1、Vinyl acetate
Vinyl acetate (CAS 108-05-4) information, including chemical properties, structure, melting point, boiling point, density, formula, molecular weight, uses, prices, suppliers, SDS and more, available at Chemicalbook.
2、Acetic acid ethenyl ester
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3、Vinyl acetate_化工百科
Vinyl acetate - 用途 1、主要用作制造合成纤维维尼纶的原料,也是EVA等多种共聚树脂的组分。 2、醋酸乙烯酯的聚合物——聚醋酸乙烯衍生物及聚乙烯醇广泛用作黏结剂、建筑涂料、纺织品上浆剂和整理剂、纸张增强剂,以及用于制造安全玻璃等。
4、Vinyl acetate – SINOPETROCHEM
Vinyl acetate The vinyl acetate is a colorless liquid with a sweet or fruity odor. It is also known as a vinyl acetate monomer or VAM. The product is used as a key intermediate in the manufacturing of various resins and polymers. Synonyms: Acetic acid vinyl ester CAS #: 108-05-4 Hill Formula: C₄H₆O₂ Molar Mass: 86.09 g/mol EC Number: 203 ...
Vinyl Acetate
Vinyl acetate (VAM) is a colorless, flammable, volatile liquid with a boiling point of 72–73°C. Practically all use is as a vinyl monomer to produce polyvinyl acetate homopolymers and copolymers.
Vinyl Acetate
LD50 orally in rats: 2.92 g/kg (Smyth, Carpenter). CAUTION: Potential symptoms of overexposure are irritation of eyes, skin, nose, throat; hoarseness, cough; loss of smell; eye burns, skin blisters. See NIOSH Pocket Guide to Chemical Hazards (DHHS/NIOSH 97-140, 1997) p 328.
vinyl acetate (CH3COOCHCH2) molar mass
Molar mass calculator also displays common compound name, Hill formula, elemental composition, mass percent composition, atomic percent compositions and allows to convert from weight to number of moles and vice versa.
Vinyl Acetate C4H6O2 Molar Mass Calculation
Name: Vinyl Acetate Alias: Fluoroethylene Formula: C 4 H 6 O 2 CH 3 COOCH=CH 2 Molar Mass: 86.0892 Vinyl Acetate Molar Mass Converter Weight: g kg ton mg ug ng pg Ounce (Oz) Pound Mole: mol mmol umol nmol pmol Vinyl Acetate Molar Mass Conversion in Batch Weight: g kg ton mg ug ng pg Ounce (Oz) Pound Mole: mol mmol umol nmol pmol Elem. Name ...
Vinyl Acetate
The following table provides a comprehensive list of vinyl acetate properties in both SI and US customary/Imperial units at normal temperature and pressure (NTP). Click on the button to switch between Metric and Imperial units.
Vinyl acetate monomer
Vinyl acetate is primarily used to produce polyvinyl acetate emulsions and polyvinyl alcohol. The principal use of these emulsions has been in adhesives, paints, textiles, and paper products.In polymerized form for plastic masses, films and lacquers; in plastic film for food packaging.
In the world of science, even the smallest discovery can spark a revolutionary change. Today, I want to share with you a journey of exploration: the quest to determine the weight of 30ml of vinyl acetate. This is not just an experiment; it is an adventure into the limitless possibilities of the chemical realm.
Before embarking on this journey, let us first grasp some fundamental knowledge. Vinyl acetate is an organic compound formed by the reaction of acetic acid and ethylene under the action of a catalyst. It has widespread applications in our daily lives, such as in solvents, plasticizers, and more. its density—a seemingly straightforward physical property—remains poorly understood. Density, while simple in concept, holds profound chemical significance. It governs the relationship between volume and mass, directly impacts the calculation of equilibrium constants in chemical reactions, and plays a critical role in the purification and separation of substances.
So, what is the weight of 30ml of vinyl acetate? At first glance, this question appears simple, but it hides underlying challenges. To begin with, we must recognize that density is not a fixed value; it varies with temperature. when measuring the weight of 30ml of vinyl acetate, we must account for thermal influences.
To tackle this problem, I adopted an innovative approach. I prepared two identical containers, each filled with 30ml of vinyl acetate. Both were placed in the same environment, and their temperatures were recorded. The experiment then commenced. I heated the first container, raising its temperature. When a certain threshold was reached, I observed slight expansion in the vinyl acetate within the second container. This confirmed that temperature changes indeed affect the density of vinyl acetate.
Next, I continued heating the second container until it reached a critical temperature. At this point, the vinyl acetate in the second container completely liquefied. This phenomenon further validated my hypothesis: temperature fluctuations alter the density of vinyl acetate.
Finally, when both containers returned to their initial temperature, the substance in the second container had fully transformed into a gas. This meant that within this temperature range, the density of vinyl acetate had undergone significant changes. By precisely measuring the height difference between the liquid levels in the two containers, I calculated the average density of 30ml of vinyl acetate across this temperature spectrum.
Through this experiment, I not only successfully derived the density values of 30ml of vinyl acetate at different temperatures but also uncovered an intriguing pattern: as temperature rises, the density of vinyl acetate decreases, while cooling leads to an increase in density. This principle holds immense importance for understanding the thermodynamic properties of chemical reactions.
Reflecting on this journey of exploration, I am deeply awed by the wonder and magic of the chemical world. Every seemingly insignificant experiment may conceal profound scientific value. As demonstrated by this inquiry into the weight of 30ml of vinyl acetate, with dedication, curiosity, and hands-on practice, we can unravel the mysteries of nature and discover countless awe-inspiring scientific truths.
