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What is cyclohexylamine used for?
Cyclohexylamine is a transparent, colorless
liquid with a strong fishy and ammonia smell. Flammable, relative molecular
mass is 99.18, relative density is 0.8191, melting point is -17.7℃, boiling
point is 134.5℃, 118.9℃(6.67×104Pa), 102.5℃(4.00×104Pa),
72.0℃(1.33×104Pa), 56.0℃(6.67×103Pa), 45.1℃(
4.00×103Pa), 41.3°C (3.333×103Pa), 36.4°C (2.67×103Pa), 303.5°C (6.5°C), 303.5°C (103Pa), 3.99°C (103.5°C), 2.5°C),
2.95°C (1035°C), 2.35°C (15 ℃), 2.35℃(1.3.3.5℃), 2.3.3.5℃), 2.5℃.
It is soluble in water and can
be mixed and dissolved with ethanol, ether, acetone, ethyl acetate, chloroform,
heptane, benzene, and other common organic solvents. Cyclohexylamine can
evaporate with steam and absorb carbon dioxide in the air to form white
crystalline carbonate.
It can form an azeotropic
substance with water, and the azeotropic point is 96.4℃, the water
content is 55.8%, its aqueous solution is alkaline. pH value of 0.01% aqueous
solution is 10.5.
Its steam can form an explosive
mixture with air. The product is toxic, irritating to the skin and mucous
membranes. Inhalation of the vapor that may cause undesirable maggots has an
anesthetic effect but does not cause blood poisoning. Oral dose for
rats:LD50:710 mg/kg. The maximum allowable concentration in the workplace is 10×10-6.
Heating cyclohexylamine and
hydrogen iodide together in a sealed tube at 200°C produces methyl
cyclopentane. Cyclohexylamine and dimethyl sulfate can be heated together in
ether to produce methane and also a small amount of dimethyl cyclohexylamine. Its
hydrochloride can be reacted with sodium nitrite salt to form cyclohexanol. The
reaction of excess ammonia and zinc chloride produces 2-methylpyridine.
Preparation: Finished
cyclohexylamine can be made by catalytic reduction of aniline at high temperature
and pressure (with nickel or cobalt as a catalyst) to produce cyclohexanol
cyclohexanone from the catalytic reduction of phenol as raw material or by
amination with ammonia. In industry, cyclohexylamine is mainly used as an azole
vulcanization accelerator for rubber and a tank detergent, dyeing auxiliary,
and surfactant.
Dai Xiongfeng Chemistry Book
edits the above information.
Cyclohexylamine can be used as
raw material for surfactants, production of alkylbenzene sulfonate, used as an
emulsifier and foaming agent.
It can be used as a raw
material for the production of perfume, producing allyl cyclohexyl propionate.
It can be used as raw materials
for dye production, such as acid blue 62, disperse fluorescent yellow,
fluorescent yellow dispersion H5GL, weak acid blue BRN, disperse blue 6, and
dye additives.
As a raw material for food
additive sweeteners, cyclohexylamine can also produce cyclohexylamine sulfonate
and sodium cyclamate, the latter sweetener being 30 times sweeter than sucrose.
The Ministry of Health of China has approved the application in sauces,
dressings, prepared wines, cakes, cookies, bread, frozen drinks, and beverages
at a maximum allowable amount of 0.65g/kg.
It can be used to produce
insecticide "Propargite," herbicide "Wilbur," fungicide,
and other pesticide materials for fruit trees.
It can prepare additives for
petroleum products, boiler feed water treatment agents, rust removers, etc.
As a raw material for rubber
CZazole vulcanization accelerator production, this vulcanization accelerator
has a good effect and is especially suitable for SBR and FDA rubber.
It can be used as an antirust
agent for the production of antirust paper.
It can be used as a tank
cleaning agent.
It can be used as an antifreeze
agent. It can be used as a tank cleaner for the production of antirust paper.
It can be used as an antistatic
agent (textile auxiliary), latex coagulant, and additive of petroleum products.
Due to the alkaline nature of
cyclohexylamine aqueous solution, it can be used as an absorbent to remove
carbon dioxide and sulfur dioxide.
Chemical properties.
This product is a colorless
liquid with odor. The product is mixed and dissolved with various organic
solvents.
Uses.
It can be used as a
vulcanization accelerator of rubber, as the raw material of synthetic fiber,
dyestuff, vapor phase corrosion inhibitor. It can be used to make dyestuff,
softener VS, and drugs, such as Antiradon, Thio-TEPA, solaziquone, etc. It can
also be used in medicine and pesticide.
It can be used to manufacture
dyes, softener VS, Antiradon, Thio-TEPA, solaziquone, and other drugs of
medicine and pesticide.
Cyclohexylamine is the intermediate of
herbicide "hexazinone" and the intermediate of rubber accelerator,
oil additive, and corrosion inhibitor.
It can be used to produce
cyclohexanol, cyclohexanone and caprolactam, cellulose acetate, and nylon 6.
Cyclohexylamine itself is a solvent and can be used in resin, paint, grease,
and paraffin oil. It can also be used to manufacture desulfurization agents, rubber
antioxidants, vulcanization accelerators, plastic and textile chemical
auxiliaries, boiler feedwater treatment agents, and metal corrosion inhibitors
emulsifiers, preservatives, antistatic agents, latex coagulants, oil additives,
fungicides, pesticides, and dye intermediates. Cyclohexylamine sulfonate can be
used as an artificial sweetener in food, beverage, and medicine.
It can be used in organic
synthesis, plastic synthesis, and preservative and acid gas absorber.
It can be used as an
intermediate in producing water treatment chemicals, artificial sweeteners,
rubber processing chemicals, and agrochemicals, and as an acid gas absorber for
organic synthesis.
It can be used as an acid gas
absorbent for organic synthesis.
Production method.
It is derived from the
catalytic hydrogenation of aniline. The process can be divided into the
atmospheric pressure method and reduced pressure method. Other methods such as
catalytic ammonolysis of cyclohexane or cyclohexanol, recovery of
nitrocyclohexane, and catalytic ammonolysis of cyclohexanone can also be used
to produce cyclohexylamine.
It is made by catalytic
hydrogenation of aniline as raw material. Mixing aniline vapor and hydrogen,
pouring into the catalytic reactor under the action of cobalt catalyst, the
hydrogenation reaction is carried out at 130~170℃, and the product obtained after
cooling is further distilled.
Flammable liquid.
Toxicity classification.
Highly toxic.
Acute toxicity.
Oral-rat LD50:156 mg/kg
Oral-rat LD50:224 mg/kg.
Irritation data.
Skin-Rabbit 2mg/24h, mild;
Eyes-Rabbit 0.05mg/24h, severe.
Hazardous properties of
explosive material.
The explosion will occur when
mixed with air.
Flammability and hazard.
Flammable in the presence of
fire, heat, and oxidizing agents produce toxic nitrogen oxide fumes on
combustion.
Storage properties.
Storage: Store separately from
ventilated, low temperature, dry oxidizers, and acids.
Fire extinguishing agent.
Dry powder, dry sand, carbon
dioxide, foam, 1211 fire extinguishing agent.
Professional standard.
TWA40mg/m3.
Chemical properties.
Cleaning fluid.
Chemical properties.
Cyclohexylamine is a liquid
from colorless to yellow (amine, primary aromatic). Has an unpleasant fishy
odor.
Chemical properties.
Cyclohexylamine is a derivative
of ammonia with hydrogen atoms replacing the six-carbon saturated ring. It is a
strong base and forms salts with all acids, including carbon dioxide, which is
rapidly absorbed from the air. It reacts with carbon disulfide to produce the
usual reaction of aliphatic amines to form carbamate disulfide. Cyclohexylamine
reacts with long-chain fatty acids to form soap. Reaction with nitric acid
releases nitrogen to form cyclohexanol (Schweizer 1978). Cyclohexylamine reacts
with organic compounds containing reactive halogen atoms, acid anhydrides, and
alkyl oxides, replacing one or two hydrogens on the nitrogen atom.
Cyclohexylamine can attack all
copper alloys and lead. When hot, aluminum attacks very slowly (Carswell et
al., 1937).
Uses.
In organic synthesis,
plasticizers, corrosion inhibitors, rubber chemicals, dyes, emulsifiers,
dry-cleaning soaps, and acid gas absorbers make insecticides.
Uses.
Cyclohexylamine is used to
manufacture a variety of products, including plasticizers, dry-cleaning soaps,
insecticides, and emulsifiers. Cyclohexylamine is also used as a corrosion
inhibitor and in organic synthesis.
Uses.
Used in the manufacture of
plasticizers, dry cleaning soap, insecticides, emulsifiers, and many other
products.
Production of rubber processing
chemicals boiler water supply in the production of corrosion inhibitors
production of insecticides, plasticizers, dry cleaning soap sweetener cyclamate
metabolites.
Definition.
ChEBI. Primary aliphatic amine
consisting of cyclic self alkane with amino substitution.
Production method.
Cyclohexylamine is the reaction
of ammonia and cyclohexanol at high temperature and pressure in the presence of
a silica-alumina catalyst (SRI, 1985). Cyclohexylamine can also be prepared by
a similar process of catalytic hydrogenation of aniline at high temperature and
pressure. The reaction products are fractionated to give CHA, aniline, and a
high boiling point residue containing ortho-phenylcyclohexylamine and
dicyclohexylamine.In 1982, U.S. production was 4.54 metric tons, and U.S.
imports were 739.3 metric tons (SRI, 1985).
General Description.
Colorless to yellow transparent
liquid with an ammonia odor. Flashpoint is 90° F. Irritating to eyes and
respiratory system. May burn on skin contact. Density is less than water. Vapor
is heavier than air. Produces toxic nitrogen oxides on combustion.
The reaction of air and water.
Highly flammable. Sensitive to
air and light. Easily soluble in water.
Reactivity Introduction.
Cyclohexylamine is neutralized
with acid in an exothermic reaction to form a salt plus water. Isocyanates,
halogenated organics, peroxides, phenols (acidic), epoxides, acid anhydrides,
and acid halides may be incompatible. Combination with strong reducing agents
(hydrides, etc.) may produce flammable gaseous hydrogen.
Health hazard.
The substance is classified as
a highly toxic-70 kg (150 lb) person who may die orally at doses of 50-500
mg/kg or 1 teaspoon to 1 oz. It is considered to be neurotoxic. It is a weak
substance that forms methemoglobin.
Health hazard.
Severe irritation and mild
sensitization have been reported in humans exposed to a 25% aqueous cyclohexylamine
solution in skin paste tests (Malette and vonHaam, 1952). Exposure to high
concentrations of cyclohexylamine may cause nausea and anesthesia (Windholz et
al., 1983). Three cases of transient systemic toxic effects caused by acute
accidental industrial exposure have been reported. Victims reported dizziness,
drowsiness, anxiety, worry, and nausea. Some had unclear speech, vomiting, and
dilated pupils. However, workers exposed from 4 to 10 p.m. did not experience
adverse effects.
Oral administration of
cycloheximide (5 and 10 mg/kg) to adult males resulted in headaches, blurred
vision, and tremors in the subjects.
Dependent increases in arterial
blood pressure were observed in humans with oral administration of
cycloheximide (2.5, 5.0, 10 mg/kg) (Eichelbaum et al., 1974). Researchers
calculated that plasma levels of cycloheximide must reach 0.7-0.8 μg/ml to
cause a significant increase in blood pressure. Only the highest dose (11
mg/ml) significantly increased the cumulative excretion of plasma free fatty
acids and catecholamines. These data suggest that cycloheximide is an
indirectly acting sympathomimetic substance that, despite its relatively low
potency, correlates well with animal studies' results (Classen and
Marquardt1969; Rosenblum and Rosenblum1968a, 1968b; Wechsler et al. 1969;
Yamamura et al. 1968 ).
Health hazards.
Cyclohexylamine is a severe
irritant to the eyes, skin, and respiratory tract. Skin contact can cause burns
and sensitization Pure or concentrated liquids can cause blindness in contact
with the eyes.
In test substrates,
cyclohexylamine has moderate acute oral and dermal toxicity. Toxic effects include
nausea, vomiting, and degenerative changes in the brain, liver, and kidneys.
Inhalation of high concentrations of cyclohexylamine vapor causes narcotic
effects.
LD50 value, oral (rat):156
mg/kg.
LD50 value, dermal (rabbit):277
mg/g.
Cyclohexylamine may be
mutagenic, and tests in this area have been inconclusive so far. Administration
of this compound to animals affects the reproductive system, including
embryotoxicity and decreased male fertility. Roberts and coworkers (1989)
studied the metabolism and testicular toxicity of cyclohexylamine in rats and
mice. After 13 weeks of chronic dietary administration at 400 mg/kg/day, Wistar
and dark agoutiDA rats showed decreased organ weights, histological changes,
and testicular atrophy. Still, the degree varied greatly, and the rats showed
no evidence of testicular damage.
There is no evidence that
cycloheximide is carcinogenic to animals or humans.
Fire is dangerous.
When heated to decomposition,
cyclohexylamine releases highly toxic fumes. Vapors may travel considerable
distances to reach the ignition source and flash. Combustion produces toxic
nitrogen oxides. Nitric acid; reacts violently with oxidizing substances. Good
stability, avoid physical damage, store with oxidizing substances.
Industrial use.
The primary use of
cyclohexylamine is as a corrosion inhibitor in boiler water treatment and
oilfield applications (HSDB, 1989). It is also a chemical intermediate for
rubber processing chemicals, dyes (Acid Blue 62, previous use), carbamate
artificial sweeteners and herbicides, and a process agent for nylon fiber
production (SRI, 1985). According to Windholz et al. (1983), used in the
manufacture of insecticides, plasticizers, emulsifiers, dry cleaning soaps, and
acid gas absorbers.
Safety profile.
Toxic by ingestion, dermal
contact, and intraperitoneal channels. Experimental deformities and
reproductive effects. Severe irritation to human skin. Can cause dermatitis and
cramps. Human mutation data have been reported. Suspected carcinogen. Flammable
liquid. Fire hazard when exposed to heat, flame, or oxidizing agents. Use
alcohol foam, carbon dioxide, and dry chemicals when extinguishing fires. When
heated to decomposition, releases fumes of toxic nitrogen oxides.
Potential Exposure.
CHA is used in the manufacture
of dyes, chemical reagents, insecticides for dry cleaning chemicals,
plasticizers, rubbers, and as a chemical intermediate for cyclic glycine
sweetener production. It is used in water treatment and boiler water supply
additives. Also used in rubber production to retard degradation.
Carcinogenicity.
According to the International
Agency for Research on Cancer (IARC) Task Force report, there is no evidence
that cyclohexylamine is teratogenic or carcinogenic.
Price et al. reported the
development of bladder tumors in Charles River rats fed cyclohexylamine sulfate
for 2 years at doses of 0, 0.15, 1.5, and 15 mg/kg/day per group, with 25 males
and 25 females per group. In the first year, only slight control of body weight
gain was observed in males of the high-dose group, and no other signs of
toxicity were observed. At the end of 2 years (104 weeks), 13-16 animals
remained alive in the 0.15- and 1.5-mg/kg groups, and 8 males and 9 females in
the 15-mg/kg group. Invasive transitional cell carcinoma of the bladder was
observed in one of the eight male survivors in the high-dose group. The authors
noted that spontaneous bladder tumors were sporadic in the rat line used. No
other relevant findings were noted. Gaunt conducted a 2-year dietary feeding
study with the same doses in Wistar rats. They observed no evidence of
carcinogenesis, slight anemia, inability to produce normally concentrated
urine, and an increased number of animals with foamy macrophages in the alveoli
at the highest dose level. Food intake was reduced, body weight was increased,
and organ weights were reduced compared to controls. Animals ingesting 2000 or
6000 ppm had testicular atrophy or less tubular spermatozoa. In both studies,
the level without side effects was 600 ppm, which corresponds to an intake of
about 30 mg/kg per day.
Metabolism.
Cyclopamine is metabolized to
cyclohexylamine by rat intestinal flora (Renwick and Williams, 1969 Bickel et
al., 1974 Tesoriero and Roxon, 1975) and is excreted in the urine after
ingestion by rats, rabbits, dogs, monkeys, and humans (Asahina et al., 1971
Coulston et al. 1977 Kojima and Ichibagase, 1968 Leahy et al. 1967 Individual
differences exist in the ability to biotransform cyclamic acid to
cyclohexylamine, possibly due to the presence or absence of the necessary
bacteria. Bacteria exposed to cyclamate appear to have acquired the ability to
convert cyclamate. Individuals that did produce cycloheximide were classified
as converters by the researchers. Rhesus monkeys kept for 8 years converted
0.5% of their dose to cyclohexylamine, which metabolizes cyclohexanone and
cyclohexanol at a 1-2% (Coulston et al. 1977).
In general, cyclohexylamine is
readily absorbed and rapidly excreted from the body. After feeding to rats,
cyclohexylamine appeared in body tissues with the highest concentrations in the
lungs, spleen, liver, adrenals, heart, stomach, intestines, and kidneys
(reported by Estep and Wiegand, 1967, Bopp et al. 1986).
Following oral administration
(0.2 g/kg) to rabbits, cyclohexylamine produced unchanged cyclohexylamine and
7V-hydroxycyclohexylamine in the urine (Elliott et al. 1968). When
[14C]-labeled cyclohexylamine was administered, 68% of the radioactivity was
recovered in the urine after 60 hours, a small amount (0.5%) was eliminated in
the breath, and 45% of the administered amount was excreted in the urine as
unbound cyclohexylamine, 0.2% as bound JV-hydroxycyclohexylamine, and 2.5% as
cyclohexanone oxime. The authors speculate that the post-metabolites are
unrealistically imagined to be formed during hydrolysis of
TV-hydroxycyclohexylamine glucuronide.
In contrast to rabbits, more
than 90% of the [14C] dose-labeled cyclohexylamine excreted by humans and rats
and guinea pigs- was unchanged in the urine. Small amounts of radioactivity
were found in the feces, more than 1% in humans, rats and rabbits, and 4-7% in
guinea pigs. Rats and guinea pigs metabolized only 4-5% of the dose in 24
hours, and humans metabolized 1-2% of the dose. Explicit metabolites suggest
that cyclohexylamine is metabolized primarily by cyclohexane cyclohydroxylation
in rats, by deamination in humans, and by cyclohydroxylation and deamination in
guinea pigs and rabbits. The metabolites of cyclohexylamine are excreted in
both free and conjugated forms.
When cyclohexylamine was administered
orally to healthy adults at 2.5, 5, and 10 mg/kg, 86-95% of the weight was
excreted in the urine as unchanged cyclohexylamine within 48 hours (Eichelbaum
et al., 1974). studies by Roberts and Renwick (1985) showed that
cyclohexylamine's metabolism differs in other species and varieties, with dose
dependence at a plasma half-life of 3.5 to 4.8 hours. After administering
[14C]-cyclohexylamine (35-500 mg/kg) to male rats and mice, 80% of the urine
was excreted 24 hours after dosing. In Wistar rats, 14-19% of 14C was present
in 3- and 4-aminocyclohexanols, and in rats of the DA strain,
aminocyclohexanols accounted for only 1-2% of activity, with <1% in rats.
There was no significant effect on metabolism by the amount or channel of
administration.
When [14C]-cyclohexylamine
hydrochloride was infused into pregnant rhesus monkeys via the antecubital
vein, maternal and fetal radioactivity levels were essentially identical over 6
hours (Pitkin et al. 1969), indicating that cyclohexylamine can freely pass through
the bloodstream placenta.
Cyclohexylamine can be
deaminated to cyclohexanone in the presence of NADPH and molecular oxygen in
rabbit liver microsomes (Kurebayashi et al. 1979). Cyclohexanone is then
reduced to an alcohol (~75% of the deamination product). Carbon monoxide, SKF
525A, methyl ethyl ketone, potassium cyanide, and mercuric chloride controlled
the deamination. These results suggest that the microsomal pigment P-450
monooxygenase system catalyzes deamination.
Transport.
UN2357 Cyclohexylamine, Hazard
Class. 8; Label:8-Corrosive substance, 3-Flammable liquid. 8-Corrosive
substance, 3-Flammable liquid.
Purification Method.
Dry amine with CaCl2 or LiAlH4,
then distill with BaO, KOH or Na under N2. It can also be converted to
hydrochloride (crystallized from water several times) and then purified by
releasing the amine with alkali and fractional distillation under N2. The m of
the hydrochloride is 205-207o (dioxane/EtOH). Lycan et al.
OrgSynthCollVolII3191943, Beilstein 12II10, 12IV8.
Incompatibility.
May form explosive mixtures with
air. Cyclohexylamine is a strong base: Reacts strongly with acids. Contact with
strong oxidizing agents may lead to fire and explosion. Incompatible with
organic anhydrides, isocyanates, ethyl acetate, acrylates, substituted
propylene, alkyl oxides, epichlorohydrin, ketones, aldehydes, alcohols,
glycols, phenols, cresols, self-caprolactam solutions, lead, etc. Corrosive to
copper alloys, zinc or galvanized steel.
Waste disposal.
Incineration; incinerators
equipped with scrubbers or heat units to reduce NOx emissions.
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