Manufacturing of Chloromethane

   Manufacturing of Chloromethane (CH₃Cl)

Contents:

1. Properties

2. Manufacturing Process

3. Reactions Involved in Production of CH₃Cl

4. Flow Diagram

5. Production Process

6. Applications

 

Properties:

 

Chemical Name	Chloromethane, Methyl Chloride, Monochloromethane, R-40.
Chemical Formula	CH3Cl
Molar Mass	50.49 g/mol
Appearance	Colourless gas
Odor	Faint, Sweet odor
Density	1.003 g/L
Melting Point	-97.4 oC
Boiling Point	-23.8 oC
Solubility in Water	5.325 g/L

 

 

Manufacturing Process :

Chloromethanes are produced from methane by chlorination route.

Chloromethanes namely methyl chloride (CH₃Cl), methyl dichloride (CH₂Cl₂), Chloroform (CHCl₃) and carbon tetra-chloride (CCl₄) are produced by direct chlorination of CH₄ in a gas phase reaction without any catalyst.

 

Reactions :

CH₄ + Cl_{2           }          CH₃Cl + HCl

CH₃Cl + Cl_{2           }         CH₂Cl₂ + HCl

CH₂Cl₂ + Cl_{2           }         CHCl₃ + HCl

CHCl₃ + Cl_{2           }         CCl₄ + HCl

The reactions are very exothermic. The feed molar ratio affects the product distribution. When CH₄/Cl₂ is about 1.8, then more CH₃Cl is produced. On the other hand, when CH₄ is chosen as a limiting reactant, more of CCl₄ is produced. Therefore, depending upon the product demand, the feed ratio is adjusted.

 

Production Process :

 

 

Methane and Cl₂ are mixed and sent to a furnace.

The furnace has a jacket or shell and tube system to accommodate feed pre-heating to desired furnace inlet temperature (about 380-300^oC). To control temperature, N₂ is used a diluent. Depending on the product distribution desired, the CH₄/Cl₂ ratio is chosen.

The product gases enter an integrated heat exchanger that receives separated CH₄ (or a mixture of CH₄ and N₂) and gets cooled from the furnace exit temperature (400 ^oC).

Eventually, the mixture enters an absorber where water is used ass an absorber and water absorb the HCl to produce 32% HCl. The trace amounts of HCl in the vapour phase are removed in a neutralizer fed with NaOH.

The gas eventually is compressed and sent to a partial condenser followed with a phase separator. The phase separator produces two streams namely a liquid stream consisting of the chlorides and the unreacted CH₄ and N₂.

The gaseous product enters a dryer to remove H2O from the vapour stream using 98%

H₂SO₄ as the absorbent for water from vapour.

The chloromethanes enter a distillation sequence. The distillation sequence consist of columns that sequentially separate CH₃Cl, CH₂Cl₂, CHCl₃ and CCl₄.

 

Applications:

The most important use of chloromethane today is as a chemical intermediate in the production of silicon polymers.

Smaller quantities are used as a solvent in the manufacturing of butyl rubber and in petrochemical industry.

Chloromethane is also employed as a methylating and chlorinating agent in organic chemisty.