Jump to content

Textile industry

From Wikipedia, the free encyclopedia
(Redirected from British textiles)

An old textile factory ("Cvernovka") in Bratislava, Slovakia (1901–2004).
Textile factory (Germany, c. 1975).

The textile industry is primarily concerned with the design, production and distribution of textiles: yarn, cloth and clothing.

Industry process

[edit]

Cotton manufacturing

[edit]
Cotton manufacturing processes
Bale breaker Blowing room
Willowing
Breaker scutcher Batting
Finishing scutcher Lapping Teasing
Carding Carding room
Sliver lap
Combing
Drawing
Slubbing
Intermediate
Roving Fine roving
Mule spinning Ring spinning Spinning
Reeling Doubling
Winding Bundling Bleaching
Weaving shed Winding
Beaming Cabling
Warping Gassing
Sizing/slashing/dressing Spooling
Weaving
Cloth Yarn (cheese) Bundle Sewing thread

Cotton is the world's most important natural fibre. In the year 2007, the global yield was 25 million tons from 35 million hectares cultivated in more than 50 countries.[1] There are five stages of cotton manufacturing:[2]

  • Cultivating and harvesting
  • Preparatory processes
  • Spinning — giving yarn
  • Weaving — giving fabrics[a]
  • Finishing — giving textiles

In the textile industry, textile engineering is an area of engineering that involves the design, production, and distribution of textile products through processes including cultivation, harvesting, spinning, weaving, and finishing of raw materials, encompassing both natural and synthetic fibers.[3]

Synthetic fibres

[edit]

Artificial fibres can be made by extruding a polymer, through a spinneret (polymers) into a medium where it hardens. Wet spinning (rayon) uses a coagulating medium. In dry spinning (acetate and triacetate), the polymer is contained in a solvent that evaporates in the heated exit chamber. In melt spinning (nylons and polyesters) the extruded polymer is cooled in gas or air and then sets.[4] Some examples of synthetic fibers are polyester, rayon, acrylic fibers and microfibers. All these fibres will be of great length, often kilometres long. Synthetic fibers are more durable than most natural fibers and will readily pick-up different dyes. Artificial fibres can be processed as long fibres or batched and cut so they can be processed like natural fibre.

Natural fibres

[edit]

Sheep, goats, rabbits, silkworms, and other animals, as well as minerals like asbestos, are sources of natural fibers (cotton, flax, sisal). These vegetable fibers can originate from the seed (cotton), the stem (bast fibres: flax, hemp, jute), or the leaf (sisal). All of these sources require a number of steps, each of which has a distinct name, before a clean, even staple is produced. All of these fibers, with the exception of silk, are short, only a few centimeters long, and have a rough surface that allows them to adhere to other like staple fibers.

History

[edit]

Cottage stage

[edit]

There are some indications that weaving was already known in the Palaeolithic. An indistinct textile impression has been found at Pavlov, Moravia. Neolithic textiles were found in pile dwellings excavations in Switzerland and at El Fayum, Egypt at a site which dates to about 5000 BC.

In Roman times, wool, linen and leather clothed the European population, and silk, imported along the Silk Road from China, was an extravagant luxury. The use of flax fiber in the manufacturing of cloth in Northern Europe dates back to Neolithic times.

During the late medieval period, cotton began to be imported into Northern Europe. Without any knowledge of what it came from, other than that it was a plant, noting its similarities to wool, people in the region could only imagine that cotton must be produced by plant-borne sheep. John Mandeville, writing in 1350, stated as fact the now-preposterous belief: "There grew in India a wonderful tree which bore tiny lambs on the edges of its branches. These branches were so pliable that they bent down to allow the lambs to feed when they are hungry." This aspect is retained in the name for cotton in many European languages, such as German Baumwolle, which translates as "tree wool". By the end of the 16th century, cotton was cultivated throughout the warmer regions of Asia and the Americas.

The main steps in the production of cloth are producing the fibre, preparing it, converting it to yarn, converting yarn to cloth, and then finishing the cloth. The cloth is then taken to the manufacturer of garments. The preparation of the fibres differs the most, depending on the fibre used. Flax requires retting and dressing, while wool requires carding and washing. The spinning and weaving processes are very similar between fibers, however.

Spinning evolved from twisting the fibers by hand, to using a drop spindle, to using a spinning wheel. Spindles or parts of them have been found in archaeological sites and may represent one of the first pieces of technology available.[5] The spinning wheel was most likely invented in the Islamic world by the 11th century.[6]

Industrial Revolution

[edit]

The woven fabric portion of the textile industry grew out of the Industrial Revolution in the 18th century as mass production of yarn and cloth became a mainstream industry.[7]

In 1734 in Bury, Lancashire John Kay invented the flying shuttle — one of the first of a series of inventions associated with the cotton woven fabric industry. The flying shuttle increased the width of cotton cloth and speed of production of a single weaver at a loom.[8] Resistance by workers to the perceived threat to jobs delayed the widespread introduction of this technology, even though the higher rate of production generated an increased demand for spun cotton.

Shuttles

In 1761, the Duke of Bridgewater's canal connected Manchester to the coal fields of Worsley and in 1762, Matthew Boulton opened the Soho Foundry engineering works in Handsworth, Birmingham. His partnership with Scottish engineer James Watt resulted, in 1775, in the commercial production of the more efficient Watt steam engine which used a separate condenser.[citation needed]

In 1764, James Hargreaves is credited as inventor of the spinning jenny which multiplied the spun thread production capacity of a single worker — initially eightfold and subsequently much further. Others[9] credit the invention to Thomas Highs. Industrial unrest and a failure to patent the invention until 1770 forced Hargreaves from Blackburn, but his lack of protection of the idea allowed the concept to be exploited by others. As a result, there were more than 20,000 spinning jennies in use by the time of his death. Also in 1764, Thorp Mill, the first water-powered cotton mill in the world was constructed at Royton, Lancashire, and was used for carding cotton. With the spinning and weaving process now mechanized, cotton mills cropped up all over the North West of England.

The stocking frame invented in 1589 for silk became viable when in 1759, Jedediah Strutt introduced an attachment for the frame which produced what became known as the Derby Rib,[10] that produced a knit and purl stitch. This allowed stockings to be manufactured in silk and later in cotton. In 1768, Hammond modified the stocking frame to weave weft-knitted openworks or nets by crossing over the loops, using a mobile tickler bar – this led in 1781 to Thomas Frost's square net. Cotton had been too coarse for lace, but by 1805 Houldsworths of Manchester were producing reliable 300 count cotton thread.[11]

19th-century developments

[edit]

With the Cartwright Loom, the Spinning Mule and the Boulton & Watt steam engine, the pieces were in place to build a mechanised woven fabric textile industry. From this point there were no new inventions, but a continuous improvement in technology as the mill-owner strove to reduce cost and improve quality. Developments in the transport infrastructure; that is the canals and after 1831 the railways facilitated the import of raw materials and export of finished cloth.

Firstly, the use of water power to drive mills was supplemented by steam driven water pumps, and then superseded completely by the steam engines. For example, Samuel Greg joined his uncle's firm of textile merchants, and, on taking over the company in 1782, he sought out a site to establish a mill.Quarry Bank Mill was built on the River Bollin at Styal in Cheshire. It was initially powered by a water wheel, but installed steam engines in 1810. Quarry Bank Mill in Cheshire still exists as a well-preserved museum, having been in use from its construction in 1784 until 1959. It also illustrates how the mill owners exploited child labour, taking orphans from nearby Manchester to work the cotton. It shows that these children were housed, clothed, fed and provided with some education. In 1830, the average power of a mill engine was 48 hp, but Quarry Bank mill installed a new 100 hp water wheel.[12] William Fairbairn addressed the problem of line-shafting and was responsible for improving the efficiency of the mill. In 1815 he replaced the wooden turning shafts that drove the machines at 50rpm, to wrought iron shafting working at 250 rpm, these were a third of the weight of the previous ones and absorbed less power.[12]

A Roberts loom in a weaving shed in 1835. Note the wrought iron shafting, fixed to the cast iron columns

Secondly, in 1830, using an 1822 patent, Richard Roberts manufactured the first loom with a cast iron frame, the Roberts Loom.[8] In 1842 James Bullough and William Kenworthy, made the Lancashire Loom, a semiautomatic power loom: although it is self-acting, it has to be stopped to recharge empty shuttles. It was the mainstay of the Lancashire cotton industry for a century, until the Northrop Loom (invented in 1894, with an automatic weft replenishment function) gained ascendancy.

Roberts self-acting mule with quadrant gearing

Thirdly, also in 1830, Richard Roberts patented the first self-acting mule. Stalybridge mule spinners strike was in 1824; this stimulated research into the problem of applying power to the winding stroke of the mule.[13] The draw while spinning had been assisted by power, but the push of the wind had been done manually by the spinner, the mule could be operated by semiskilled labor. Before 1830, the spinner would operate a partially powered mule with a maximum of 400 spindles; after, self-acting mules with up to 1300 spindles could be built.[14]

Number of looms in the UK[15]
Year 1803 1820 1829 1833 1857
Looms 2400 14650 55500 100000 250000

The industrial revolution changed the nature of work and society The three key drivers in these changes were textile manufacturing, iron founding and steam power.[16][17][18][19] The geographical focus of textile manufacture in Britain was Manchester and the small towns of the Pennines and southern Lancashire.

Textile production in England peaked in 1926, and as mills were decommissioned, many of the scrapped mules and looms were bought up and reinstated in India.

Women began entering the workforce in the 19th century through textile factories,[20] the industrial and garment assembly jobs done during this time “[provided a] point for participation by rural women in the formal economy”. [21] While women began entering the workforce and earning wages for themselves, there was an assumption that the earned wages were ones that should “supplement the family income rather than provide it”,[20] which was typically done by that of the breadwinning father or husband. It was commonly acknowledged that the role of a woman as a textile worker was a "secondary occupation and that a woman's real work was raising children and running the household”. [20] This socially accepted convention was illustrated in the hiring process of female textile workers, employers preferred “hiring women who were young and unmarried: most machine operatives were between the ages of 16 and 25”. [20] This also affected the wage of female textile workers, since it was considered that a women’s wage in the textile industry was one to supplement the family, there was a “belief that women did not merit or require wages as high as those of men”. [20]

20th century

[edit]
Textile factory workers in Poland, 1950s
Textile workers at Finlayson factory in Tampere, Finland in 1951
Manila hemp warp yarns being prepared for weaving in a modern textile factory

Major changes came to the textile industry during the 20th century, with continuing technological innovations in machinery, synthetic fibre, logistics, and globalization of the business. The business model that had dominated the industry for centuries was to change radically. Cotton and wool producers were not the only source for fibres, as chemical companies created new synthetic fibres that had superior qualities for many uses, such as rayon, invented in 1910, and DuPont's nylon, invented in 1935 as in inexpensive silk substitute, and used for products ranging from women's stockings to tooth brushes and military parachutes.

The variety of synthetic fibres used in manufacturing fibre grew steadily throughout the 20th century. In the 1920s, the computer was invented; in the 1940s, acetate, modacrylic, metal fibres, and saran were developed; acrylic, polyester, and spandex were introduced in the 1950s. Polyester became hugely popular in the apparel market, and by the late 1970s, more polyester was sold in the United States than cotton.[22]

By the late 1980s, the apparel segment was no longer the largest market for fibre products, with industrial and home furnishings together representing a larger proportion of the fibre market.[23] Industry integration and global manufacturing led to many small firms closing for good during the 1970s and 1980s in the United States; during those decades, 95% of the looms in North Carolina, South Carolina and Georgia shut down, and Alabama and Virginia also saw many factories close.[23]

The largest exporters of textiles in 2013 were China ($274 billion), India ($40 billion), Italy ($36 billion), Germany ($35 billion), Bangladesh ($28 billion) and Pakistan ($27 Billion).[24]

By region

[edit]

India

[edit]
Textile workers in Tiruppur, South India

The textile industry in India traditionally, after agriculture, is the only industry that has generated huge employment for both skilled and unskilled labour in textiles. The textile industry continues to be the second-largest employment generating sector in India. It offers direct employment to over 35 million in the country.[25] According to the Ministry of Textiles, the share of textiles in total exports during April–July 2010 was 11.04%. During 2009–2010, the Indian textile industry was pegged at US$55 billion, 64% of which services domestic demand.[25] In 2010, there were 2,500 textile weaving factories and 4,135 textile finishing factories in all of India.[26] According to AT Kearney's 'Retail Apparel Index', India was ranked as the fourth most promising market for apparel retailers in 2009.[27]

India is first in global jute production and shares 63% of the global textile and garment market. India is second in global textile manufacturing and also second in silk and cotton production. 100% FDI is allowed via automatic route in textile sector. Rieter, Trutzschler, Saurer, Soktas, Zambiati, Bilsar, Monti, CMT, E-land, Nisshinbo, Marks & Spencer, Zara, Promod, Benetton, and Levi's are some of the foreign textile companies invested or working in India.[28]

Great Britain

[edit]

The key British industry at the beginning of the 18th century was the production of textiles made with wool from the large sheep-farming areas in the Midlands and across the country (created as a result of land-clearance and enclosure). This was a labour-intensive activity providing employment throughout Britain, with major centres being the West Country; Norwich and environs; and the West Riding of Yorkshire. The export trade in woolen goods accounted for more than a quarter of British exports during most of the 18th century, doubling between 1701 and 1770.[29] The British textile industry drove the Industrial Revolution, triggering advancements in technology, stimulating the coal and iron industries, boosting raw material imports, and improving transportation, which made Britain the global leader of industrialization, trade, and scientific innovation.[30]

Exports by the cotton industry – centered in Lancashire – had grown tenfold during this time, but still accounted for only a tenth of the value of the woolen trade. Before the 17th century, the manufacture of goods was performed on a limited scale by individual workers, usually on their own premises (such as weavers' cottages). Goods were transported around the country by clothiers who visited the village with their trains of packhorses. Some of the cloth was made into clothes for people living in the same area, and a large amount of cloth was exported. River navigations were constructed, and some contour-following canals. In the early 18th century, artisans were inventing ways to become more productive. Silk, wool, fustian, and linen were being eclipsed by cotton, which was becoming the most important textile. This set the foundations for the changes.[31]

Pakistan

[edit]

The textile sector accounts for 54% of Pakistan's export earnings.[32] The industry's contribution in the nation's exports account for 8.5% of the total GDP. Textile exports stood at $4.4 billion in 2017–18. The industry employs a large section of the labour force in the country.

Pakistan is the 4th largest producer of cotton with the third largest spinning capacity in Asia. It contributes 5% to the global spinning capacity. At present, there are 1,221 ginning units, 442 spinning units and 124 large spinning units in addition to 425 small units which produce textiles. Pakistan is the third largest consumer of cotton. Exports of $3.5 billion were recorded in 2017–18 (6.5% of the total exported cotton on the world).

In 1950, textile manufacturing emerged as the central of Pakistan industrialisation. Between 1947 and 2000, the number of textile Mills increased from 3 to 600. In the same time, spindles increased in number from 177,000 to 805 million.

Bangladesh

[edit]

Many Western multinationals use labor in Bangladesh, which is one of the cheapest in the world: 30 euros per month compared to 150 or 200 in China. Four days is enough for the CEO of one of the top five global textile brands to earn what a Bangladeshi garment worker will earn in her lifetime. In April 2013, at least 1,135 textile workers died in the collapse of their factory. Other fatal accidents due to unsanitary factories have affected Bangladesh: in 2005 a factory collapsed and caused the death of 64 people. In 2006, a series of fires killed 85 people and injured 207 others. In 2010, some 30 people died of asphyxiation and burns in two serious fires.

In 2006, tens of thousands of workers mobilized in one of the country's largest strike movements, affecting almost all of the 4,000 factories. The Bangladesh Garment Manufacturers and Exporters Association (BGMEA) uses police forces to crack down. Three workers were killed, and hundreds more were wounded by bullets, or imprisoned. In 2010, after a new strike movement, nearly 1,000 people were injured among workers as a result of the repression.[33]

Ethiopia

[edit]

Employees of Ethiopian garment factories, who work for brands such as Guess, H&M or Calvin Klein, receive a monthly salary of 26 dollars per month. These very low wages have led to low productivity, frequent strikes and high turnover. Some factories have replaced all their employees on average every 12 months, according to the 2019 report of the Stern Centre for Business and Human Rights at New York University.

The report states: "Rather than the docile and cheap labour force promoted in Ethiopia, foreign-based suppliers have met employees who are unhappy with their pay and living conditions and who want to protest more and more by stopping work or even quitting. In their eagerness to create a 'made in Ethiopia' brand, the government, global brands and foreign manufacturers did not anticipate that the base salary was simply too low for workers to make a living from."[34]

European Union

[edit]

The prominence of small and medium enterprises (SMEs) within the European Union's textile industry has been noted by the European Commission:

The European textile and clothing industry is a highly diversified, innovation and creativity driven industrial sector made up largely of SMEs: firms had an average of 10 employees in 2009, down from 18 employees at the beginning of the decade. In 2011, the sector consisted of more than 185 000 companies employing 1.7 million people in Europe and with a total turnover of € 152 billion.[35]: 3 

Catalonia

[edit]

The cotton industry in Catalonia was the first industry in Spain to industrialise and led, by the mid 19th century, to Catalonia becoming the main industrial region of Spain, a position it maintained until well into the 20th century. Catalonia is the one Mediterranean exception to the tendency of early industrialisation to be concentrated in northern Europe.[36]

The industry began in the early 18th century in Barcelona, when printed cloth chintz (Catalan: indianes) was produced as an import substitution. The market quickly expanded to the American colonies from where dyes and (later) cotton raw materials could be sourced. Spinning was a late addition to the industry and took off after English spinning technology was introduced at the turn of the 19th century. Industrialisation of the industry occurred in the 1830s after adoption of the factory system, and the removal of restrictions by Britain on the emigration of expert labour (1825) and of machinery (1842). Steam power was introduced but the cost of imported coal and steam engines, led to the extensive use of hydraulic power from the late 1860s.

Commerce and regulation

[edit]

The Multi Fibre Arrangement (MFA) governed the world trade in textiles and garments from 1974 through 2004, imposing quotas on the amount developing countries could export to developed countries. It expired on 1 January 2005.

The MFA was introduced in 1974 as a short-term measure intended to allow developed countries to adjust to imports from the developing world. Developing countries have a natural advantage in textile production because it is labor-intensive and they have low labor costs. According to a World Bank/International Monetary Fund (IMF) study, the system has cost the developing world 27 million jobs and $40 billion a year in lost exports.[37]

However, the Arrangement was not negative for all developing countries. For example, the European Union (EU) imposed no restrictions or duties on imports from the very poor countries, such as Bangladesh, leading to a massive expansion of the industry there.

At the General Agreement on Tariffs and Trade (GATT) Uruguay Round, it was decided to bring the textile trade under the jurisdiction of the World Trade Organization (WTO). The WTO Agreement on Textiles and Clothing (ATC) provided for the gradual dismantling of the quotas that existed under the MFA. This process was completed on 1 January 2005. However, large tariffs remain in place on many textile products.

Women work in a textile factory outside Dhaka, Bangladesh.

Bangladesh was expected to suffer the most from the ending of the MFA, as it was expected to face more competition, particularly from China. However, this was not the case. It turns out that even in the face of other economic giants, Bangladesh's labor is "cheaper than anywhere else in the world." While some smaller factories were documented making pay cuts and layoffs, most downsizing was essentially speculative – the orders for goods kept coming even after the MFA expired. In fact, Bangladesh's exports increased in value by about $500 million in 2006.[38]

Regulatory standards

[edit]

For textiles, like for many other products, there are certain national and international standards and regulations that need to be complied with to ensure quality, safety and sustainability.

The following standards amongst others apply to textiles:

  • CPSIA, e.g. Standard for the Flammability of Clothing Textiles[39]
  • ASTM Textile Standards[40]
  • REACH Regulations for Textiles[41]
  • China Product Standard for Textiles[42]
  • In the European Union, the Textile Regulation (Regulation 1007/2011 on textile fibre names and related labelling and marking of fibre composition of textile products) applies. This replaced earlier Directives 73/44/EC, 96/73/EC and 2008/121/EC, which had required transposition into national law, with effect from 8 May 2012.[35]

Environmental impact

[edit]
Indigo color water pollution in Phnom Penh, Cambodia, 2005

The textile industry is one of the largest polluters in the globalized world of mostly free market dominated socioeconomic systems.[43] Chemically polluted textile wastewater degrades the quality of the soil and water.[44] The pollution comes from the type of conduct of chemical treatments used e.g., in pretreatment, dyeing, printing, and finishing operations[45] that many or most market-driven companies use despite "eco-friendly alternatives". Textile industry wastewater is considered to be one the largest polluters of water and soil ecosystems, causing "carcinogenic, mutagenic, genotoxic, cytotoxic and allergenic threats to living organisms".[46][47] The textile industry uses over 8000 chemicals in its supply chain,[48] also polluting the environment with large amounts of microplastics[49] and has been identified in one review as the industry sector producing the largest amount of pollution.[50]

A campaign of big clothing brands like Nike, Adidas and Puma to voluntarily reform their manufacturing supply chains to commit to achieving zero discharges of hazardous chemicals by 2020 (global goal)[51][52] appears to have failed.

The textile industry also creates a lot of pollution that leads to externalities which can cause large economic problems. The problem usually occurs when there is no division of ownership rights. This means that the problem of pollution is largely caused because of incomplete information about which company pollutes and at what scale the damage was caused by the pollution.

Worker Health Impacts

[edit]

Chemical Exposures

[edit]

Within the textile industry, more than 8000 different chemicals may be used in the manufacturing process, many of which are toxic or nonbiodegradable.[53] Some textile factory workers handle dangerous chemicals every day, leading to increased occupational risk of hearing disorders, dermatitis, and ophthalmological symptoms when not using protective measures.[53] Additionally, an increase of miscarriages occurs when pregnant textile workers are exposed to natural and synthetic fibers.[53] Other diseases can be caused by frequent hazardous chemical exposures.

Cancer Risks

[edit]

With increased exposure to toxic chemicals comes an increased risk of occupational cancer. Studies of textile workers have shown an increased risk of nasal, bladder and urinary cancers, which are thought to be related to the dyes that are used.[53]

Physical Hazards

[edit]

Ergonomic Hazards

[edit]

When producing textiles, many repetitive physical movements are made by workers. From this, issues and pain can arise, particularly in textile sewing machine operators. Of these operators, many experienced lower back and neck pain.[54] Other common pain areas reported were upper back, shoulders, and the hips and thighs.[54] Additionally, 69% of the workers reported hard knuckles within the past 12 months, which occurs from scissor induced calluses.[54]

Dust Exposure

[edit]

Various health effects occur when regularly exposed to dust without protective measures. Common dust related respiratory symptoms include cough, phlegm, shortness of breath, wheezing and chest pain.[55] Respiratory disorder symptoms in textile workers not using personal protective equipment were 1,130 times more likely than their coworkers who used personal protective equipment and other protective measures.[55] The study also found that when the amount of dust in the air was greater than the quality standard, workers were at a higher risk of having respiratory disorder symptoms.[55] Fiber dust exposure has also been found to contribute to the risk of cancers, such as lung cancer.[56]

Noise exposure

High noise exposures have been observed in textile industries across countries, as well as high rates of occupational hearing loss.[57][58]


See also

[edit]

Notes

[edit]
  1. ^ includes Knitting processes

References

[edit]

Citations

[edit]
  1. ^ Majeed, A (January 19, 2009), Cotton and textiles — the challenges ahead, Dawn-the Internet edition, archived from the original on January 23, 2009, retrieved 2009-02-12
  2. ^ "Machin processes", Spinning the Web, Manchester City Council: Libraries, archived from the original on 2008-10-23, retrieved 2009-01-29
  3. ^ Elmogahzy, Yehia E. (August 15, 2019). Engineering Textiles: Integrating the Design and Manufacture of Textile Products (2nd ed.). Sawston, Cambridge: Woodhead Publishing. p. 462. ISBN 978-0081024881.
  4. ^ Collier 1970, p. 33
  5. ^ Cotton: Origin, History, Technology, and Production By C. Wayne Smith, Joe Tom Cotton. Page viii. Published 1999. John Wiley and Sons. Technology & Industrial Arts. 864 pages. ISBN 0-471-18045-9
  6. ^ Pacey, Arnold (1991) [1990]. Technology in World Civilization: A Thousand-Year History (First MIT Press paperback ed.). Cambridge MA: The MIT Press. pp. 23–24.
  7. ^ Hammond, J.L.; Hammond, Barbara (1919), The Skilled Labourer 1760–1832 (pdf), London: Longmans, Green and co., p. 51
  8. ^ a b Williams & Farnie 1992, p. 11
  9. ^ Great Industries of Great Britain, Volume I, published by Cassell Petter and Galpin, (London, Paris, New York, c1880).
  10. ^ Earnshaw 1986, p. 17.
  11. ^ Earnshaw 1986, pp. 24–26.
  12. ^ a b Hills 1993, p. 113
  13. ^ Hills 1993, p. 118
  14. ^ Williams & Farnie 1992, p. 9
  15. ^ Hills 1993, p. 117
  16. ^ Eric Hobsbawm, The Age of Revolution: Europe 1789–1848, Weidenfeld & Nicolson Ltd. ISBN 0-349-10484-0
  17. ^ Joseph E Inikori. Africans and the Industrial Revolution in England, Cambridge University Press. ISBN 0-521-01079-9 Read it
  18. ^ Berg, Maxine (1992). "Rehabilitating the Industrial Revolution" (PDF). The Economic History Review. 45 (1): 24–50. doi:10.2307/2598327. JSTOR 2598327.
  19. ^ Rehabilitating the Industrial Revolution Archived 2006-11-09 at the Wayback Machine by Julie Lorenzen, Central Michigan University. Retrieved November 2006.
  20. ^ a b c d e Scott, Joan Wallach (1982-09-01). "The Mechanization of Women's Work". Scientific American. 247 (3): 166–187. Bibcode:1982SciAm.247c.166S. doi:10.1038/scientificamerican0982-166. Retrieved 2024-04-04.
  21. ^ English, Beth (2013). "Global Women's Work: Historical Perspectives on the Textile and Garment Industries". Journal of International Affairs. 67 (1): 67–82. ISSN 0022-197X. JSTOR 24461672.
  22. ^ The U.S. textile and apparel industry : a revolution in progress : special report. United States Congress, Office of Technology Assessment. 1987. p. 39. ISBN 9781428922945.
  23. ^ a b The U.S. textile and apparel industry : a revolution in progress : special report. United States Congress, Office of Technology Assessment. 1987. pp. 31–2. ISBN 9781428922945.
  24. ^ TNN (3 June 2014). "India overtakes Germany and Italy, is new world No. 2 in textile exports". Times of India. Archived from the original on 30 June 2016. Retrieved 2 September 2016.
  25. ^ a b "A brief history of Textile Industry in India, January, 2010" (PDF). Archived from the original (PDF) on 22 May 2012.
  26. ^ "Wearing Apparel Manufacturing Report". AnythingResearch India.
  27. ^ "Emerging Markets Offer Growth Opportunities for Apparel Retailers Battling Declines in Domestic Consumer Spending".
  28. ^ Sectors – Make In India
  29. ^ Toynbee, Arnold (1884). Lectures On The Industrial Revolution In England: Public Addresses, Notes and Other Fragments, together with a Short Memoir by B. Jowett. London: Rivington's. ISBN 978-1-4191-2952-0. Archived from the original on 2016-03-03.
  30. ^ "Textile Manufacturing | Boundless World History". courses.lumenlearning.com. Retrieved 2021-10-29.
  31. ^ Industrial Revolution and the Standard of Living: The Concise Encyclopedia of Economics. Archived 2008-02-21 at the Wayback Machine, Library of Economics and Liberty
  32. ^ "Phase I – Research on garments industry in Pakistan". International Growth Centre. 2007-06-30. Retrieved 2024-10-18.
  33. ^ "Au Bangladesh, une ouvrière du textile meurt tous les deux jours". 15 May 2013.
  34. ^ "En Ethiopie, les petites mains de H&M ou Calvin Klein gagnent 23 euros par mois". Le Monde.fr. 8 May 2019.
  35. ^ a b Report From the Commission to the European Parliament and the Council regarding possible new labelling requirements of textile products and on a study on allergenic substances in textile products, COM(2013) 656 final, published 25 September 2013, accessed 21 August 2023
  36. ^ Thomson, J.K.J. (1992). A distinctive industrialisation. Cotton in Barcelona 1728-1832. Cambridge University Press. ISBN 0-521-39482-1. Retrieved 14 July 2022.
  37. ^ Presentation by H.E. K.M. Chandrasekhar, Chairman ITCB, EC Conference on the Future of Textiles and Clothing after 2004, Brussels, 5–6 May 2003. "後遺症が残りそうな交通事故で気をつけるポイント" (PDF). Archived (PDF) from the original on 2008-12-21. Retrieved 2011-10-05.
  38. ^ Haider, Mahtab. "Defying predictions, Bangladesh's garment factories thrive". The Christian Science Monitor. 7 Feb 2006. 11 Feb 2007. "Defying predictions, Bangladesh's garment factories thrive". Christian Science Monitor. 2006-02-07. Archived from the original on 2007-09-30. Retrieved 2007-02-11.
  39. ^ "Standard for the Flammability of Clothing Textiles" (PDF). cpsc.gov. Archived (PDF) from the original on 8 January 2013. Retrieved 30 April 2018.
  40. ^ "Textile Standards". www.astm.org. Archived from the original on 30 April 2018. Retrieved 30 April 2018.
  41. ^ "REACH Regulations - How they apply to Textile and Leather articles (hktdc.com)". info.hktdc.com. Archived from the original on 30 April 2018. Retrieved 30 April 2018.
  42. ^ "GB Standards - China Certification – CCC mark certificate (3C) for China – Your expert for China Compulsory Certification". china-certification.com. Archived from the original on 13 January 2018. Retrieved 30 April 2018.
  43. ^ Niinimäki, Kirsi; Peters, Greg; Dahlbo, Helena; Perry, Patsy; Rissanen, Timo; Gwilt, Alison (April 2020). "The environmental price of fast fashion". Nature Reviews Earth & Environment. 1 (4): 189–200. doi:10.1038/s43017-020-0039-9. ISSN 2662-138X. Retrieved 8 June 2024.
  44. ^ Pattnaik, Punyasloka; Dangayach, G. S.; Bhardwaj, Awadhesh Kumar (1 June 2018). "A review on the sustainability of textile industries wastewater with and without treatment methodologies". Reviews on Environmental Health. 33 (2): 163–203. doi:10.1515/reveh-2018-0013. ISSN 2191-0308. PMID 29858909. S2CID 44084197.
  45. ^ Madhav, Sughosh; Ahamad, Arif; Singh, Pardeep; Mishra, Pradeep Kumar (March 2018). "A review of textile industry: Wet processing, environmental impacts, and effluent treatment methods". Environmental Quality Management. 27 (3): 31–41. doi:10.1002/tqem.21538.
  46. ^ Kishor, Roop; Purchase, Diane; Saratale, Ganesh Dattatraya; Saratale, Rijuta Ganesh; Ferreira, Luiz Fernando Romanholo; Bilal, Muhammad; Chandra, Ram; Bharagava, Ram Naresh (1 April 2021). "Ecotoxicological and health concerns of persistent coloring pollutants of textile industry wastewater and treatment approaches for environmental safety" (PDF). Journal of Environmental Chemical Engineering. 9 (2): 105012. doi:10.1016/j.jece.2020.105012. ISSN 2213-3437. S2CID 233532794.
  47. ^ Akhtar, Muhammad Furqan; Ashraf, Muhammad; Javeed, Aqeel; Anjum, Aftab Ahmad; Sharif, Ali; Saleem, Mohammad; Mustafa, Ghulam; Ashraf, Moneeb; Saleem, Ammara; Akhtar, Bushra (28 February 2018). "Association of textile industry effluent with mutagenicity and its toxic health implications upon acute and sub-chronic exposure". Environmental Monitoring and Assessment. 190 (3): 179. doi:10.1007/s10661-018-6569-7. ISSN 1573-2959. PMID 29492685. S2CID 3710964.
  48. ^ Nimkar, Ullhas (1 February 2018). "Sustainable chemistry: A solution to the textile industry in a developing world". Current Opinion in Green and Sustainable Chemistry. 9: 13–17. doi:10.1016/j.cogsc.2017.11.002. ISSN 2452-2236.
  49. ^ Xu, Xia; Hou, Qingtong; Xue, Yingang; Jian, Yun; Wang, LiPing (20 November 2018). "Pollution characteristics and fate of microfibers in the wastewater from textile dyeing wastewater treatment plant". Water Science and Technology. 78 (10): 2046–2054. doi:10.2166/wst.2018.476. ISSN 0273-1223. PMID 30629532. S2CID 58649372.
  50. ^ Behera, Meerambika; Nayak, Jayato; Banerjee, Shirsendu; Chakrabortty, Sankha; Tripathy, Suraj K. (1 August 2021). "A review on the treatment of textile industry waste effluents towards the development of efficient mitigation strategy: An integrated system design approach". Journal of Environmental Chemical Engineering. 9 (4): 105277. doi:10.1016/j.jece.2021.105277. ISSN 2213-3437. S2CID 233901225.
  51. ^ "Destination Zero: seven years of Detoxing the clothing industry" (PDF). Greenpeace. Retrieved 30 September 2020.
  52. ^ "Greenpeace Calls Out Nike, Adidas and Puma for Toxic Clothing". Reuters. 9 August 2011. Retrieved 30 September 2020.
  53. ^ a b c d Tounsadi, Hanane; Metarfi, Yousra; Taleb, M.; El Rhazi, Karima; Rais, Zakia (July 2020). "Impact of chemical substances used in textile industry on the employee's health: Epidemiological study". Ecotoxicology and Environmental Safety. 197: 110594. Bibcode:2020EcoES.19710594T. doi:10.1016/j.ecoenv.2020.110594. PMID 32335392. S2CID 216557035.
  54. ^ a b c Okareh, O.T.; Solomon, O.E.; Olawoyin, R. (April 2021). "Prevalence of ergonomic hazards and persistent work-related musculoskeletal pain among textile sewing machine operators". Safety Science. 136: 105159. doi:10.1016/j.ssci.2021.105159. S2CID 233072066.
  55. ^ a b c Berlian, Alifia; Setiani, Onny; Sulistiyani, Sulistiyani; Raharjo, Mursid; Darundiati, Yusniar (2023-03-01). "The Relationship of Dust Exposure with Respiratory Disorders Symptoms Among Textile Industry Workers". Journal of Ecological Engineering. 24 (3): 35–46. doi:10.12911/22998993/157389. ISSN 2299-8993.
  56. ^ Singh, Zorawar; Chadha, Pooja (December 2016). "Textile industry and occupational cancer". Journal of Occupational Medicine and Toxicology. 11 (1): 39. doi:10.1186/s12995-016-0128-3. ISSN 1745-6673. PMC 4986180. PMID 27532013.
  57. ^ Yildirim, Ilhami; Kilinc, Metin; Okur, Erdogan; Inanc Tolun, Fatma; Kiliç, M. Akif; Kurutas, Ergul Belge; Ekerbi̇çEr, Hasan Çetin (2007). "The Effects of Noise on Hearing and Oxidative Stress in Textile Workers". Industrial Health. 45 (6): 743–749. doi:10.2486/indhealth.45.743. ISSN 0019-8366. PMID 18212468.
  58. ^ Zaw, Aung K.; Myat, Aung M.; Thandar, Mya; Htun, Ye M.; Aung, Than H.; Tun, Kyaw M.; Han, Zaw M. (June 2020). "Assessment of Noise Exposure and Hearing Loss Among Workers in Textile Mill (Thamine), Myanmar: A Cross-Sectional Study". Safety and Health at Work. 11 (2): 199–206. doi:10.1016/j.shaw.2020.04.002. ISSN 2093-7911. PMC 7303531. PMID 32596016.

Sources

[edit]
  • Collier, Ann M. (1970), A Handbook of Textiles, Pergamon Press, p. 258, ISBN 978-0-08-018057-1
  • Copeland, Melvin Thomas. The cotton manufacturing industry of the United States (Harvard University Press, 1912) online
  • Cameron, Edward H. Samuel Slater, Father of American Manufactures (1960) scholarly biography
  • Conrad Jr., James L. "'Drive That Branch': Samuel Slater, the Power Loom, and the Writing of America's Textile History", Technology and Culture, Vol. 36, No. 1 (January 1995), pp. 1–28 in JSTOR
  • Earnshaw, Pat (1986). Lace Machines and Machine Laces. Batsford. ISBN 978-0713446845.
  • Griffiths, T., Hunt, P.A., and O'Brien, P. K. "Inventive activity in the British textile industry", Journal of Economic History, 52 (1992), pp. 881–906.
  • Griffiths, Trevor; Hunt, Philip; O'Brien, Patrick. "Scottish, Irish, and imperial connections: Parliament, the three kingdoms, and the mechanization of cotton spinning in eighteenth-century Britain", Economic History Review, Aug 2008, Vol. 61 Issue 3, pp 625–650
  • Hills, Richard Leslie (1993), Power from Steam: A History of the Stationary Steam Engine, Cambridge University Press, p. 244, ISBN 9780521458344
  • Smelser; Neil J., Social Change in the Industrial Revolution: An Application of Theory to the British Cotton Industry (1959)
  • Tucker, Barbara M., "The Merchant, the Manufacturer, and the Factory Manager: The Case of Samuel Slater", Business History Review, Vol. 55, No. 3 (Autumn, 1981), pp. 297–313 in JSTOR
  • Tucker, Barbara M.,, Samuel Slater and the Origins of the American Textile Industry, 1790-1860 (1984)
  • Williams, Mike; Farnie (1992), Cotton Mills of Greater Manchester, Carnegie Publishing, ISBN 978-0-948789-89-2
  • Woytinsky, W. S., and E. S. Woytinsky. World Population and Production Trends and Outlooks (1953) pp. 1051–98; with many tables and maps on the worldwide textile industry in 19508
[edit]