SU46496A1 - Method for producing 2,3-butylene glycol - Google Patents

Description

It has long been known that various carbohydrates and related compounds Sbrag live by certain genera of bacteria, forming 2-3 butylene glycol along with other products of fermentation. Thus, Garden and Valpol proved in 1906 that, under certain conditions, bacterium lactis aerogenes forms quite significant amounts of 2-3 butylene glycol from glucose and mannitol. The same fact was established with respect to bacteria, which in the state of forming a small amount of 2-3 butylene glycol and related acetyl methyl carbinol turned out to be. Very large.

Although obtaining 2-3 butylene glycol by microbiological means has been known for more than 20 years, however, until now this method has not led to the industrial production of 2-3 butylene glycol. This will not be surprising if we recall that the conditions that were required by the experiments of Gardena and Valpol to achieve complete fermentation of glucose were of such a kind that their technical application was out of the question. To achieve complete fermentation of a 2% glucose solution, it was necessary to add to the fermentable solution.

1% protein, which should be in turn cleaved to expensive peptone, and even under such conditions, complete fermentation lasts no less than a month.

The method according to the invention is based on the new and unexpected observation that on one side it is possible to completely avoid expensive raw materials and instead ferment into 2-3 butylene glycol a quite accessible substance — sugar; on the other hand, more concentrated solutions can be fermented, as the process ends incomparably faster than usual.

As starting materials, maize and potato jams with or without saccharification were suitable, and it does not matter if saccharification is achieved using malt or microbial diastasis or using acids; further, the mash can be from rye, oats, wheat, barley, buckwheat, cassava and other starchy substances, as well as from sugary substances like beet molasses, cane nelessa, maple

And palm sugar syrup, in short, from all raw materials that generally can be used for the industrial production of alcohol. Further, materials containing milk sugar, whey, skimmed milk, etc., are quite suitable.

The use of these materials for the fermentation process has been possible, since you have dreamed that of these materials differ so much between them, if only they contain starch or sugar or both, and if they are mixed with nitrogen compounds, phosphates and carbonates (since these compounds are not contained in them), a congestion can be obtained that gives, when fermented, with the help of clostridium polymyxa, aerobacter aerogencs, or bacteria with a corresponding fermentation force of 2-3 butylene glycol.

Under the appropriate fermentation force is meant the ability of the fermentation (bat different varieties of sugar in the formation of 2-3 bottle-1-glycol.

In general, used raw materials contain too little nitrogenous compounds, as well as phosphates and carbonates. However, the congestion made from such materials with the addition of nitrates,. inorganic ammonium salts, urea or phosphates, and insoluble carbonates, is a nutrient medium that is quite suitable for fermentation in 2-3 butylene glycol. It was possible to bring congestion with the content of soluble carbohydrates up to 15 and even 209 to complete digestion and during such periods of time that do not preclude the industrial application of this method. For example, it was possible to bring cane and beetroot molasses to full fermentation for 36 hours, if diluted in the right way and adding small amounts of superphosphate and calcium carbonate, thereby producing high yield of butylene glycol, reaching 30-50% of sugar used in molasses. . In addition, it is also clear that alcohol is obtained in the amount of 16-40% of the fermented

Sahara; this alcohol can be used to produce normal alcohol.,

Further, it was found that in the presence of lysing-known nutrient salts, the fermentation ability of various genera of bacteria in jams increases significantly if oxygen is blown through them with admixture of other gases (for example air) or without them, moreover, in such quantities as nor in the amount of fermented product does not occur noticeable changes. The duration of fermentation is thus greatly reduced. In this case, it turned out to be advisable to flush the waste gases with water in order to eliminate the loss of alcohol.

Since you dreamed that a relatively high concentration of butylene glycol, as opposed to comparatively small amounts of alcohol, does not harm the fermentation properties of bacteria, it may be beneficial to distil the alcohol with or without vacuum, but using the butyl alcohol residue to prepare a new mash.

In this way, a relatively high concentration of butylene glycol in the fermented mash can be obtained, thereby reducing production costs.

Butylene glycol is obtained by evaporating the fermented mash in a vacuum evaporator or other evaporator, or by extracting the residue with ether or similar solvents.

For example, potatoes with 20th starch content are treated in a Genze steamer in such a way that a pressure of 3 atm is reached within 30 minutes. The mass thus obtained is rubbed off in the usual manner with 75 kg of malt. The clog is heated in a sealed, pre-sterilized device after refluxing to a boiling point and then cooled to 41 g. The plans are added 25 kg of superphosphate and 19 kg of well-ground limestone. All this mixes well with a 200 l culture of aerobacter aerogenes fe Malt extract.

When the evolution of gases begins, air is blown through the liquid with such a force that it takes 25 hours per hour. " After some time (33 to 39 hours), the fermentation ends. From a burglar mash is obtained by distillation and rectification of 150 liters of 95% alcohol. By evaporation and subsequent distillation in vacuum, 235 K1 of crude 2–3 butylene glycol with a content of 92% is obtained.

Example 2. 1400 kg of uncooked sugar chalk are mixed with 3500 l of water and 40 Kt of finely ground phosphorite and the mixture is heated for 15 minutes at boiling point. After this, 50 g of ammonium sulphate and 35 kg of well ground limestone are added. Upon cooling to 43, 300 l of pure serum clostridium polymyxa culture is added. After 2 hours, the air begins to be blown out with such a force that 30 m passes per hour. The gases coming out of the closed mash tank are stored in a tank filled with water, as a result of which the entrained alcohol is trapped. Fermentation ends in 24-36 hours. The fermented mash with the wash liquid is treated as in Example 1. The output is 175 liters.

alcohol and 183 kg of raw 2-3 butylene glycol content of 92%.

The subject matter of the invention.

Claims (2)

1. A method for producing 2-3. Butylene glycol by fermenting carbohydrates, differs in that the previously sterilized mash of carbohydrates, with the addition of the usual nutrients for microorganisms of nitrogenous phosphates and carbonates, is subjected to fermentation with the help of clostridium polymyxa or aerobacter aerogenes with blowing air or oxygen after which ethyl alcohol formed during fermentation is distilled off, and 2-3 butylene glycol is isolated from the residue by known methods, for example, by distillation in vacuum, by solvent extraction or the like. 2. The implementation of the method according to claim 1, characterized in that upon termination of the fermentation and distillation of ethyl alcohol, a new mash and a new amount of the same microorganisms are added to the residue, and a new fermentation is carried out, processing the product according to claim 1 or repeating alcohol, additive mash and. bacteria and fermentation again.