IV Bottles Project Report

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You can immediate download the IV Bottles Manufacturing sample project report format template, in MS excel or word / pdf format.

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The amount of fluid received intravenously or through the bloodstream is referred to as intravenous fluid regulation. An intravenous line delivers this fluid via a packet or a bottle. A tiny tube, commonly referred to as an “I.V.,” is put into a person’s veins. Fluids are given this manner for quite a few reasons, consisting of rehydration after being dehydrated because of infection or immoderate bodily activity, the remedy of any contamination or disease where eating is impossible, when a person is being operated on and also after the surgery, during cancer treatment, and pain management using certain medications.

I.V. fluids are pre-filled plastic bottles made with various materials, including petrochemical resins such as HDPE, LDPE, PVC, Polyester, Polycarbonate, Polypropylene, Polystyrene, and others. Some bioplastics and BPA (Bisphenol A) are also employed in the bottle manufacturing process. In the manufacturing of Plastic I.V. bottles, a new class of soft propylene has made a breakthrough.

HDPE is a common material used in the production of saline bottles and plastic I.V. bottles. Additionally, Polypropylene is a polymer that is often utilized to fabricate plastic I.V. bottles (P.P.). High-Density Polyethylene, or HDPE, is a regularly used resin in the production of plastic bottles. The material is impact-resistant, cost-effective, and provides adequate moisture protection. 

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Market Outlook

In the projected period of 2020–2025, the global I.V. bottles market is expected to reach USD 2.38 billion, with a CAGR of 5.70 per cent. With rising healthcare spending and research and development investments, the pharmaceutical sector is booming. The rise in demand from the pharmaceutical industry is projected to propel the parental packing market forward rapidly. Hospitals and healthcare institutions use the I.V. or intravenous infusion method because of the high benefit therapy. The I.V. bottles are one of the oldest I.V. infusion systems among the various procedures. Because the use of alternative materials was limited in the late 1980s, glass I.V. bottles became popular. However, as time passed, plastic I.V. bottles began to dominate the market, offering distinct advantages over glass bottles. The first benefit is that plastic bottles do not break when dropped; second, they are not reusable because they are crushed. Thus there is no danger of pollution.

The market can be divided into three categories based on capacity: up to 250 ml, 250-500 ml, and above 500 ml. The most commonly utilized volume is between 250 and 500 mL.

Applications of the product

  • The most common application for Plastic I.V. Bottles is hydration of the body during various medical procedures.
  • The I.V. bottles include a variety of items such as regular saline, dextrose, and others.
  • They’re also utilized to deliver intravenously various drugs and medicines. Volume expanders, blood-based products, blood substitutes, medicines, and nutrition are among the substances injected intravenously.
  • They are utilized in the intravenous treatment of cancer treatments.
  • They are utilized in the transfusion of blood.
  • Parenteral nutrition is the process of giving a person the nutrients they need via an intravenous line. This is given to patients who are unable to obtain nutrients through regular meals and digestion. An intravenous solution including salts, dextrose, amino acids, lipids, and vitamins will be administered to a person receiving parenteral nourishment.
  • The contrast agent is injected into the saline solution in the I.V. bottle during the imaging processes, such as the C.T. scan and MRI imaging.
  • For the athletes, the I.V. rehydration technique is used.

Raw Material Requirement 

  • Medical grade Polypropylene pellets are used as the primary raw material for the I.V. Bottles. These pellets are blended with various additives to improve the polymer’s characteristics and produce a better product.
  • The I.V. bottles are made of Polypropylene, which is one of the cheapest plastics available. However, find some drawbacks to using it. The polypropylene homopolymer is susceptible to microbial attack, is very flammable, is not U.V. light-resistant, and is not resistant to all organic solvents. To improve these qualities, chemicals are applied to it.
  • Antacids such as calcium stearate, calcium pelargonate, zinc oxide, and hydro calcite are common additions used to improve the characteristics of P.P. These substances are needed to neutralize catalyst residues, which could otherwise generate acids that are harmful to the converter’s equipment. An antioxidant is the second most important component of P.P. This is essential to prevent the polymer from chain scission during processing and ageing, at the very least. Antioxidants that are commonly used as process stabilizers are hindered phenols.
  • Clarifiers, flame retardants, and other additives are also added to the mix. To add “value addition,” more fillers and flame retardants are added. These substances will be added according to the manufacturer’s specifications. 

Process of Manufacturing 

  • The procurement of raw materials is the initial step in the production process. To remove any impurities, medical-grade P.P. beads are first de-dusted. In the plastic compounding machine, they are blended with various additives (fillers, stabilizers, antioxidants, antibacterial agents, and so on).
  • The polymer compound is “extruded through a die.”After cooling, the extrudate is hardened and then chopped into little pellets. Alternatively, the molten extrudate can be sliced as it exits the extrusion die and then cooled into pellets. In this situation, both cutting and chilling can be done in air or water, or cutting can be done in the air and then quenched in water. Knife wear is reduced when cutting thermoplastics as a melt rather than when they are solid. The pelletizing equipment is attached to the Extruder or gear pump and converts the product into various shapes and sizes pellets.
  • The above-formed Compound P.P. pellets are then fed into an “Injection moulding machine” through the hopper. They then reach the moulding machine’s Barrel, where the compound plastic is molten due to the heat and shearing action of the feed screw. The molten plastic is then pumped into several cavity moulds, taking on the shape of “long, thin tubes.”The formed necks and threads that will be used to cap the bottles to come are frequently included in these tubes, which are referred to as “Parisons.”
  • These Parisons are now fed into a feeder and processed through an “Unscrambler” during the re-heating process, which orients the Parisons for feeding into the “Blow-molding machine.”
In Addition to Above
  • Stretch Blow Molding began when a thin steel rod called a “Mandrel” glides into the parison’s neck and fills it with “High-pressurized air.” After passing through Quartz heaters, the parisons are heated before entering the mould. The parison is blasted and stretched axially and radially into the mould, where it forms a bottle shape due to the pressured air, heat, and pressure.
  • For the Plastic bottles to assume their shape, the Molds must be immediately chilled. Numerous cooling methods can successfully cool both the mould and the bottles, including direct and indirect cooling. Using pressurized air or carbon dioxide directly on the mould and plastic is an example of a direct approach. Water can be pumped through pipes encircling the mould, cooling it and the plastic in the process.
  • The bottles are ready to be taken from the mould once they have cooled and set. They’re taken out of the moulds, and the excess plastic is chopped down. The accepted bottles are sent to the labelling division once they have been inspected.
  • The Bottles are cleaned with an Ultrasonic cleaning to ensure that they remain dust and oil-free.
  • Instructions and information for storage and handling are printed on the bottles.
  • After being sterilized in autoclaves, the I.V. bottles are sent to the packing division.
  • To avoid contamination at this stage, the packing is done in a clean, laminar flow sterile environment.
  • Finally, a complete check is performed to ensure no particulates, leaks, or other flaws. The inspected bottles are then wrapped in foil and placed in cartons. They’re then kept in a germ-free storage space until they’re ready to ship. 

Technology Used

Blow-Fill-Seal (BFS) Technology: Blow-fill-seal (BFS) technology, a type of advanced aseptic production, creates, fills, and seals the container in one continuous, automated operation. A primary advantage of this technique is that it reduces human involvement, which reduces the risk of microbial contamination and foreign particles.

Advantages of BFS Technology

  • Blow-fill-seal technology can be used to create single-unit doses that are devoid of preservatives. Because preservatives are damaging to the sensitive mucosae of the eyes, nose, and lungs, this is a huge benefit for sensitive people.
  • Another benefit of unit-doses is that they ensure that the patient receives the exact amount of product, which is particularly important when dealing with highly potent chemicals or therapeutically active chemicals at low concentrations.
  • Individual sterile unit doses are portable and straightforward to use, making them ideal for today’s active lifestyles.
  • Blow-fill-seal generation calls for much less employee intervention, making it a different reliable technique of sterile pharmaceutical production.
  • The basic idea of BFS is that a container is formed, filled, and sealed in a sterile contained space inside a machine in a continuous process that does not require human intervention. As a result, this technology can make sterile pharmaceutical liquid dosage forms in an aseptic manner.

Key Points Cover in Sample Project Report 

Table of Contents

Sr. No.Particulars
1Purpose Of The Document
2Introduction
3Market Potential
4Industrial Scenerio
5Product Description
6Product Uses
7Raw Material Requirement
8Manufacturing Process
9Yield Of Product
10Production Ratio
11Indian Standards
12Project Components
13Land /Civil Work
14Plant & Machinery Details With Images
15Misc. Assets
16Power Requirement
17Manpower Requirement
18License & Approvals
19S.W.O.T Analysis
20Cost Of Project
21Means Of Finance
22Projected Balance Sheet
23Projected Profitability Statement
24Cash Flow Statement
25Calculation Of D.S.C.R
26Computation Of Sale Of Plastic Iv Bottles
27Closing Stock
28Computation Of Working Capital Requirement
29Depreciation
30Repayment Schedule Of Term Loan
31Financial Indicators
32Profitability Ratio With Graphs
33Break Even Point Analysis
34Implementation Schedule
35Assumptions

Apart from this, all the information is being provided. To help in preparing project reports.

CONCLUSION

Due to increased investment in the healthcare sector, the Asian market for IV bottles is projected to expand the most. China and India, the Asia Pacific economic powerhouses, are projected to be an essential market for IV bottles and a substantial market for manufacturers to concentrate on. The Asia Pacific market is seeing the newest entries in the IV bottle industry. Consumer awareness is projected to increase, resulting in a preference for IV administration, fuelling the expansion of the IV bottle market.

FAQ’s

The demand for IV Bottles is rising globally. Why?

The demand for IV bottles is projected to rise as people become more aware of the benefits of parenteral nutrition. According to the World Health Organization, malnutrition is responsible for around 11% of all diseases worldwide. Because this percentage is predicted to climb shortly as a result of food security and changing environmental conditions, interest in parenteral nutrition is expected to remain steady. IV bottles and bags are expected to be good choices for intravenous nutrition supplementation.

Who are the key players operating in the global IV bottles market?

With the increased demand for intravenous solution bottles in the worldwide industry, market participants in the Intravenous solution bottles market are expected to have profitable growth possibilities in the coming years. A list of a few firms involved in the Intravenous solution bottles industry is provided below:

  • Cardinal Health Inc
  • Baxter International Inc
  • B. Braun Melsungen AG
  • BD
  • Fresenius Kabi AG
  • Terumo Corporation
  • Nipro Corporation
  • Smiths Medical
  • Zyno Medical
  • ICU Medical, Inc
  • Vioser SA
  • Arvind Group
  • Hebei Xinfuda Plastic Products Co., Ltd. 
Sample Project Report Format

In our project report format, we cover technology details, its diagrams, flow chart etc. as and when required or deemed fit to include. Also, prepare in-depth financial calculations which is necessary for the Investor/bank.

You will get the  report data IV Bottles Manufacturing Business in PDF or MS word. Which you can use easily. You can also modify the information according to your need. You will be able to access the data easily according to the your requirement. Additionally you can easily convert the data to PDF format.

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For whom are these formats useful?
  1. CA Chartered Accountants
  2. Tax Consultants
  3. Small Business Owners
  4. Students
  5. Engineers
  6. Who want to self study 

In addition to those who want to prepare project reports themselves.

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