENT CATEGORIES,
  • MEDICAL GLOVES
  • MEDICAL GLOVES CAN FURTHER BE DIVIDED INTO TWO,
  • HOUSEHOLD GLOVES
  • INDUSTRIAL GLOVES
  • SPECIALITY GLOVES
  • EMERGENCY SERVICES
  • POLICE GLOVES
  • GLOVE PROPERTIES
  • THE PERFORMANCE REQUIREMENTS OF GLOVES ARE,
  • AFTER TREATMENTS OF GLOVES
  • CHLORINATION
  • POLYMER COATING
  • HYDROGEL COATINGS
  • GLOVE ALLERGY AND IT’S REMEDIES
  • TYPE I ALLERGY
  • TYPE IV ALLERGY
  • CHEMICALS USED IN THE PROCESSING OF RUBBER PRODUCTS CAUSE THIS TYPE OF ALLERGY.
  • "SAFE" PROTEIN LEVELS
  • POWDER-FREE GLOVES
  • TESTING AND QUALITY CONTROL OF GLOVES
  • IN-PROCESS TESTING
  • DIPPED LATEX PRODUCTS
  • WET-COACERVANT DIPPING
  • DRY-COACERVANT DIPPING ( COAGULANT DIPPING )
  • EXAMPLES OF DRY COACERVANT SOLUTIONS ARE GIVEN BELOW: PARTS BY WEIGHT (PBW)
  • HEAT SENSITIZED DIPPING
  • ELECTRO DEPOSITION
  • FORMERS
  • DIPPING TANKS
  • DIPPING MACHINES
  • SEQUENCE OF OPERATIONS
  • GLOVE PRODUCTION & MANUFACTURING
  • THE GLOVES ARE MANUFACTURED BY EITHER A
  • BATCH DIPPING PROCESS
  • CONTINUOUS DIPPING PROCESS
  • LATEX DIPPING
  • LATEX CONCENTRATE
  • COMPOUNDING
  • COAGULANT DIPPING
  • LATEX DIPPING
  • BEADING
  • LEACHING
  • VULCANIZATION
  • POST LEACHING
  • SLURRY DIP
  • BEADING
  • LEACHING
  • VULCANIZATION
  • POST LEACHING
  • SLURRY DIP
  • STRIPPING
  • TUMBLING
  • GLOVE PACKING
  • GLOVE STERILIZATION
  • FINISHED GLOVES
  • LATEX COMPOUND DESIGN FOR DIPPED GOODS
  • POLYMER:
  • FILLERS:
  • SOFTENERS:
  • STABILISERS:
  • ANTIOXIDANTS:
  • VISCOSITY MODIFIERS:
  • OTHER ADDITIVES
  • BRIEF ABOUT VULCANIZATION & ACCELERATORS
  • ACCELERATORS:
  • RAW MATERIAL
  • EXAMINATION GLOVES USED IN HEALTHCARE
  • ELEMENTS OTHER THAN THE GLOVE MATERIAL THAT DETERMINE THE LEVEL OF BARRIER PROTECTION INCLUDE:
  • PROCESS FLOW DIAGRAM
  • FORMULATION
  • FUTURE DEVELOPMENTS
  • NITRILE TECHNOLOGY IS RAPIDLY ADVANCING AND A RANGE OF DEVELOPMENTS IS PREDICTED:
  • 1) CLEANROOM GLOVES
  • 2) ACCELERATOR FREE GLOVES
  • 3) AQL 0.65
  • ADVANTAGE & DISADVANTAGE
  • ADVANTAGE & DISADVANTAGE
  • THE QUALITY-CONTROL PHASE
  • MARKET SURVEY
  • PRODUCT SEGMENT
  • FORM SEGMENT REVIEW
  • KEY BENEFITS FOR INDIA DISPOSABLE GLOVES MARKET:
  • BY PRODUCT
  • BY FORM
  • BY APPLICATION
  • BY DISTRIBUTION CHANNEL
  • MACHINERY SUPPLIERS
  • RAW MATERIAL SUPPLIERS
  • NR LATEX
  • POLYETHYLENE OXIDE FATTY ALCOHOL
  • NBR LATEX
  • KOH SOLUTION
  • POLYPHENOL (ANTIOXIDANT DISPERSION)
  • ZINC OXIDE
  • SULPHER
  • ZDEC, ZDBC, TMTD
  • RAW MATERIAL PHOTOGRAPHS
  • NBR LATEX
  • NR LATEX
  • KOH SOLUTION
  • STYRENATED PHENOL
  • ZINC OXIDE
  • SULPHER
  • ZDECZDBC
  • TMTD


APPENDIX – A:


01. PLANT ECONOMICS

02. LAND & BUILDING

03. PLANT AND MACHINERY

04. OTHER FIXED ASSESTS

05. FIXED CAPITAL

06. RAW MATERIAL

07. SALARY AND WAGES

08. UTILITIES AND OVERHEADS

09. TOTAL WORKING CAPITAL

10. TOTAL CAPITAL INVESTMENT

11. COST OF PRODUCTION

12. TURN OVER/ANNUM

13. BREAK EVEN POINT

14. RESOURCES FOR FINANCE

15. INSTALMENT PAYABLE IN 5 YEARS

16. DEPRECIATION CHART FOR 5 YEARS

17. PROFIT ANALYSIS FOR 5 YEARS

18. PROJECTED BALANCE SHEET FOR (5 YEARS)


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