Difference between revisions of "Anhydrous sodium methylate"

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(Calculating how much to use)
(Calculating how much to use)
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A good starting point for the base figure is 5.0 although clearly the base figure is adjustable and can be tweaked to get as low as possible whilst maintaining good results.
 
A good starting point for the base figure is 5.0 although clearly the base figure is adjustable and can be tweaked to get as low as possible whilst maintaining good results.
  
As an example : assuming a batch size of 150 Litres, a [[titration]] of 2.0g/L (using 0.1% NaOH titration fluid) and using a base value of 5.0 g/L gives
+
As an example : assuming a batch size of 150 Litres, a [[titration]] of 2.0g/L (using 0.1% NaOH [[Titration#Reference_solution|titration reference solution]] fluid) and using a base value of 5.0 g/L gives
  
  
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Whilst it is perfectly possible to use a single stage reaction for making biodiesel, many brewers are now taking advantage of the benefits of the two stage no titration process with it's reduced chemical usage, reduced soap production and better yields.
+
Whilst it is perfectly possible to use a single stage reaction for making biodiesel, many brewers are now taking advantage of the benefits of the [[two stage process with no titration]] with it's reduced chemical usage, reduced soap production and better yields.
  
 
Methylate lends itself nicely to the [[two stage process with no titration]] and the base figure can often be reduced somewhat.
 
Methylate lends itself nicely to the [[two stage process with no titration]] and the base figure can often be reduced somewhat.

Revision as of 09:56, 24 January 2013

This page gives a guide to making Biodiesel from Anhydrous Sodium Methylate (ASM), a liquid catalyst which can be used in place of the more conventional Sodium Hydroxide or Potassium Hydroxide catalysts.


What is it and where do I get it from?

What is Anhydrous Sodium Methylate

It is a white powder in pure form but for practical use as a catalyst in diy biodiesel it is dissolved in pure methanol at 28% to 30% concentration. In this form it is a colourless, viscous fluid with a slighlty sweet alcohol smell - very similar to methanol which, after all, makes up a large proportion of the fluid volume. ASM is both highly flammable,corrosive and toxic through inhalation, skin contact and ingestion. It evaporates readily to leave a white powdery residue and at low temperatures it tends to precipitate out the white solid.

Availability

Compared to Sodium Hydroxide and Potassium Hydroxide which are readily available from a number of chemical suppliers around the UK, ASM is somewhat harder to source. One well known biodiesel chemical supplier does sell it in various pack sizes from 25litre HDE cans to 1000litre IBCs and new sources are starting to appear. Current prices are in the £1.50 to £2.20 per litre range


Making biodiesel with Anhydrous Sodium Methylate

Calculating how much to use

A lot of clever people have gone through a lot of complex calculations to work out the correct amount of ASM to use. However, a certain James Leach from the Vegetable Oil Diesel forum has simplified pages of complex organic chemistry down to a simple, single line equation


mL of Methylate = ((Base Amount + Titration Value) X Batch Volume in Litres) X 5


This is based upon the use of a 0.1% Sodium Hydroxide titration reference solution (ie the normal 1g of Sodium Hydroxide in 1 litre of de-ionised water that most of us use and also known as Lye Water).

A good starting point for the base figure is 5.0 although clearly the base figure is adjustable and can be tweaked to get as low as possible whilst maintaining good results.

As an example : assuming a batch size of 150 Litres, a titration of 2.0g/L (using 0.1% NaOH titration reference solution fluid) and using a base value of 5.0 g/L gives


((5.0 + 2.0) X 150) X 5 = 5250mL of Methylate


Whilst it is perfectly possible to use a single stage reaction for making biodiesel, many brewers are now taking advantage of the benefits of the two stage process with no titration with it's reduced chemical usage, reduced soap production and better yields.

Methylate lends itself nicely to the two stage process with no titration and the base figure can often be reduced somewhat.

For the first stage of the process, the formula is


mL of Methylate = (Base Figure X Batch Volume) X 5


A conversion test, be that 3/27, 5/45 or 10/90 is then done to identify the remaining unconverted litres in the batch

The second stage formula is then


mL of Methylate = (Base Figure X Unconverted Litres) X 5


Several brewers, including myself, have achieved very good results using a base figure of 4.0 for both stages.

As a worked example, using the same 150 litre batch as the single stage example, a base figure of 4.0 and an assumed fallout of 2.0mL in a 10/90 test gives


First stage : mL of Methylate = (150 X 4.0) X 5 = 3000mL


The 2.0mL of fallout in the 10/90 suggests that 20% of the 150 Litre batch or 30 Litres remain unconverted


Second stage : mL of Methylate = (30 X 4.0) X 5 = 600mL


This demonstrates the significant saving in chemicals of the two stage process, giving 3600mL for the two stage instead of 5250mL for the single stage, a 31% saving and is based on real world results I have seen in my own processor.

Mixing

The ease of mixing is without doubt the best feature of mixing Sodium Methylate. Using conventional solid catalysts is a labour intensive process. Whilst Potassium Hydroxide flakes dissolve relatively easily in methanol, Sodium Hydroxide micro pearl is more trouble and full sized Sodium Hydroxide pearl requires significant effort.

Mixing Sodium Methylate and Methanol is an instantaneous process, comparable to mixing fruit cordial with water since both are liquids.


Reducing the Methanol volume

The second advantage of using Methylate is that around 70% of the fluid is actually methanol. This means that less methanol needs to be added to the batch. Conventional wisdom has been around 20% methanol using solid catalysts whereas using Sodium Methylate this can be reduced signficantly.

In my own processor, using the two stage no titration process, I have seen perfect 10/90 tests using just 12% methanol in each stage.

A real world example

Let's assume a batch size of 150 litres, a two stage process with no titration, a base figure of 4.0 and a dropout on the 10/90 conversion test at the end of the first stage of 2.0ml

For the first stage: Methanol volume = 12% X 150litres = 18 litres, Methylate volume = (150 X 4.0) X 5 = 3000ml

For the second stage, which has 30 uncoverted litres: Methanol volume = 12% X 30litres = 3.6 litres, Methylate volume = (30 X 4.0) X 5 = 600ml

Giving a total of 21.6 litres of methanol and 3.6 litres of Methylate

The pros and cons of using Sodium Methylate

Pros

  • Mixing it with methanol is as easy as making orange squash
  • Being a liquid, there is no corrosive dust to worry about
  • Being around 70% methanol, using methylate requires less methanol in the batch

Cons

  • Methylate is considerably more expensive than solid catalysts although this can be offset against methanol savings
  • Availability is still an issue although this is improving


Julesandtash 21:11, 15 September 2012 (BST)