A process for the purification of levulinic acid including the following steps: a. providing a composition 1, comprising at least 75 wt. % of levulinic acid; b. cooling composition 1 to at least one temperature Tc, wherein Tc is a temperature in the range 1.23*(W1)104.5Tc ( C.)1.23*(W1)89.5, wherein W1 is the weight % of levulinic acid in composition 1, to obtain a cooled composition 1; c. performing melt crystallization of composition 1 including the steps of: i. bringing the cooled composition 1 into contact with levulinic acid crystal seeds, ii. allowing the levulinic acid in composition 1 to crystallize at at least one temperature Tc to obtain crystals 1 and liquid 1, and iii. draining of liquid 1; d. optionally, treating crystals 1, after draining of liquid 1, by sweating, according to the following steps: i. heating the crystals 1 at a temperature between 5 and 40 C. to obtain crystals 2 and liquid 2, and ii. draining of liquid 2; e. melting the crystals 1 or 2, after draining of liquid 1 or 2, to obtain composition 2, f. determining the levulinic acid concentration in composition 2 and, in case the levulinic acid concentration is below a predetermined value, repeating steps b, c, optionally d, and e, as many times as necessary to obtain a final composition with a predetermined levulinic acid concentration.

A process for the purification of levulinic acid including the following steps: a. providing a composition 1, comprising at least 75 wt. % of levulinic acid; b. cooling composition 1 to at least one temperature Tc, wherein Tc is a temperature in the range 1.23*(W1)104.5Tc ( C.)1.23*(W1)89.5, wherein W1 is the weight % of levulinic acid in composition 1, to obtain a cooled composition 1; c. performing melt crystallization of composition 1 including the steps of: i. bringing the cooled composition 1 into contact with levulinic acid crystal seeds, ii. allowing the levulinic acid in composition 1 to crystallize at at least one temperature Tc to obtain crystals 1 and liquid 1, and iii. draining of liquid 1; d. optionally, treating crystals 1, after draining of liquid 1, by sweating, according to the following steps: i. heating the crystals 1 at a temperature between 5 and 40 C. to obtain crystals 2 and liquid 2, and ii. draining of liquid 2; e. melting the crystals 1 or 2, after draining of liquid 1 or 2, to obtain composition 2, f. determining the levulinic acid concentration in composition 2 and, in case the levulinic acid concentration is below a predetermined value, repeating steps b, c, optionally d, and e, as many times as necessary to obtain a final composition with a predetermined levulinic acid concentration.

The present invention provides an integrated system comprising: an electrocatalysis device, in which an oxidation reaction is carried out at an anode by an electrocatalysis of glycerol, and at a cathode hydrogen is produced through a reduction reaction; and a chemical catalysis device for producing butene oligomers from lignocellulosic biomass through a hydrogenation process, wherein the hydrogen produced by the electrocatalysis device is used for the production of the butene oligomers by the chemical catalysis device, and a thermal energy of the electrocatalysis device and the chemical catalysis device is exchanged with each other. The integrated system according to the present invention can reduce the cost of materials of a process for preparing butene oligomers by using hydrogen, which is a byproduct of a process for preparing glycerol derivatives, as a material of a process for preparing the butene oligomers through the integration of materials and energy from the processes for preparing glycerol derivatives and butene oligomers, and can obtain an effect of reducing energy costs by greatly reducing energy required in an integrated process by supplying, as a part of a thermal energy required at the process for preparing glycerol derivatives, the waste heat of the process for preparing the butene oligomers through the construction of a thermal energy integration network.

A levulinic acid composition A having: a. at least 95 wt. % of levulinic acid; b. between 5 wppm and 5000 wppm of formic acid; and c. less than 1000 wppm of angelica lactone, based on the total weight of the composition. A process for the isolation of a levulinic acid composition, having the following steps: a. performing acid catalyzed hydrolysis of a C6 carbohydrate-containing feedstock to obtain reaction product X, b. subjecting of reaction product X to solid-liquid separation to provide a composition 1, c. feeding composition 1 to at least two purification steps to treat composition 1 to obtain a levulinic acid composition, wherein a second or a further purification step is a melt crystallization step.

A levulinic acid composition A having: a. at least 95 wt. % of levulinic acid; b. between 5 wppm and 5000 wppm of formic acid; and c. less than 1000 wppm of angelica lactone, based on the total weight of the composition. A process for the isolation of a levulinic acid composition, having the following steps: a. performing acid catalyzed hydrolysis of a C6 carbohydrate-containing feedstock to obtain reaction product X, b. subjecting of reaction product X to solid-liquid separation to provide a composition 1, c. feeding composition 1 to at least two purification steps to treat composition 1 to obtain a levulinic acid composition, wherein a second or a further purification step is a melt crystallization step.

A levulinic acid composition A having: a. at least 95 wt. % of levulinic acid; b. between 5 wppm and 5000 wppm of formic acid; and c. less than 1000 wppm of angelica lactone, based on the total weight of the composition. A process for the isolation of a levulinic acid composition, having the following steps: a. performing acid catalyzed hydrolysis of a C6 carbohydrate-containing feedstock to obtain reaction product X, b. subjecting of reaction product X to solid-liquid separation to provide a composition 1, c. feeding composition 1 to at least two purification steps to treat composition 1 to obtain a levulinic acid composition, wherein a second or a further purification step is a melt crystallization step.

The invention describes processes to prepare levulinic acid, formic acid and/or hydroxymethyl furfural from various biomass materials.

The invention describes processes to prepare levulinic acid, formic acid and/or hydroxymethyl furfural from various biomass materials.

The invention describes processes to prepare levulinic acid, formic acid and/or hydroxymethyl furfural from various biomass materials.

Unique methods have been developed to convert polysaccharides into value-added products, such as levulinic acid and alkyl levulinates. The polysaccharides are heated in the presence of water, an alcohol, and an acid to cleave the polysaccharide, and the resulting monosacchrides or monosaccharide acetals or both are contacted with an acid in the presence of an alcohol at a higher temperature. Useful acids include Brnsted acid catalysts and Lewis acid catalysts including mineral acids, metal halides, immobilized heterogeneous catalysts functionalized with a Brnsted acid group or a Lewis acid group, or combinations thereof.