Difference between revisions of "Testing methanol purity"
Line 1: | Line 1: | ||
+ | |||
+ | {{WIP}} | ||
+ | |||
+ | |||
==Specific gravity== | ==Specific gravity== | ||
Pure methanol has an SG (specific gravity) of 0.7913 (0.79 for our purposes) at 20°C. For those unfamiliar with specific gravity, it’s a comparison of the density (mass per volume at a specific temperature and pressure) of a substance with the density of pure water. Water has a specific gravity of 1. So from the figures above it’s obvious that methanol is less dense that water. | Pure methanol has an SG (specific gravity) of 0.7913 (0.79 for our purposes) at 20°C. For those unfamiliar with specific gravity, it’s a comparison of the density (mass per volume at a specific temperature and pressure) of a substance with the density of pure water. Water has a specific gravity of 1. So from the figures above it’s obvious that methanol is less dense that water. |
Revision as of 19:08, 11 March 2013
This page is Work In Progress and therefore may not be complete. |
Specific gravity
Pure methanol has an SG (specific gravity) of 0.7913 (0.79 for our purposes) at 20°C. For those unfamiliar with specific gravity, it’s a comparison of the density (mass per volume at a specific temperature and pressure) of a substance with the density of pure water. Water has a specific gravity of 1. So from the figures above it’s obvious that methanol is less dense that water. If methanol and water were not miscible (able to mix in all proportions, i.e. one is soluble in the other) and we poured some methanol into a beaker of water, it would float as a layer at the top. However, water and methanol are miscible and therefore cause us some problems in the production of biodiesel, water promoting the formation of soap during the process.
Why test purity
For best results the methanol used in biodiesel production needs to be a minimum of 97% pure. It’s good practise to test the purity of a new batch of methanol firstly to ensure you are getting what you paid for, not substandard product from an unscrupulous supplier and secondly to ensure that it’s not going to cause problems during production. As methanol is hydroscopic (able to absorb moisture from the atmosphere) is may be of benefit to test old stock or methanol that has been open to the atmosphere for any length of time. Perhaps the most beneficial use of SG tests is on methanol recovered from biodiesel to see if it’s suitable for use in the next batch.
Testing SG with a hydrometer
Many people may be familiar with a hydrometer, they are frequently used to test battery acid, for testing concentrations of anti-freeze in car engines and to check the salinity of salt water aquariums. More accurate versions, covering a limited range of SG are available for laboratory use and can be found at reasonable prices on internet auction sites. When purchasing this type of hydrometer, be sure that it covers a range suitable for testing methanol. Typically a laboratory hydrometer of this type will have a range between 0.750 - .850 with 0.0005 divisions. Also suitable, but not quite so accurate, is a Trellis hydrometer used in home brewing. These often read in % alcohol, proof or ABV (alcohol by volume). They will be based on ethanol which comprises the bulk of alcohol found in common beverages. Ethanol has an SG of 0.789, so very close to methanol, not as accurate as a laboratory version, but good enough for our needs if economy is an overriding factor. In addition to the hydrometer, you will need what’s known as a trial jar or hydrometer cylinder. This is simply a tall, preferably transparent jar in which the hydrometer will float without touching the sides or bottom. A measuring cylinder is ideal, but these can be quite expensive in larger sizes. A cheaper alternative can be made from odds and ends, see Hydrometer trial jar. If you are using a transparent trial jar, fill it with sufficient methanol to allow the hydrometer to float well clear of the bottom. Give it a gentle spin to remove any air bubbles and allow it to settle. The SG can be read from the scale
The following table is reproduced with kind permission of Graham Lambing:
Assuming water is the pollutant, this table gives you the relationship between density and purity ....
Methyl Alcohol (CH3OH) Density kg/litre
% | 0 DegC | 10 DegC | 15 Deg C | 20 DegC |
75 | 0.8754 | 0.8676 | 0.8629 | 0.8592 |
76 | 0.8729 | 0.8651 | 0.8604 | 0.8567 |
77 | 0.8705 | 0.8626 | 0.8579 | 0.8542 |
78 | 0.868 | 0.8602 | 0.8554 | 0.8518 |
79 | 0.8657 | 0.8577 | 0.8529 | 0.8494 |
80 | 0.8634 | 0.8551 | 0.8503 | 0.8469 |
81 | 0.861 | 0.8527 | 0.8478 | 0.8446 |
82 | 0.8585 | 0.8501 | 0.8452 | 0.842 |
83 | 0.856 | 0.8475 | 0.8426 | 0.8394 |
84 | 0.8535 | 0.8449 | 0.84 | 0.8366 |
85 | 0.851 | 0.8422 | 0.8374 | 0.834 |
86 | 0.8483 | 0.8394 | 0.8347 | 0.8314 |
87 | 0.8456 | 0.8367 | 0.832 | 0.8286 |
88 | 0.8428 | 0.834 | 0.8294 | 0.8258 |
89 | 0.84 | 0.8314 | 0.8267 | 0.823 |
90 | 0.8374 | 0.8287 | 0.8239 | 0.8202 |
91 | 0.8347 | 0.8261 | 0.8212 | 0.8174 |
92 | 0.832 | 0.8234 | 0.8185 | 0.8146 |
93 | 0.8293 | 0.8208 | 0.8157 | 0.8118 |
94 | 0.8266 | 0.818 | 0.8129 | 0.809 |
95 | 0.824 | 0.8152 | 0.8101 | 0.8062 |
96 | 0.8212 | 0.8124 | 0.8073 | 0.8034 |
97 | 0.8186 | 0.8096 | 0.8045 | 0.8005 |
98 | 0.8158 | 0.8068 | 0.8016 | 0.7976 |
99 | 0.813 | 0.804 | 0.7987 | 0.7948 |
100 | 0.8102 | 0.8009 | 0.7959 | 0.7917 |
So, as long as 1 litre weighs less than 800g at 20C, it should be OK to use directly. (Better than 97% pure)