In 2023, the GDP of Tennessee was valued at around 422 U.S. dollars. The manufacturing industry contributed 57.71 billion U.S. dollars of value to the state's gross domestic product. The finance, insurance, real estate, rental, and leasing industry contributed the most to the state's GDP with a value of 74.53 billion U.S. dollars in value added in the same year.

Graph and download economic data for Chain-Type Quantity Index for Real GDP: Primary Metal Manufacturing (331) in Tennessee (TNPRIMETMANQGSP) from 1997 to 2023 about primary metals, quantity index, primary, TN, metals, GSP, durable goods, private industries, goods, private, manufacturing, industry, GDP, and USA.

Real Gross Domestic Product: Primary Metal Manufacturing (NAICS 331) in Tennessee was 2177.30000 Mil. of Chn. 2009 $ in January of 2023, according to the United States Federal Reserve. Historically, Real Gross Domestic Product: Primary Metal Manufacturing (NAICS 331) in Tennessee reached a record high of 2177.30000 in January of 2023 and a record low of 803.20000 in January of 2009. Trading Economics provides the current actual value, an historical data chart and related indicators for Real Gross Domestic Product: Primary Metal Manufacturing (NAICS 331) in Tennessee - last updated from the United States Federal Reserve on June of 2025.

description: The water resources in Tennessee are likely to be stressed in the future by factors such as population increase, urban and suburban development, climate change, and other competing demands. Water-resource managers and policy makers will need accurate water-use data for regional water-supply planning including infrastructure investment, conservation, and cost-recovery strategies. Quantifying public-supply and self-supplied industrial water use and relating the use to effects on -water resources and natural hydrologic systems; is important for the public and policy makers. This dataset includes public-supply water-use and self-supplied industrial water-use information for the State of Tennessee in 2010. Public supply refers to water that is withdrawn by suppliers to furnish water year round to at least 25 people or has at least 15 service connections (U.S. Geological Survey, 1978). To assess public-supply water use in Tennessee, data were collected and analyzed for public-supply water systems active between January 1 and December 31, 2010. The public-supply water systems included investor-owned water companies, private water companies, municipal water departments, regional water authorities, residential developments, mobile-home parks, homeowner associations, and institutions such as schools and prisons. Self-supplied industrial water use refers to surface-water and groundwater withdrawals by facilities with total usage values greater than or equal to 10,000 gallons per day (gal/d) (Tennessee Department of Environment and Conservation, 2015) with mean withdrawals greater than or equal to 10,000 gal/d. To assess self-supplied industrial water use in Tennessee, data were collected and analyzed for industrial-water users active between January 1 and December 31, 2010. Industrial facilities use water for purposes such as fabrication, processing, washing, diluting, cooling, or transporting a product; incorporating water into a product; or for sanitation needs within a manufacturing facility (Maupin and others, 2014). Other industries that use large amounts of water produce commodities such as chemicals, food, metals, paper, or refined petroleum. References Maupin, M.A., Kenny, J.F., Hutson, S.S., Lovelace, J.K., Barber, N.L., and Linsey, K.S., 2014, Estimated use of water in the United States in 2010: U.S. Geological Survey Circular 1405, 56 p. [Also available at http://dx.doi.org/10.3133/cir1405.], Tennessee Department of Environment and Conservation, 2015, Water Withdrawal Registration Program: Nashville, Tenn., Tennessee Department of Environment and Conservation, accessed July 2015 at http://www.tn.gov/environment/article/wr-wq-water-withdrawal-registration-program, and U.S. Geological Survey, 1978, Public water supply, chap. 11.C of National handbook of recommended methods for water data acquisitionChapter 11Water use: U.S. Geological Survey, accessed December 17, 2013, at http://pubs.usgs.gov/chapter11/chapter11C.html.; abstract: The water resources in Tennessee are likely to be stressed in the future by factors such as population increase, urban and suburban development, climate change, and other competing demands. Water-resource managers and policy makers will need accurate water-use data for regional water-supply planning including infrastructure investment, conservation, and cost-recovery strategies. Quantifying public-supply and self-supplied industrial water use and relating the use to effects on -water resources and natural hydrologic systems; is important for the public and policy makers. This dataset includes public-supply water-use and self-supplied industrial water-use information for the State of Tennessee in 2010. Public supply refers to water that is withdrawn by suppliers to furnish water year round to at least 25 people or has at least 15 service connections (U.S. Geological Survey, 1978). To assess public-supply water use in Tennessee, data were collected and analyzed for public-supply water systems active between January 1 and December 31, 2010. The public-supply water systems included investor-owned water companies, private water companies, municipal water departments, regional water authorities, residential developments, mobile-home parks, homeowner associations, and institutions such as schools and prisons. Self-supplied industrial water use refers to surface-water and groundwater withdrawals by facilities with total usage values greater than or equal to 10,000 gallons per day (gal/d) (Tennessee Department of Environment and Conservation, 2015) with mean withdrawals greater than or equal to 10,000 gal/d. To assess self-supplied industrial water use in Tennessee, data were collected and analyzed for industrial-water users active between January 1 and December 31, 2010. Industrial facilities use water for purposes such as fabrication, processing, washing, diluting, cooling, or transporting a product; incorporating water into a product; or for sanitation needs within a manufacturing facility (Maupin and others, 2014). Other industries that use large amounts of water produce commodities such as chemicals, food, metals, paper, or refined petroleum. References Maupin, M.A., Kenny, J.F., Hutson, S.S., Lovelace, J.K., Barber, N.L., and Linsey, K.S., 2014, Estimated use of water in the United States in 2010: U.S. Geological Survey Circular 1405, 56 p. [Also available at http://dx.doi.org/10.3133/cir1405.], Tennessee Department of Environment and Conservation, 2015, Water Withdrawal Registration Program: Nashville, Tenn., Tennessee Department of Environment and Conservation, accessed July 2015 at http://www.tn.gov/environment/article/wr-wq-water-withdrawal-registration-program, and U.S. Geological Survey, 1978, Public water supply, chap. 11.C of National handbook of recommended methods for water data acquisitionChapter 11Water use: U.S. Geological Survey, accessed December 17, 2013, at http://pubs.usgs.gov/chapter11/chapter11C.html.

The global Push Plate Rubber Core Machine market is experiencing robust growth, driven by increasing demand from the automotive, aerospace, and industrial sectors. These industries rely heavily on precision-engineered rubber components, and the push plate rubber core machine plays a crucial role in their efficient and cost-effective production. While precise market size figures for 2025 are unavailable, based on industry analysis and considering similar machinery markets, we can estimate the 2025 market size to be approximately $500 million. Assuming a conservative Compound Annual Growth Rate (CAGR) of 5% over the forecast period (2025-2033), the market is projected to reach approximately $814 million by 2033. This growth is fueled by several key drivers, including advancements in automation technology leading to increased production efficiency, the rising adoption of rubber components in various applications, and stringent quality control requirements in industries like automotive, demanding high-precision manufacturing equipment. The market's competitive landscape is moderately concentrated, with several key players like Puluo Group, Stauff, and Tennessee Tool and Engineering holding significant market share. However, emerging manufacturers in regions like Asia-Pacific are steadily gaining traction, driven by cost advantages and increasing local demand. Market trends indicate a growing preference for automated and highly precise machines, coupled with a demand for sustainable manufacturing practices. This shift necessitates continuous innovation and adaptation from existing players and creates opportunities for new entrants offering environmentally friendly and advanced technology solutions. Restraints to growth include the relatively high initial investment costs for these machines and the cyclical nature of demand influenced by the overall economic conditions in major industries.