Fact-checked by Grok 2 weeks ago

Lacquer thinner

Lacquer thinner is a specialized blend designed to thin, dissolve, and clean lacquer-based paints and finishes, enabling smoother application and removal of residues. It consists of a of fast-evaporating chemicals that target the resins in lacquers, distinguishing it from general-purpose thinners like mineral spirits. The composition varies by manufacturer but typically includes solvents such as acetone, toluene, xylene, methyl ethyl ketone, ethyl acetate, and diluents like aliphatic naphtha or methanol. These components dissolve lacquer solids to reduce viscosity, with varying evaporation rates controlling drying for an even finish. Over-thinning can lead to drips, while under-thinning may cause uneven application; ratios are adjusted based on temperature and humidity, typically in the range of 55-90°F (13-32°C). Primarily used in , automotive refinishing, and industrial coatings, lacquer thinner improves flow for professional results, cleans equipment, and removes residues. It is not suitable for oil-based paints, as its aggressive solvent nature can degrade them, and it evaporates faster than paint thinners. Due to high flammability ( around -18°C) and , it poses risks including and potential organ damage. Use in well-ventilated areas with PPE; dispose as . Its high content subjects it to regulations, with low-VOC variants available as of 2025.

Overview

Definition

Lacquer thinner is a specialized mixture formulated to dissolve and thin nitrocellulose-based , primarily by breaking down their components to achieve the desired consistency for application. This blend enables the lacquer to be applied more evenly, whether by brushing, spraying, or other methods, while maintaining its ability to form a durable finish. Unlike general paint thinners, which are designed for oil-based paints that cure through oxidation and —rendering them insoluble once dried—lacquer thinner specifically targets that dry via . This evaporation-based drying process allows cured lacquer layers to be re-dissolved by the thinner, facilitating adjustments or removals without permanent bonding. In its basic mechanism, lacquer thinner reduces the of the mixture, improving flow and leveling during application; as the solvents evaporate rapidly after deposition, they leave behind a hard, glossy film composed of the original resins. This process ensures a smooth, protective coating suitable for , metal, and other surfaces, distinct from slower-curing alternatives.

Physical and chemical properties

Lacquer thinner is typically a clear, colorless liquid at , exhibiting low characteristic of mixtures, which facilitates its flow and application . Its high is evident from boiling points generally ranging between 56°C and 110°C, with specific components contributing to this range—for instance, acetone boils at 56°C and at 110°C. The of lacquer thinner formulations falls within 0.8–0.9 g/cm³, influencing its handling and requirements. As a chemical , lacquer thinner is highly flammable, with flash points typically below 0°C, often measured around -20°C in closed-cup tests, necessitating stringent precautions. Its with varies by formulation and component ratios; polar solvents like acetone are fully miscible, while non-polar ones like show limited . Under normal conditions, lacquer thinner remains but can react vigorously with strong oxidizing agents, potentially leading to hazardous or . Its solvency power, crucial for dissolving resins in lacquers, is quantified by the , which for typical mixtures ranges from 18 to 20 MPa^{1/2}, aligning with values for key components such as acetone (19.9 MPa^{1/2}) and (18.2 MPa^{1/2}).

Composition

Historical formulations

In the early 20th century, lacquer thinners were formulated as multi-component solvent blends to effectively dissolve and dilute nitrocellulose-based lacquers for industrial applications. A typical composition included 20–30% alkyl esters such as , 10–20% s like acetone or methyl ethyl ketone, 20–40% aromatic hydrocarbons such as , 5–10% ethers like cellosolve ( monoethyl ether), and 5–10% alcohols such as . These proportions varied by manufacturer and specific use, but the mixtures were designed to balance solvency, evaporation rates, and application properties, as seen in s from the and that emphasized stable, blush-resistant thinners for spray application. Each solvent class served a distinct role in the formulation to optimize the performance of lacquers. Alkyl esters like provided primary solvency for the polymer, enabling effective dissolution and film formation. Aromatic hydrocarbons such as facilitated penetration into substrates and improved wetting during application. Ketones like acetone contributed to rapid for fast-drying finishes, while alcohols such as aided in blending the components and adjusting viscosity to prevent issues like precipitation or uneven drying. Ethers like cellosolve acted as retarders to control and enhance overall . These historical formulations were prevalent in automotive and furniture finishing from the 1920s through the 1980s, revolutionizing production by enabling quick-drying, sprayable coatings that supported high-volume manufacturing. In the , nitrocellulose lacquers thinned with these solvents became standard by the mid-1920s, allowing for colorful, durable finishes on vehicles. Similarly, they dominated furniture production, accounting for about 75% of U.S. wood finishes by 1978 due to their clarity and ease of application. This widespread use persisted until environmental regulations prompted shifts toward less volatile alternatives.

Modern formulations

Modern formulations of lacquer thinner vary, with traditional high-VOC blends (often ~90% VOC or 700 g/L) remaining common outside strict regulatory areas, while low-VOC variants—developed primarily since the 1990s for compliance with volatile organic compound (VOC) regulations—minimize hazardous aromatics and emphasize fast-evaporating . These compliant blends typically consist of 40–60% acetone as the primary solvent, supplemented by 20–30% other such as methyl ethyl ketone (MEK), with aromatic hydrocarbons like limited to less than 5% or eliminated entirely. Low-VOC thinners help meet overall coating VOC limits under U.S. Environmental Protection Agency (EPA) standards, such as 680 g/L for lacquers in architectural coatings (40 CFR Part 59, Subpart D). To further reduce VOC emissions while maintaining solvency, manufacturers incorporate exempt solvents such as tertiary butyl acetate (TBAC), which is classified as VOC-exempt under EPA regulations due to its low photochemical reactivity. Typical compliant blends may include 10–20% TBAC alongside acetone and esters like , resulting in overall levels as low as 230–300 g/L; for instance, one achieves 229 g/L through 65–83% acetone balanced with 25–32% monobutyl ether. These adjustments ensure adherence to regional rules, including (CARB) limits of 25 g/L (3% by weight) for consumer paint thinners and multi-purpose solvents, as well as South Coast Air Quality Management District (SCAQMD) Rule 1143. EU REACH requirements restrict specific substances like (e.g., <0.1% in consumer mixtures) through safe registration and use limits. Variations exist between industrial and consumer-grade products, with industrial formulations often allowing slightly higher ketone concentrations for enhanced performance in heavy-duty applications, while consumer versions cap additives to meet stricter retail VOC thresholds. Some modern blends incorporate up to 10% water-miscible alcohols, such as methanol or tetrahydrofurfuryl alcohol, to improve stability and reduce flammability without significantly elevating VOC profiles. As of 2025, ongoing developments include bio-based solvents and reformulations for faster evaporation to address evolving regulations.

History

Early development

The development of lacquer thinner emerged in the early 1920s as part of 's innovations in nitrocellulose lacquers, which were created to address the limitations of slower-drying varnishes used in automotive painting. DuPont chemists, building on prior acquisitions of nitrocellulose solvent technologies dating back to 1905, formulated quick-evaporating solvent blends to dissolve nitrocellulose into sprayable solutions, enabling faster production cycles in the burgeoning automobile industry. This shift was driven by post-World War I overcapacity in nitrocellulose production, repurposed from munitions to coatings. Lacquer thinner's initial purpose was to facilitate thin, glossy finishes on metal and wood surfaces, particularly car bodies, by reducing viscosity for efficient spraying and rapid drying—often within hours rather than days. DuPont's Duco, the first major commercial nitrocellulose lacquer system including its dedicated thinner, was introduced in collaboration with General Motors in 1923, debuting on Oakland touring cars and slashing finishing times from two weeks to two days. By 1925, Duco and its thinner were widely marketed, supporting vibrant, durable colors that enhanced aesthetic appeal in mass-produced vehicles. Key milestones included the 1921 invention of a stable nitrocellulose lacquer formulation by DuPont chemist Edmund Flaherty, patented as low-viscosity lacquer (U.S. Patent 1,629,999) in 1927, which optimized solvent blends for better flow and film formation. Adoption accelerated with mass production; for instance, the 1927 Ford Model A incorporated nitrocellulose lacquer finishes enabled by such thinners, standardizing glossy, quick-dry coatings across the industry and boosting efficiency in assembly lines. These early advancements laid the foundation for lacquer thinning as an essential component in industrial finishing.

Evolution due to regulations

The Clean Air Act Amendments of 1970 established the U.S. Environmental Protection Agency (EPA) and introduced initial federal standards for controlling volatile organic compound (VOC) emissions to combat ground-level ozone formation, prompting the coatings industry to reduce reliance on high-VOC solvents like toluene and xylene in formulations such as lacquer thinners. These early regulations targeted solvent-based products, leading to gradual phase-outs of aromatic hydrocarbons due to their significant contribution to VOC emissions in surface coating operations. By the late 1970s, EPA guidelines for stationary sources began enforcing emission controls on solvent use, accelerating the shift away from traditional petroleum-derived thinners toward lower-emission alternatives. The 1990 Clean Air Act Amendments further intensified these efforts by mandating stricter national ambient air quality standards and capping VOC emissions from coatings at 3.5 pounds per gallon (excluding water and exempt solvents), directly impacting lacquer thinner compositions used in industrial and architectural applications. This limit, applied across categories like metal and plastic parts coatings, compelled manufacturers to reformulate thinners by minimizing or eliminating high-VOC components such as toluene and xylene, fostering innovation in compliant solvent blends. In parallel, California's Air Resources Board pioneered even more stringent low-VOC rules in the 1980s, starting with architectural coatings and extending to consumer solvents, which set a precedent for nationwide adoption by requiring thinners sold in the state to meet reduced emission thresholds ahead of federal timelines. Internationally, the European Union's VOC Directive 2004/42/EC imposed binding limits on emissions from paints, varnishes, and vehicle refinishing products, restricting total VOC content—including aromatic solvents—to 420 grams per liter for many categories by 2007, thereby reshaping lacquer thinner formulations across member states to favor low-aromatic alternatives. This directive complemented the earlier 1999/13/EC Solvents Emissions Directive, which targeted industrial solvent use, and drove a harmonized reduction in hazardous aromatics like xylene in thinners. As of 2025, global standards have tightened further with the United Nations Globally Harmonized System (GHS) Revision 11, updating hazard classifications for chemical mixtures like lacquer thinners to include enhanced labeling for flammability, toxicity, and environmental risks, promoting safer handling and transport worldwide. Concurrently, regulatory pressures have accelerated the adoption of bio-based solvents in some markets, with formulations derived from renewable sources such as vegetable oils gaining traction to meet low-VOC mandates and sustainability goals, evidenced by market projections showing a compound annual growth rate of 7.8% for bio-based coatings through 2030.

Uses

Thinning lacquers

Lacquer thinner serves as the primary solvent for reducing the viscosity of or coatings, enabling smoother application via spraying or brushing methods. The standard process involves gradually adding 10–50% lacquer thinner by volume to the lacquer, stirring thoroughly until the desired flow consistency is achieved, which facilitates better leveling and atomization during application. This range allows for adjustments based on factors like temperature, humidity, and the specific lacquer formulation, ensuring the mixture remains workable without compromising the finish's durability. The evaporation rate of the thinned lacquer is precisely controlled by the thinner's solvent blend; for instance, slower-evaporating components such as can act as retarders to extend open time and mitigate issues like dry spray in hot or low-humidity environments. For optimal results with high-volume low-pressure (HVLP) spray guns, technicians commonly employ thinning ratios of 25–33% lacquer thinner to the lacquer volume, promoting fine atomization and uniform coverage while minimizing material waste. Compatibility between the thinner and lacquer is paramount to prevent application defects: incompatible solvents can lead to blushing, a hazy or milky appearance caused by trapped moisture in humid conditions exceeding 65% relative humidity, or fisheye cratering from surface contaminants like oils or silicones that disrupt wet-edge flow. Always test the mixture on scrap material to verify flow and drying behavior before full application. In automotive refinishing, lacquer thinner is indispensable for thinning clear coats applied over base colors, typically at 10–20% ratios to achieve glossy, protective layers resistant to weathering on vehicle panels. Similarly, in woodworking for furniture finishing, it enables the application of multiple thin coats on items like cabinets and tables, yielding a hard, amber-toned surface that highlights wood grain while offering repairability through solvent re-dissolution.

Cleaning and other applications

Lacquer thinner is widely used for cleaning tools and equipment after lacquer application, as it effectively dissolves dried lacquer residues from brushes, spray guns, and overspray on surfaces. By soaking affected parts in the solvent, users can remove stubborn buildup, restoring functionality to painting tools without mechanical abrasion. This cleaning action stems from the solvent's ability to break down -based lacquers, making it a standard choice in woodworking and automotive finishing. Beyond tool maintenance, lacquer thinner serves in surface preparation by degreasing metal parts prior to painting, where it dissolves oils, resins, and grease to promote better adhesion. It is also applied for spot removal on natural fiber fabrics, particularly to eliminate paint or varnish stains when used sparingly and tested first to avoid damage. In adhesive processes, the thinner removes residue from surfaces, aiding cleanup after bonding operations. However, lacquer thinner has notable limitations, as its strong solvency can dissolve or damage plastics, rendering it unsuitable for cleaning plastic components or surfaces.

Safety and health effects

Acute hazards

Lacquer thinner is classified as a highly flammable liquid under the , typically in Category 2, with a flash point as low as -18°C (0°F), posing a significant fire hazard even at room temperature. Its vapors are heavier than air and can travel to ignition sources, creating explosive mixtures in confined spaces with lower explosive limits around 1% and upper limits up to 13% by volume. Autoignition temperatures for lacquer thinner formulations range from approximately 290°C to 465°C, depending on the specific solvent blend, which underscores the risk of spontaneous combustion under high heat conditions. Short-term inhalation of lacquer thinner vapors can cause acute effects such as dizziness, headache, nausea, and irritation of the respiratory tract, with higher concentrations potentially leading to weakness or loss of coordination. Ingestion of lacquer thinner is highly toxic and can result in severe outcomes, including methemoglobinemia, a condition where hemoglobin is oxidized to methemoglobin, impairing oxygen transport in the blood; case studies document this in accidental swallowing incidents, often requiring urgent treatment with methylene blue. Direct skin contact with lacquer thinner may cause severe irritation, redness, or chemical burns due to its solvent properties, while eye exposure leads to serious irritation, pain, and potential corneal damage. First aid for skin or eye contact involves immediate flushing with large amounts of water for at least 15 minutes, followed by seeking medical attention if irritation persists.

Chronic exposure risks

Chronic exposure to lacquer thinner, which often contains aromatic hydrocarbons such as and ketones like , primarily occurs through repeated inhalation or dermal contact in occupational settings like painting or manufacturing. Over time, these exposures can lead to cumulative neurological, reproductive, and dermatological effects, with risks increasing based on duration and concentration. Monitoring occupational exposure is guided by established limits, such as the American Conference of Governmental Industrial Hygienists (ACGIH) Threshold Limit Value (TLV) of 20 ppm for as an 8-hour time-weighted average (TWA), and the National Institute for Occupational Safety and Health (NIOSH) Recommended Exposure Limit (REL) of 100 ppm TWA over 10 hours. Aromatic components like toluene in lacquer thinner are linked to central nervous system (CNS) damage from prolonged exposure, manifesting as chronic toxic encephalopathy characterized by cognitive deficits, memory impairment, and subtle behavioral changes. Studies of solvent-exposed workers, including painters, show a higher incidence of these neurobehavioral effects, with evidence of persistent color vision impairment and hearing loss even at low levels. For instance, long-term occupational exposure to mixed solvents has been associated with multifocal CNS damage, including cortical and cerebellar atrophy in severe cases. Toluene exposure during pregnancy is associated with reproductive and developmental risks, including intrauterine growth retardation, low birth weight, and craniofacial abnormalities in offspring, as observed in cohort studies of exposed women. These effects stem from toluene's ability to cross the placenta, potentially disrupting fetal CNS development, though human data indicate risks primarily at higher exposure levels above occupational limits. No confirmed reproductive toxicity has been established for men, but overall, such findings underscore the need for protective measures in fertile workers. Ketones such as acetone in lacquer thinner can cause chronic dermatitis upon repeated skin contact, leading to dryness, cracking, and irritation due to defatting of the skin barrier. Occupational handling without proper gloves has been linked to persistent contact dermatitis in workers, though systemic effects from acetone are less pronounced compared to aromatics.

Environmental impact

Volatile organic compounds

Lacquer thinners primarily consist of organic solvents such as , , , and , which are classified as (VOCs) due to their high vapor pressure and tendency to evaporate readily into the atmosphere. Historically, traditional lacquer thinners emitted 739–850 g/L of VOCs, reflecting their composition of non-exempt solvents with densities typically ranging from 0.8 to 1.0 g/mL, resulting in near-complete volatilization during application or evaporation. In regions with strict regulations, such as California, modern low-VOC formulations achieve emissions as low as 25 g/L or less by incorporating exempt compounds like or , which reduce the regulated VOC content while maintaining solvency; however, many industrial formulations remain above 500 g/L. These VOCs from lacquer thinners contribute to smog formation through photochemical reactions in the presence of and sunlight, generating ground-level ozone and secondary organic aerosols that degrade urban air quality. Internationally, regulations like the EU's REACH restrict certain solvents in lacquer thinners due to environmental and health concerns, promoting lower-VOC alternatives as of 2025. Upon release, the VOCs in lacquer thinners undergo rapid volatilization, with evaporation rates driven by their low boiling points (typically 50–110°C for common components), leading to quick dispersion into the troposphere. This process facilitates their participation in photochemical cycles, where they react with hydroxyl radicals and NOx to produce tropospheric ozone, a key component of photochemical smog that persists for days to weeks in the lower atmosphere. Bioaccumulation potential for these solvents is low, attributed to their moderate to high water solubility (e.g., methanol >1000 g/L, acetone fully miscible) and rapid atmospheric degradation, which limit persistence in biological tissues or sediments despite some components like showing low-to-moderate factors (BCF < 100). The VOC content of lacquer thinners is measured using EPA Method 24, which determines volatile matter, , , and in coatings and related solvents through a combination of after heating at 110°C and measurements, providing the grams of VOC per liter as applied. While VOCs from solvents indirectly influence climate by enhancing tropospheric levels—a —their direct global warming potential is negligible compared to major greenhouse gases like CO2 or , as most evaporate and react within hours to days without long-term .

Disposal and regulations

Lacquer thinner, when spent or contaminated, is classified as a hazardous waste under the U.S. (RCRA) F-list, specifically under codes F001 through F005 for spent halogenated and non-halogenated solvents such as , , and acetone commonly found in its composition. Proper disposal methods include high-temperature at approximately 1000°C to ensure complete destruction of organic components, or through processes that recover reusable solvents while separating residues for further treatment. It is strictly prohibited to pour lacquer thinner down drains or into sewers, as this constitutes illegal discharge and risks contaminating water sources. In the United States, large-scale processes involving over 10,000 pounds of flammable liquids like lacquer thinner may fall under OSHA standard 1910.119, which mandates to prevent releases of highly hazardous chemicals. In the , the Waste Framework Directive 2008/98/EC, as revised in 2025, governs the classification and management of solvent wastes like lacquer thinner as hazardous if they exhibit properties such as flammability or , requiring separate collection and treatment. schemes apply to specific waste streams like textiles but not directly to solvents. Best practices for handling lacquer thinner waste emphasize secondary systems, such as diking or double-walled containers, to prevent spills during and . For spill response, immediate using inert absorbents like is recommended to soak up the liquid, followed by collection and disposal as to minimize environmental release.

References

  1. [1]
    Lacquer Thinner - Corrosionpedia
    Lacquer thinner is used to thin, dissolve and clean up lacquer-based paints or lacquer products. It helps to increase the flow and leveling of lacquer.
  2. [2]
    The Difference Between Lacquer Thinner and Paint Thinner
    Nov 26, 2024 · Lacquer thinner is a strong liquid thinner and solvent. Containing up to 10 ingredients, lacquer thinner is a compound with mixture ratios that ...Missing: definition | Show results with:definition<|separator|>
  3. [3]
    [PDF] Lacquer Thinner - SAFETY DATA SHEET
    Details of the supplier of the safety data sheet ... The information given is designed only as a guidance for safe handling, use, processing,.Missing: definition | Show results with:definition
  4. [4]
    None
    ### Summary of Klean Strip Lacquer Thinner (SDS)
  5. [5]
    What chemicals are in your lacquer thinner? - Woodworking Network
    Jun 9, 2016 · Lacquer thinner is actually a combination of different chemicals. These chemicals fall into two categories. They can be diluent solvents and, thus, dilute the ...Missing: definition | Show results with:definition
  6. [6]
    Everything You Need To Know About Lacquer Thinner
    Jan 20, 2023 · Lacquer thinners enjoy massive popularity as industrial degreasers as they can be used to remove tar and grease from different surfaces.Missing: definition | Show results with:definition
  7. [7]
    LACQUER THINNER - Sunnyside Corporation
    Lacquer Thinner is a professional strength, general purpose, medium-dry lacquer thinner for use in thinning clear and pigmented nitrocellulose lacquers and
  8. [8]
    Understanding Lacquer Thinner | Popular Woodworking
    Dec 11, 2023 · Lacquer thinner is the thinner used for all types of lacquer (not water-based finishes, which are sometimes misrepresented as “lacquer”).
  9. [9]
    40 CFR 59.101 -- Definitions. - eCFR
    Lacquer means a thermoplastic coating which dries primarily by solvent evaporation, and which is resoluble in its original solvent. Low-gloss coating means ...<|control11|><|separator|>
  10. [10]
    Ill. Admin. Code tit. 35, § 211.3230 - Lacquers | State Regulations
    ... dry by evaporation without a chemical reaction. Lacquers are resoluble in their original solvent. Notes. Ill. Admin. Code tit. 35 , § 211.3230. Added at 17 ...
  11. [11]
    [PDF] 1143 - 1 (Adopted March 6, 2009) (Amended June 4, 2010 ... - AQMD
    Dec 3, 2010 · (9) LACQUER THINNERS are solvents that are manufactured for the purpose of thinning, diluting, dissolving, and for clean-up of lacquer coatings.
  12. [12]
    [PDF] Lacquer Thinner - SAFETY DATA SHEET
    PHYSICAL AND CHEMICAL PROPERTIES. Physical and Chemical Properties. Physical State. Liquid. Appearance. Clear. Odor. Mild. Color. No information available. Odor ...
  13. [13]
    [PDF] LACQUER THINNER - Crown Paint
    Jul 16, 2021 · SECTION 9: Physical and chemical properties. 9.1. Information on basic physical and chemical properties. Physical state. : Liquid. Color. : No ...<|control11|><|separator|>
  14. [14]
    [PDF] SAFETY DATA SHEET
    LACQUER THINNER. Section 9. Physical and chemical properties. Physical state. Melting point. Vapor pressure. Density. Vapor density. Solubility. Liquid. Not ...
  15. [15]
    [PDF] Lacquer Thinner MATERIAL SAFETY DATA SHEET
    Apr 1, 2013 · Extremely flammable. Poison. May be fatal or cause blindness if swallowed. Vapor harmful. Use only with adequate ventilation to prevent buildup ...
  16. [16]
    Surface Tension, Hansen Solubility Parameters, Molar Volume ...
    Acetone (propanone), C3H6O, 67-64-1, 58.08, 23.0, -0.12, 32.19, 19.9, 15.5, 10.4 ... Ethyl acetate (ethyl ethanoate), C4H8O2, 141-78-6, 88.11, 23.2, -0.12, 35.66 ...
  17. [17]
    US1835927A - Nitrocellulose lacquer thinner - Google Patents
    The process of preparing a lacquer thinner which comprises refluxing a mixture comprising one volume butyl alcohol, two and one-half volumes, approximately, 50 ...Missing: historical 1920s
  18. [18]
    Nitrocellulose composition - US1521859A - Google Patents
    By way of example, I may prepare a varnish or lacquer by mixing 30% by weight of ethyl methyl ketone with of ethyl alcohol and 50% of benzol. In this mixture I ...Missing: historical 1920s
  19. [19]
    Volatile Solvents Used in Industry - American Journal of Public Health
    According to one expert, toluol and butyl acetate make a better solvent for spray lacquer than benzol, because the latter evaporates too fast and causes " ...Missing: solvency blending
  20. [20]
    Cellosolve - MFA Cameo - Museum of Fine Arts Boston
    May 24, 2022 · Cellosolve dissolves many oils, resins, and waxes. It is used as a solvent for nitrocellulose resins, spray lacquers, varnishes, and enamels.
  21. [21]
    History Timeline and Types of Automotive Paint - The Garage™
    Nov 6, 2014 · The 1920s saw the beginning of the introduction to spray equipment and nitrocellulose lacquers and primers which were developed together to ...
  22. [22]
    [PDF] Cellulose Nitrate in Conservation (1988) - Getty Museum
    Cellulose nitrate is a polynitrate ester of cellulose, a semisynthetic polymer with unique properties, and is the most important inorganic ester of cellulose.
  23. [23]
    [PDF] Control of Volatile Organic Compounds from Adhesives and Sealants
    The test solvent for this determination shall be any lacquer thinner with a minimum vapor pressure of 105 mm of Hg at 20 degrees Celsius, and the minimum test ...
  24. [24]
    [PDF] LOW VOC LACQUER THINNER #3 - SAFETY DATA SHEET
    0000067-64-1 ACETONE 64.8% - 82.8% 0000111-76-2 ETHYLENE GLYCOL MONOBUTYL ETHER 25.2% - 32.2% 0000071-43-2 BENZENE 0 - 0.001 % LOW VOC LACQUER THINNER #3 Page ...
  25. [25]
    US7785413B2 - Lacquer thinner - Google Patents
    The thinner has an acetone, methyl acetate or tertiary butyl acetate or mixture as a base. ... OSHA finds no hazardous ingredients other than acetone in this new ...Missing: modern | Show results with:modern
  26. [26]
    [PDF] Method 310 Determination of Volatile Organic Compounds (VOC) in ...
    1.3 Method 310 determines the total volatile material in a product and the presence of any compounds prohibited by CARB regulations (“prohibited compounds”) ...<|control11|><|separator|>
  27. [27]
    [PDF] AUTOMOTIVE PRO LACQUER THINNER LOW VOC - Rust-Oleum
    Rust-Oleum® Professional Lacquer Thinner is a high- solvency thinner effective for diluting lacquer-based finishes. It is also excellent for cleaning spray guns ...Missing: viscosity cP<|control11|><|separator|>
  28. [28]
    DuPont Paint Information - UtahRails.net
    Nov 6, 2024 · DuPont Duco was a lacquer formula dating from 1923. It held its gloss better over time and stood up to regular washing better, and being a lacquer, took less ...
  29. [29]
    True Blue: DuPont and the Color Revolution | Science History Institute
    Oct 13, 2007 · By early 1922 the firms started to adapt Viscolac, a DuPont nitrocellulose lacquer used for painting pencils, into a new lacquer, Duco, ...Missing: thinner | Show results with:thinner
  30. [30]
    How cars went from "any color, as long as it's black" to a rainbow of ...
    Oct 11, 2022 · While plenty of early Model Ts came in other colors than black, Ford did switch to all-black because a finish called “Japan Black” lacquer ...<|separator|>
  31. [31]
    Clean Air Act Guidelines and Standards for Solvent Use and Surface ...
    Jun 5, 2025 · The following are the stationary sources of air pollution for the solvent use and surface coating industries, and their corresponding air pollution regulations.
  32. [32]
    40 CFR 63.745 -- Standards: Primer, topcoat, and specialty coating ...
    (4) VOC emissions from topcoats shall be limited to a VOC content level of no more than: 420 g/L (3.5 lb/gal) of coating (less water and exempt solvents) as ...Missing: 1990 cap
  33. [33]
    [PDF] Control Techniques Guidelines for Miscellaneous Metal and Plastic ...
    VOC/l (3.5 lb VOC/gallon) of coating, as applied, excluding water and exempt ... Coatings, and Air Bag Cover Coatings - 5.9 lb VOC/gal (0.71 kg VOC/L).
  34. [34]
    Your Guide to VOCs in Paint and Cleaning Products - Green Seal
    Cleaning products, paints and coatings, and several other product types are required to have low VOC content if they are sold in California. The Golden State ...
  35. [35]
    [PDF] Coating Industry (Paints, Lacquers and Varnishes) (EN) - OECD
    Two-pack paints have a solvent content of 0-50% depending on their composition and their thinning requirements. In general, they have lower VOC content than ...
  36. [36]
    Improved sectoral allocation of NMVOC emissions from solvent use ...
    In order to control NMVOC emissions from solvents, the Council of EU has imposed a gradual implementation of measures regarding the limitation of NMVOC ...
  37. [37]
    The Shift Toward Bio-Based Coatings | PCI Magazine
    Sep 7, 2025 · We are witnessing a notable and growing shift toward bio-based materials in the coatings industry. This movement is driven by multiple ...
  38. [38]
    All About Lacquers - WOOD Magazine
    Mar 20, 2025 · Brushing lacquer can be thinned and sprayed, but because it dries slower, apply light coats to avoid runs and drips. You'll need to experiment ...
  39. [39]
    Thinning the final clear coat? - Body and Paint - AutoBody101.com
    Oct 8, 2012 · I do 10% on 4:1 Clears and up to 20% on 2:1 clears. I haven't noticed any problems with the finishes, I have painted like 200 cars in the past 2 ...
  40. [40]
    4 Effective Uses for Lacquer Thinner - Hi-Tek Products
    Nov 27, 2019 · Lacquer thinner is used for cleaning surfaces, paintbrushes, tools, engines, machinery, removing tar and tree sap, and thinning lacquers.
  41. [41]
    What Is Lacquer Thinner Used For - Paint Thinner
    ### Summary of Lacquer Thinner Uses from Ecolink.com
  42. [42]
    #90 Lacquer Thinner - Whitaker
    #90 Lacquer Thinner is also highly effective in equipment cleaning, like brushes, spray guns, and application tools. #90 Lacquer Thinner plays a crucial ...
  43. [43]
    https://www.hitekproducts.com/blog/4-effective-uses-for-lacquer-thinner/
  44. [44]
    [PDF] PPG PAINTS LACQUER THINNER - SAFETY DATA SHEET
    The respiratory protection shall be in accordance to 29 CFR 1910.134. Section 9. Physical and chemical properties. Physical state. Melting point. Liquid. Not ...
  45. [45]
    [PDF] SAFETY DATA SHEET - Material Identity: #11 LACQUER THINNER
    Nov 12, 2015 · California Prop 65: This product contains Toluene and Methanol chemicals known by the State of California to cause cancer, birth defects or ...
  46. [46]
    [PDF] LACQUER THINNER - Axalta Coating Systems
    Physical and chemical properties. Physical state. Melting point. Liquid ... Safety Data Sheet (SDS) content is believed to be accurate as of its issue ...
  47. [47]
    Methemoglobinemia as a result of accidental lacquer thinner ... - NIH
    We report two cases of accidental ingestion of thinner. Case Reports. Case 1. A 26 year old male was admitted to the emergency with alleged history of ...Missing: study | Show results with:study
  48. [48]
    (PDF) Methemoglobinemia as a result of accidental lacquer thinner ...
    Aug 6, 2025 · We report two cases who presented to us with a history of accidental ingestion of paint thinner. Both the patients had very high levels of ...
  49. [49]
    [PDF] Lacquer Thinner
    Aug 26, 2023 · WARNING: This product contains chemicals known to the State of California to cause cancer and birth defects or other reproductive harm. FOR ...Missing: definition | Show results with:definition
  50. [50]
    TOLUENE - ACGIH
    Chemical structure: TLV–TWA, 20 ppm. OTO –Ototoxicant. A4 —Not Classifiable as a Human Carcinogen. To view TLV and Documentation, you must be logged in as an ...
  51. [51]
    NIOSH Pocket Guide to Chemical Hazards - Toluene - CDC
    Exposure Limits. NIOSH REL. TWA 100 ppm (375 mg/m3) ST 150 ppm (560 mg/m3). OSHA PEL. TWA 200 ppm C 300 ppm 500 ppm (10-minute maximum peak) See Appendix G.
  52. [52]
    HEALTH EFFECTS - Toxicological Profile for Toluene - NCBI - NIH
    Health effect (eg, death, systemic, immunological, neurological, reproductive, developmental, and carcinogenic effects).
  53. [53]
    Organic Solvent Neurotoxicity (87-104) | NIOSH - CDC
    For example, persons who abusively inhaled toluene almost daily for 1 to 7 years showed evidence of severe, multifocal CNS damage with cortical, cerebellar, and ...
  54. [54]
    Solvent neurotoxicity - PMC - PubMed Central - NIH
    Early studies in Scandinavia suggested that long term, high level, solvent exposure might be associated with a syndrome of personality change, memory impairment ...
  55. [55]
    PUBLIC HEALTH STATEMENT FOR TOLUENE - NCBI - NIH
    Some studies in people have shown reproductive effects, such as an increased risk of spontaneous abortions, from repeated, low to moderate levels of toluene in ...
  56. [56]
    [PDF] Toluene - U.S. Environmental Protection Agency
    Reproductive/Developmental Effects: CNS dysfunction, attention deficits, minor craniofacial and limb anomalies, and developmental delay were observed in the ...
  57. [57]
    HEALTH EFFECTS - Toxicological Profile for Acetone - NCBI - NIH
    Based on evidence from human and animal studies, acetone is associated with neurological effects ranging from mild neurobehavioral effects to severe narcosis.Missing: lacquer | Show results with:lacquer
  58. [58]
    [PDF] Toxicological Profile for Acetone
    squaric acid dibutyl in acetone developed acute contact dermatitis after handling the acetone-based product for 2 years (Tosti et al. 1988). Patch testing ...
  59. [59]
    Technical Overview of Volatile Organic Compounds | US EPA
    Sep 8, 2025 · While VOCs can also be a health concern outdoors, EPA regulates VOCs outdoors mainly because of their ability to create photochemical smog ...Missing: lacquer thinner
  60. [60]
    Rule 1113 Table of Standards - AQMD
    Grams of VOC Per Liter of Coating, Less Water and Less Exempt Compounds ; Varnish. 46, 47. 275 ; Sanding Sealers. 36. 275 ; Lacquer. 20. 275 ; Wood Conditioners. 65.
  61. [61]
    Volatile chemical products emerging as largest petrochemical ...
    Feb 16, 2018 · Oxidation of VOCs in the presence of nitrogen oxides (NOx = NO + NO2) also contributes to tropospheric ozone (O3), which increases risks of ...
  62. [62]
    [PDF] METHOD 24—DETERMINATION OF VOLATILE MATTER ...
    This method is applicable for the determination of volatile matter content, water content, density, volume solids, and weight solids of paint, varnish, lacquer, ...
  63. [63]
    Volatile Organic Compounds (VOCs) as Environmental Pollutants
    VOCs can be removed via efficient approaches involving nanomaterials, by using techniques such as adsorption, catalysis or photocatalysis.
  64. [64]
    [PDF] Incineration - EPA
    The proposed operating conditions for hazardous waste incineration include a combustion zone temperature of 2000EF (1100EC) and a residence time of 2 sec ...
  65. [65]
    Learn the Basics of Hazardous Waste | US EPA
    Mar 24, 2025 · Many hazardous wastes can be recycled safely and effectively, while other wastes will be treated and disposed of in landfills or incinerators.Missing: lacquer | Show results with:lacquer
  66. [66]
    https://www.epa.gov/sites/default/files/2020-12/documents/method_24.pdf
  67. [67]
    Revised Waste Framework Directive enters into force - Environment
    Oct 16, 2025 · The targeted revision of the Waste Framework Directive enters into force today (16 Oct), introducing common rules for extended producer ...