Detailed Project Report on water for ampoule (water ampoul of 5ml/10ml/30 ml manufactured which are used for dry injection and dry syrps)

Detailed Project Report on water for ampoule (water ampoul of 5ml/10ml/30 ml manufactured which are used for dry injection and dry syrps)

WATER FOR AMPOULE
(WATER AMPOULE OF 5ML./10ML./30ML.
MANUFACTURED WHICH ARE USED FOR DRY INJECTIONS AND DRY SYRUPS)

[CODE NO.3087]  


Water for injection by definition is water that is intended for use in the manufacture of parenteral (i.e. injectable) drugs whose solvent is water. The USP (United States Pharmacopeia) defines this as highly purified waters containing less than 10 CFU/100 ml of Aerobic bacteria. These waters should also have fewer than 500 ppb of total organic carbon, fewer than 0.25 EU/ml endotoxins, and a conductivity of less than 1.3uS/cm @ 25 C.

To begin, let’s start by looking at how Water for Injection is made. The USP allows WFI to be produced by one of two means; either distillation or reverse osmosis. Prior to making it to the still, however, supply water has to go through extensive pretreatment. Pretreatment usually includes various filtration steps, removal of chlorines through the use of activated
carbon beds, and percolation of water through ion exchange resins to remove residual ionic compounds. What is the purpose of all this pretreatment? By pretreating the water, we effectively reduce the conductivity of the water, as well as the level of organic contaminants.

Once the water makes it through these pretreatment steps, it goes to the still. What happens in a WFI still? Distillation, of course. When water is distilled, it heated until it is a vapor, stripping the heavier ions, particulates, and endotoxins from the water. There are both single and multiple effect stills and which one is best for you is determined by how much
WFI you are trying to generate. There are also vapor compression stills available that can make WFI.  Regardless of what kind of still you are using, the basic process is the same- the water vapor is passed through a series of tubes and recondensed, resulting in WFI.

We get WFI from a process called reverse osmosis. In reverse osmosis, or RO, water is forced through a semi-permeable membrane and the pores in that membrane reject dissolved ions, salts, and organic compounds. This is filtration on a molecular and ionic level. The quality of water, temperature, PH, and flows rates are all critical in RO as the membranes used can foul easily. Reverse osmosis systems rely on booster pumps to increase pressure across membranes, storage tanks, and sophisticated controls for bulk WFI preparation. RO systems are capable of producing 600-50,000 gallons per day of WFI.

So what is done with WFI after it is produced to ensure the water stays at water for injections quality? It either needs to be used quickly (usually same day) or put in a state that allows it to maintain its efficacy. How do you make sure WFI stays as WFI? You need to minimize microbial growth. This is accomplished by maintaining it at high temperatures and keeping it in motion.  Normally WFI is kept at 90 degrees C and recirculated through a distribution loop at a minimum velocity of 5 feet per second.

To ensure there is no contamination of entering or building up in the distribution system, the piping is normally highly polished, at least 20 Ra, often with electropolish.  Any ventilation or vent filters are usually sterile membranes of at least 0.2 uM. Vent filter, commonly found on tanks, are often heat traced or steam jacketed. Why is that? Well, when WFI
comes in from the still, it can be very hot. The heat can cause it to flash off and enter the filter. Once the steam makes contact with the vent filter, which if not heat traced will be cooler than the tank, the vapor will recondense and cause the vent filter to blind. When you go to pump that tank out, you would then pull a vacuum and could cause the tank to
collapse.

Other common pieces of equipment used to ensure system integrity include double sheet shell and tube heat exchangers and weir type diaphragm valves.  EPDM is probably the most common gasket material we see in a WFI system.

Because the conductivity of WFI is so low, it is considered “ion hungry”, ready to leach ions out of any surface it comes in contact with. That makes the water very abrasive. That means we use centrifugal pumps with single or double mechanical seals and hard seal faces, the most common and robust being either silicon carbide or tungsten carbide.

COST ESTIMATION

Plant  Capacity                              :    200000.00 Ampoules/day                                       
Land & Building (700 Sq.MT)    :    Rs. 94.00 Lacs
Plant & Machinery                        :    Rs. 4.00  Cr
Working Capital for 2 Months    :    Rs. 1.44  Cr
Total Capital Investment             :    Rs. 6.58  Cr
Rate of Return                              :    25%
Break Even Point                         :    57%


INTRODUCTION    
WATER FOR INJECTION    
USES    
B.I.S. SPECIFICATION    
WATER FOR INJECTION    
MARKET SURVERY    
PHARMA GIANTS RAISE THEIR R&D SPENDING    
RAW MATERIALS FOR INJECTION WATER AMPOULES    
PROCESS OF DISTILLATION    
DIFFERENT METHOD FOR WATER FOR INJECTION    
TECHNOLOGIES FOR WATER FOR INJECTION    
MANUFACTURING PROCESS    
PACKAGING OF WATER IN AMPOULES    
PROCESS FLOW DIAGRAM    
PROCESS IN DETAILS FOR WATER FOR INJECTION (WFI)    
MULTI EFFECT STILL DIAGRAM    
VAPOUR COMPRESSION STILL SCHEMATIC    
PRODUCTION OF WATER FOR INJECTION FOR THE PHARMACEUTICAL
AND BIO-PHARMACEUTICALS    
FORM-FILL-SEAL TECHNOLOGY & PROCESS    
PLANT LAYOUT    
SUPPLIERS OF RAW MATERIALS    
SUPPLIERS OF PLANT & MACHINERY    

APPENDIX – A:

 1.      COST OF PLANT ECONOMICS  
 2.      LAND & BUILDING                                      
 3.      PLANT AND MACHINERY                                  
 4.      FIXED CAPITAL INVESTMENT                             
 5.      RAW MATERIAL                                         
 6.      SALARY AND WAGES                                     
 7.      UTILITIES AND OVERHEADS                              
 8.      TOTAL WORKING CAPITAL                                
 9.      COST OF PRODUCTION                                   
10.      PROFITABILITY ANALYSIS                               
11.      BREAK EVEN POINT                                     
12.      RESOURCES OF FINANCE                           
13.      INTEREST CHART                                       
14.      DEPRECIATION CHART                                   
15.      CASH FLOW STATEMENT                                   
16.      PROJECTED BALANCE SHEET      
 

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