Banana paper

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Banana plant paper

Banana paper is a type of paper created from banana plant bark or banana peel fibers. Banana paper has a lower density, higher stiffness, higher disposability, higher renewability, and higher tensile strength compared to traditional paper. [1] These qualities are due to the cellular composition of banana fiber, which consists of cellulose, hemicellulose, and lignin. [2]

Contents

During the manufacturing process of banana paper, the fibers are ground until they appear similar to saw dust. Then, the fiber is washed to remove natural resins to create agricultural fiber. If the natural resins are not washed away, these resins would take away from the integrity of the paper. The process of pulping produces pulp to be used in the manufacturing of paper. This pulp is used to create post-consumer fiber (processed fiber). The post consumer fiber is combined with the agricultural fiber to make banana paper. [3]

Development

The earliest evidence of the use of banana stems as a source of fiber dates back to 13th century Japan. However, its popularity declined with the upsurge of silk and cotton fibers imported from China and India. [4]

Banana paper was first patented in the United States on March 16, 1912, by Charles M. Taylor and Howard Kay Cook. They both learned that cellulose fiber can be easily removed from the waste of the banana plant, and that the fiber is well adapted to making durable paper. Taylor and Cook applied for the patent on March 16, 1912. The application was granted on May 2, 1916, and they received a lifetime patent. The patent is now expired. [5]

Properties

Raw banana paper has a coarse surface due to the presence of hemicellulose, lignin, and other waxy components in the fiber. Hemicellulose is located between and within the cellulose fibrils and is incorporated into the cellulose structure. The fiber or pulp with high hemicellulose content has a high maximum tensile strength and a low maximum tear index. The cellulosic fibers enclose the outside of cellulose fibers, acting as natural binders. Long wrapped fiber bundles are a key component of banana paper. Length is also a significant fiber property, as longer fibers contain more fiber joints. These fiber joints contribute to a stronger network of fibers. Long fiber manufactured papers usually have better strength properties than short fiber manufactured papers. [6]

Banana fiber can vary in weight and thickness depending on the specific part of the banana stem used. Sturdy, thick fibers can be taken from the outer sheaths, and softer fibers can be extracted from the inner sheaths. [2] [4]

The properties of banana paper overall include a lower density, higher stiffness, higher disposability, higher renewability, and higher tensile strength compared to traditional paper. [1]

Manufacturing process

The paper can be handmade or produced by machinery. Both the handmade and machine processes have similar steps. First, banana stems are collected as they contain more than 4% fiber which can be used to manufacture banana paper. The fiber from the banana is removed and washed in order to eliminate natural resins that can decrease the strength and durability of the paper. The washed fibers are used to form a stronger fiber (agricultural fiber). Then, the process of pulping makes pulp used in the production of paper. This pulp is used to produce the post-consumer fiber and is mixed with the agricultural fiber. Lastly, the mixed fibers are either molded together by a deckle (a tool used for handmade processes of molding fibers) or a machine. [3] [7]

Environmental impact

After bananas are harvested from plantations, the stems and trunks are usually discarded. However, these parts contain available sources of fibers. If the scrapped stems and trunks are utilized, this can lead to a decrease in synthetic fiber production. Synthetic fiber production requires extra energy, fertilizer, and chemicals. [8]  Banana paper does not require any chemicals to be used during manufacturing.[ citation needed ] Banana paper is also more durable and has a longer lifetime than conventional paper. [9]  Therefore, the manufacturing of banana paper does not add to environmental pollution. Banana paper reduces pollution by having lower disposal costs and less agricultural waste enter landfills and rivers. The production of banana paper uses less energy compared to traditional paper production as the traditional paper industry is one of the largest sources of energy consumption. [10] Therefore, banana paper is less impactful on natural resources, such as forests. [11]

Future of industry

The global banana paper market size was approximately $490 million in 2021, and is projected to reach $760 million by 2031, according to Business Research Insights, a global market research firm. [12]  The banana paper market is expanding because of a growing number of uses for banana paper such as paper pens, business cards, greeting cards, notebooks, and other stationery items. The market is specifically expanding in Europe, North America, South America, and APAC (Asia-Pacific). The expanding banana paper market is further supported by its low production cost. Factors contributing to the low production cost include relatively inexpensive banana fiber extraction machinery and ease of operation of these machines by unskilled workers. [13]

Related Research Articles

<span class="mw-page-title-main">Cellulose</span> Polymer of glucose and structural component of cell wall of plants and green algae

Cellulose is an organic compound with the formula (C
6H
10O
5)
n, a polysaccharide consisting of a linear chain of several hundred to many thousands of β(1→4) linked D-glucose units. Cellulose is an important structural component of the primary cell wall of green plants, many forms of algae and the oomycetes. Some species of bacteria secrete it to form biofilms. Cellulose is the most abundant organic polymer on Earth. The cellulose content of cotton fiber is 90%, that of wood is 40–50%, and that of dried hemp is approximately 57%.

<span class="mw-page-title-main">Wood</span> Fibrous material from trees or other plants

Wood is a structural tissue found in the stems and roots of trees and other woody plants. It is an organic material – a natural composite of cellulose fibers that are strong in tension and embedded in a matrix of lignin that resists compression. Wood is sometimes defined as only the secondary xylem in the stems of trees, or more broadly to include the same type of tissue elsewhere, such as in the roots of trees or shrubs. In a living tree it performs a support function, enabling woody plants to grow large or to stand up by themselves. It also conveys water and nutrients between the leaves, other growing tissues, and the roots. Wood may also refer to other plant materials with comparable properties, and to material engineered from wood, woodchips, or fiber.

<span class="mw-page-title-main">Pulp (paper)</span> Fibrous material used notably in papermaking

Pulp is a fibrous lignocellulosic material prepared by chemically, semi-chemically or mechanically producing cellulosic fibers from wood, fiber crops, waste paper, or rags. Mixed with water and other chemicals or plant-based additives, pulp is the major raw material used in papermaking and the industrial production of other paper products.

<span class="mw-page-title-main">Paper engineering</span>

Paper engineering is a branch of engineering that deals with the usage of physical science and life sciences in conjunction with mathematics as applied to the converting of raw materials into useful paper products and co-products. The field applies various principles in process engineering and unit operations to the manufacture of paper, chemicals, energy and related materials. The following timeline shows some of the key steps in the development of the science of chemical and bioprocess engineering:

<span class="mw-page-title-main">Pulpwood</span> Timber intended for processing into wood pulp for paper production

Pulpwood can be defined as timber that is ground and processed into a fibrous pulp. It is a versatile natural resource commonly used for paper-making but also made into low-grade wood and used for chips, energy, pellets, and engineered products.

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Lyocell is a semi-synthetic fiber used to make textiles for clothing and other purposes. It is a form of regenerated cellulose made by dissolving pulp and dry jet-wet spinning. Unlike rayon made by the more common viscose processes, Lyocell production does not use carbon disulfide, which is toxic to workers and the environment. Lyocell was originally trademarked as Tencel in 1982.

<span class="mw-page-title-main">Bagasse</span> Residue of sugar cane after juice extraction

Bagasse is the dry pulpy fibrous material that remains after crushing sugarcane or sorghum stalks to extract their juice. It is used as a biofuel for the production of heat, energy, and electricity, and in the manufacture of pulp and building materials. Agave bagasse is similar, but is the material remnants after extracting blue agave sap.

<span class="mw-page-title-main">Kraft process</span> Process of converting wood into wood pulp

The kraft process (also known as kraft pulping or sulfate process) is a process for conversion of wood into wood pulp, which consists of almost pure cellulose fibres, the main component of paper. The kraft process involves treatment of wood chips with a hot mixture of water, sodium hydroxide (NaOH), and sodium sulfide (Na2S), known as white liquor, that breaks the bonds that link lignin, hemicellulose, and cellulose. The technology entails several steps, both mechanical and chemical. It is the dominant method for producing paper. In some situations, the process has been controversial because kraft plants can release odorous products and in some situations produce substantial liquid wastes.

<span class="mw-page-title-main">Pulp mill</span> Facility which pulps wood or plant fibre

A pulp mill is a manufacturing facility that converts wood chips or other plant fiber sources into a thick fiber board which can be shipped to a paper mill for further processing. Pulp can be manufactured using mechanical, semi-chemical, or fully chemical methods. The finished product may be either bleached or non-bleached, depending on the customer requirements.

<span class="mw-page-title-main">Black liquor</span> Industrial by-product

In industrial chemistry, black liquor is the by-product from the kraft process when digesting pulpwood into paper pulp removing lignin, hemicelluloses and other extractives from the wood to free the cellulose fibers.

<span class="mw-page-title-main">Kraft paper</span> Paper or paperboard produced from chemical pulp produced in the kraft process

Kraft paper or kraft is paper or paperboard (cardboard) produced from chemical pulp produced in the kraft process.

<span class="mw-page-title-main">Lignocellulosic biomass</span> Plant dry matter

Lignocellulose refers to plant dry matter (biomass), so called lignocellulosic biomass. It is the most abundantly available raw material on the Earth for the production of biofuels. It is composed of two kinds of carbohydrate polymers, cellulose and hemicellulose, and an aromatic-rich polymer called lignin. Any biomass rich in cellulose, hemicelluloses, and lignin are commonly referred to as lignocellulosic biomass. Each component has a distinct chemical behavior. Being a composite of three very different components makes the processing of lignocellulose challenging. The evolved resistance to degradation or even separation is referred to as recalcitrance. Overcoming this recalcitrance to produce useful, high value products requires a combination of heat, chemicals, enzymes, and microorganisms. These carbohydrate-containing polymers contain different sugar monomers and they are covalently bound to lignin.

<span class="mw-page-title-main">Biocomposite</span>

A biocomposite is a composite material formed by a matrix (resin) and a reinforcement of natural fibers. Environmental concern and cost of synthetic fibres have led the foundation of using natural fibre as reinforcement in polymeric composites. The matrix phase is formed by polymers derived from renewable and nonrenewable resources. The matrix is important to protect the fibers from environmental degradation and mechanical damage, to hold the fibers together and to transfer the loads on it. In addition, biofibers are the principal components of biocomposites, which are derived from biological origins, for example fibers from crops, recycled wood, waste paper, crop processing byproducts or regenerated cellulose fiber (viscose/rayon). The interest in biocomposites is rapidly growing in terms of industrial applications and fundamental research, due to its great benefits. Biocomposites can be used alone, or as a complement to standard materials, such as carbon fiber. Advocates of biocomposites state that use of these materials improve health and safety in their production, are lighter in weight, have a visual appeal similar to that of wood, and are environmentally superior.

The sulfite process produces wood pulp that is almost pure cellulose fibers by treating wood chips with solutions of sulfite and bisulfite ions. These chemicals cleave the bonds between the cellulose and lignin components of the lignocellulose. A variety of sulfite/bisulfite salts are used, including sodium (Na+), calcium (Ca2+), potassium (K+), magnesium (Mg2+), and ammonium (NH4+). The lignin is converted to lignosulfonates, which are soluble and can be separated from the cellulose fibers. For the production of cellulose, the sulfite process competes with the Kraft process which produces stronger fibers and is less environmentally costly.

Dissolving pulp, also called dissolving cellulose, is bleached wood pulp or cotton linters that has a high cellulose content. It has special properties including a high level of brightness and uniform molecular-weight distribution. This pulp is manufactured for uses that require a high chemical purity, and particularly low hemicellulose content, since the chemically similar hemicellulose can interfere with subsequent processes. Dissolving pulp is so named because it is not made into paper, but dissolved either in a solvent or by derivatization into a homogeneous solution, which makes it completely chemically accessible and removes any remaining fibrous structure. Once dissolved, it can be spun into textile fibers, or chemically reacted to produce derivatized celluloses, such cellulose triacetate, a plastic-like material formed into fibers or films, or cellulose ethers such as methyl cellulose, used as a thickener.

<span class="mw-page-title-main">Cellulose fiber</span> Fibers made with ethers or esters of cellulose

Cellulose fibers are fibers made with ethers or esters of cellulose, which can be obtained from the bark, wood or leaves of plants, or from other plant-based material. In addition to cellulose, the fibers may also contain hemicellulose and lignin, with different percentages of these components altering the mechanical properties of the fibers.

Wood-free paper is paper created exclusively from chemical pulp rather than mechanical pulp. Chemical pulp is normally made from pulpwood, but is not considered wood as most of the lignin is removed and separated from the cellulose fibers during processing, whereas mechanical pulp retains most of its wood components and can therefore still be described as wood. Wood-free paper is not as susceptible to yellowing as paper containing mechanical pulp. Wood-free paper offers several environmental and economic benefits, including reduced deforestation, decreased energy consumption, and improved waste management. The term Wood-free paper can be rather misleading or confusing for someone unfamiliar with the papermaking process because paper is normally made from wood pulp derived from trees and shrubs. However, wood free paper does not mean that the paper in question is not made from wood pulp but it means that the lignin in the wood fiber has been removed by a chemical process.

In industrial paper-making processes, organosolv is a pulping technique that uses an organic solvent to solubilise lignin and hemicellulose. It has been considered in the context of both pulp and paper manufacture and biorefining for subsequent conversion of cellulose to fuel ethanol. The process was invented by Theodor Kleinert in 1968 as an environmentally benign alternative to kraft pulping.

<span class="mw-page-title-main">Paper chemicals</span> Chemicals used in paper manufacturing

Paper chemicals designate a group of chemicals that are used for paper manufacturing, or modify the properties of paper. These chemicals can be used to alter the paper in many ways, including changing its color and brightness, or by increasing its strength and resistance to water. The chemicals can be defined on basis of their usage in the process.

Hemp paper is a paper variety consisting exclusively or to a large extent from pulp obtained from fibers of industrial hemp. The products are mainly specialty papers such as cigarette paper, banknotes and technical filter papers. Compared to wood pulp, hemp pulp offers a four to five times longer fibre, a significantly lower lignin fraction as well as a higher tear resistance and tensile strength. Because the paper industry's processes have been optimized for wood as the feedstock, production costs currently are much higher than for paper from wood.

References

  1. 1 2 Subagyo, Chafidz, Asmanto, Achmad (2018). Banana Pseudo-Stem Fiber: Preparation, Characterisitcs, and Applications.{{cite book}}: CS1 maint: multiple names: authors list (link)
  2. 1 2 Reddy, Yang, Narendra, Yiqi (2014). Fibers from Banana Pseudo Stems.{{cite book}}: CS1 maint: multiple names: authors list (link)
  3. 1 2 "Eco-Paper Production". Vikaspedia.
  4. 1 2 Trade, Made (2019-08-19). "Behind the Fiber: Transforming Banana Tree Waste Into Fabric". Medium. Retrieved 2020-11-19.
  5. ,"Process of manufacturing paper-pulp.",issued 1912-03-16
  6. Othman, Siti (2019). Health Physics Series-1. Malaysia: Universiti Tun Hussein Onn Malaysia.
  7. "Banana Paper Making". www.techxlab.org. Retrieved 2020-11-19.
  8. Pitimaneeyakul, Uraiwan. Banana Fiber: Environmental Friendly Fabric. Thailand: King Mongkut’s Institute of Technology Ladkrabang.
  9. "Global Banana Paper Market by Distribution Channel & Geography - Forecast to 2023 - ResearchAndMarkets.com". AP NEWS. 2019-09-10. Retrieved 2020-11-19.
  10. "About Us". www.ecopaper.com. Retrieved 2020-11-19.
  11. Laurijssen, Jobien; Faaij, André; Worrell, Ernst (2013-02-01). "Benchmarking energy use in the paper industry: a benchmarking study on process unit level". Energy Efficiency. 6 (1): 49–63. doi: 10.1007/s12053-012-9163-9 . ISSN   1570-6478.
  12. "Banana Paper Market Size, Share, Growth, And Industry Analysis". Business Research Insights. Retrieved 2024-07-10.
  13. "Global Banana Paper Market 2019-2023 | Increasing Applications of Banana Paper to Boost Growth | Technavio". www.businesswire.com. 2019-08-30. Retrieved 2020-11-19.
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