GB2050190A - Improvements in or relating to a process for recovering material from a solution - Google Patents

Abstract

In the crystallization of a material from a liquid solution thereof wherein normal rapid cooling tends to produce a non-filterable solid, the mixture of material and liquid is subjected to a high shear force field to produce a filterable slurry of the material, with the mixture being subjected to the shear force either during the cooling or subsequent thereto. The process is particularly applicable to recovering nicotinamide from a supersaturated aqueous solution thereof.

Description

SPECIFICATION Improvements in or relating to a process for recovering material from a solution THIS INVENTION relates to the recovery of a material from a solution by crystallization, and is particularly applicable to the recovery of nicotinamide frorn an aqueous solution thereof.

In many processes wherein a material is to be recovrered from a solution, particularly a supersaturated solution, by cooling the solution to a temperature below the incipient crystallization temperature, undesired spontaneous nucleation in the bulk of the solution occurs, resulting in the formation of a solid mass which cannot be stirred, pumped, filtered, or washed conveniently. Thus, for example, in the production of nicotinamide, nicotinamide is recovered as an aqueous solution, the hot solution being subsequently cooled to cause the nicotinamide to crystallize, thereby separating the nicotinamide from water soluble impurities such as nicotinic acid.

Nicotinamide is characterized by a very high solubility in water (it is completely miscible above 55 C) and a tendency to form supersaturated solutions. At high supersaturation levels, undesired spontaneous nucleation occurs, and at the concentration levels generally encountered, for example sixty to seventy percent nicotinamide, the resulting crystals adhere to each other and transform the content of the crystallizer into a solid mass which cannot be stirred, pumped, filtered, or washed conveniently. In order to maintain the flow properties of the resultant slurry, one of the current practices is to perform the cooling in stages.During the first stage, the hot solution is cooled at a convenient rate to the temperature of incipient crystallization (40 to 45"C), and then during the second stage the cooling proceeds at a strictly controlled rate of 1"C per hour until most of the nicotinamide has crystallized, the temperature then being 32"C.

During the third stage, the temperature is lowered as rapidly as possible to the filtration temperature (10 to 1 5 C). The slow cooling during the second stage is required in order to obtain a filterable slurry, and, depending on the concentration of the initial solution, the cooling process may take six to eight hours.

In accordance with another procedure, the nicotinamide is recrystallized from a convenient organic solvent in which the solubility of the nicotinamide is lower than in water; however, such a procedure requires the additional step of removing organic solvent adhering to the crystals and effecting recovery thereof.

According to the present invention, there is provided a process for recovering a material from a liquid solution thereof, the process comprising: rapidly cooling said solution to crystallize the material from the solution, and applying to the material and liquid a shear force field sufficient to produce a filterable slurry of said material. The shear force may be applied during or subsequent to said rapid cooling. The invention also relates to a material recovered by such a process.

It has been found that a filterable slurry of the crystallized material in the liquid can be produced from a solution which if it had been subjected to rapid crystalization cooling would normally produce a nonfilterable solid-like mixture of material and liquid, provided that the mixture of material and liquid is subjected to a high shear force during the cooling or after formation of the solid-like mixture of material and liquid. Thus, in a method in accordance with the present invention, the solution may be rapidly cooled while subjecting the solution to a shear force sufficient to produce a filterable slurry. Alternatively, the solution may be rapidly cooled (without application of such a shear force) and the resulting solid-like aggregate or mixture is subjected to a shear force sufficient to convert the solid aggregate or mixture to a filterable slurry.

The high shear force may be applied to the solid by use of any one of a wide variety of apparatuses capable of providing a shear force field. Thus, for example, the equipment may. be one or two-screw grinders, Z blade mixers, vibrating mixers and the like. The shear force which is applied is varied depending on the concentration of the solution (in general higher forces are required at higher concentrations), the particular type of solid, and other characteristics. As should be apparent, the power input, velocity or frequency and amplitude of the active shearing elements are controlled to provide a shear force which is sufficient to produce a filterable slurry of the material.The selection of the particular shear force required to produce a filterable slurry is deemed to be well within the scope of those skilled in the art from the teachings herein, and as a result, no further details in this respect are deemed necessary for a complete understanding of the present invention.

Although the invention is of general applicability to recovery of a material from a solution wherein rapid cooling of the solution to produce solidification would normally produce a nonfilterable solid, the present invention has particular applicability to the recovery of nicotinamide from aqueous solutions thereof, such as those resulting from the production of nicotinamide from nicotinonitrile. In general, such solutions have a nicotinamide concentration of at least 40%, most generally at least 50%, but usually the nicotinamide concentration does not exceed 85%. The aqueous solution also generally contains as an impurity nicotinic acid, generally present as ammonium nicotinate. Such an aqueous solution may be produced, for example, by the procedure disclosed in U.S.A.Patent Specification No. 4;008,241, although as should be apparent the present invention is not limited to aqueous solutions of nicotinamide produced by such a procedure.

An aqueous solution of nicotinamide is cooled to solidify the nicotinamide from the aqueous solution, without slow cooling, in other words cooling is effected at the maximum practicable cooling rate, with the mixture being subjected to a shear force field sufficient to produce a filterable slurry either during or subsequent to such cooling. In this manner, nicotinamide may be recovered and separated from a mother liquor which contains the nicotinic acid impurity. The recovered nicotinamide crystals may then be washed to remove nicotinic acid dissolved in the mother liquor which adheres to the crystals after filtration.

The recovery of a compound from a solution in accordance with the present invention may be effected in a batch or continuous manner. Preferred embodiments of the invention offer the advantage that filterable slurries are obtained irrespective of cooling rate, do that by cooling the solution at the maximum practicable rate, the overall time for solid recovery may be reduced. In addition, strict control procedures over lengthy periods of time are no longer required.

The invention will be further described with respect to the following Examples; however, the scope of the invention is not to be limited thereby; EXAMPLE 1 500 g of a hot mixture containing 65% nicotinamide, 5% nicotinic acid (as ammonium nicotinate) and the rest water is cooled in a beaker placed in an ice-water bath. The first crystals appear at 42"C, and at 30"C the mixture cannot be stirred any more. When a thermocouple implanted in various points of the solid mass which has formed shows a temperature of 10-1 5 C, the mass is cut to conveniently sized pieces and fed to a worm grinder, which was previously cooled. A thick paste results, from which upon filtration, 70 g filtrate are obtained.

The possibility of purifying the nicotinamide crystals from the nicotinic acid existing in the initial solution, by using the procedure of the present disclosure, is proven in Example 2.

EXAMPLE 2 A hot mixture containing 65% nicotinamide, 5% nicotinic acid (as ammonium nicotinate) and the rest water is cooled in an ice bath. A shear force is applied to the cooling mixture by means of a perforated disk immersed in the mixture, which is made to vibrate along a direction normal to its main surface (frequency 60 Hz, amplitude ca. 0.05-0.2 mm). A thick, homogenous slurry is obtained. Upon reaching 12"C, 214 g of the slurry are:iltered on a Buchner funnel. 47 g filtrate are obtained. The precipitate (167 g) is reslurried at 14"C with 46 g saturated solution of pure nicotinamide and then refiltered. In this manner no crystals of nicotinamide will dissolve in the wash liquid.The nicotinic acid (ammonium nicotinate) dissolved in the mother liquor, which adheres to the crystals after the filtration, will be diluted by the wash liquid. Upon filtration, the amount of nicotinic acid dissolved in the mother liquor adhering to the crystals will be less than before. The reslurrying and filtration are repeated twice under substantially the same conditions.

After the initial filtration and after the second and third washings, samples of the precipitate are collected and analyzed for nicotinic acid. The results, expressed as wt% nicotinic acid in the dry precipitate, are compared in the table below to those calculated (by using the actual weights of the precipitate, filtrate and wash liquid) by assuming that the whole amount of nicotinic acid is dissolved in the mother liquid adhering to the crystals.

Wt% Nicotinic Acid (dry basis) Calculated Actual Initial mixture -- 7.03 Precipitate after filtration 4.1 5 4.74 Precipitate after 1 sot wash 2.70 Precipitate after 2nd wash 1.41 0.80;0.81 Precipitate after 3rd wash 0.74 0.51;0.42 The above results show that by proceeding in accordance with the invention the nicotinic acid, present as ammonium nicotinate in the initial slurry, neither forms mixed crystals with the nicotinamide nor is occluded in its crystals; accordingly, a high degree of purification is achieved.

Claims (11)

1. A process for recovering a material from a liquid solution thereof, the process comprising: rapidly cooling said solution to crystallize the material from the solution, and applying to the material and liquid a shear force field sufficient to produce a filterable slurry of said material.

2. A process according to claim 1 wherein the shear force field is applied during said rapid cooling.

3. A process according to claim 1 wherein said shear force field is applied, subsequent to said rapid cooling, to a solid-like aggregate of material and liquid.

4. A process according to any one of the preceding claims wherein the solution is such that, if subjected solely to rapid cooling, the solution would produce a nonfilterable solid.

5. A process according to any one of the preceding claims wherein the solution is an aqueous solution of nicotinamide.

6. A process according to claim 5 wherein the nicotinamide concentration is at least 40%.

7. A process for recovering nicotinamide substantially as herein described with reference to Example 1.

8. A process for recovering nicotinamide substantially as herein described with reference to Example 2.

9. A process for recovering a material from a liquid solution thereof substantially as herein described.

1 0. A material whenever recovered from a liquid solution by a process according to any one of the preceding claims.

11. Any novel feature or combination of features herein described.