KR101430393B1 - By-product recyclign equipment applied fatty acid derivatives manufacturing process - Google Patents

Abstract

The present invention relates to a byproduct reproducing apparatus applied to a production process of a fatty acid derivative and, more specifically, to a byproduct reproducing apparatus applied to a production process of a fatty acid which may reproduce and reuse a byproduct generated when making a fatty acid react with ammonia to produce a fatty acid derivative. As a technical mean to solve the problem described above, the present invention provides a byproduct reproducing apparatus applied to a production process of a fatty acid derivative, includes: a reactor making a fatty acid react, a processor separating the fatty acid which have reacted from the fatty acid in the reactor; a refiner refining the fatty acid which has reacted and separated by the processor; a pulverizer pulverizing the fatty acid derivative refined by the refiner; and a packer packing the pulverized fatty acid derivative. The reproducing apparatus further includes a reproducing device including: a byproduct storage tank storing the byproduct generated by the processor; a reproducing reactor reproducing the byproduct stored in the byproduct storage tank; a water tank supplying water to the reproducing reactor; a sulfuric acid tank providing sulfuric acid to the reproducing reactor; a reproduced fatty acid storage tank storing the reproduced fatty acid in the reproducing reactor; and a refiner receiving and refining waste water having passed through the reproducing reactor.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a by-product recycling apparatus for producing a fatty acid derivative,

More particularly, the present invention relates to a process for producing a fatty acid derivative capable of regenerating and reusing a by-product generated when a fatty acid is reacted with ammonia to produce a fatty acid derivative To a by-product regeneration apparatus.

Fatty acid derivatives are very useful substances widely used as surfactants, soaps, cosmetics, pharmaceuticals, lubricants or raw materials for biodiesel. The fatty acid derivative is produced by reacting a fatty acid with ammonia (NH ₃ ) or by an ester reaction, and a technique for producing a fatty acid derivative is a known technique.

1 is a diagram showing a conventional process for producing a fatty acid derivative using ammonia.

1, a fatty acid derivative is produced through a reaction process 10, a treatment process 30, a purification process 50, a pulverization process 70 and a packaging process 90, The fatty acid is pumped into the reaction apparatus, purged with nitrogen, and then reacted with ammonia (NH ₃ ). In the reaction step (10), the reaction is carried out at a reaction temperature of 150 to 250 ° C and a reaction pressure of 5 to 15 kg / cm ² for several hours, and the fatty acid via the reaction step (10) is sent to the treatment step (30). The treatment process 30 may be performed in the reaction apparatus or may be performed in a separate processing apparatus. In the treatment step (30), caustic soda (NaOH, sodium hydroxide) is added to the fatty acid which has been reacted in the reaction step (10) to separate unreacted fatty acids. The longer the reaction time is, the higher the reaction yield will be. However, considering the productivity, it is effective to stop the reaction at a constant yield rather than reacting the trace amount of residual fatty acid. Generally, it is the most efficient process when the reaction between ammonia and fatty acid becomes about 85 ~ 95%. After the reaction between the fatty acid and ammonia is finished, a treatment step (30) is required to separate the unreacted fatty acid. In the treatment step (30), the reacted fatty acid is separated from the unreacted fatty acid and the reacted fatty acid is sent to the purification step (50). In the refining step 50, only the reacted fatty acid is purified to high purity. In the pulverizing step 70, the high-purity fatty acid derivative is pulverized. In the packing step 90, the pulverized fatty acid derivative is packed. The method for producing a fatty acid derivative in the above-described manner is a well-known technique widely used in the prior art and will not be described in further detail.

On the other hand, sodium salt byproducts of about 5 to 15% of the raw materials are generated in the process as described above. In the past, all such by-products were treated as industrial waste. Therefore, there is a problem in that the waste treatment costs are costly, and the fatty acids that depend on the whole amount are consequently discarded. Therefore, there is a need for a technique that can reproduce and use such by-products.

KR 10-1347145 A KR 10-2007-0103441 A KR 10-2012-0131529 A JP 2012-246285 A JP 2013-67590 A JP 2013-233142 A JP 2014-15623 A

The object of the present invention is to provide a by-product regeneration apparatus applied to a process for producing a fatty acid derivative capable of reducing sodium salt by-products generated in a treatment process to fatty acids and reusing the same. have.

The present invention, as a technical means for solving the above-mentioned problems, is characterized in that it comprises a reaction device for reacting a fatty acid, a treatment device for separating the fatty acid reacted in the fatty acid reacted in the reaction device, A regeneration apparatus for purifying fatty acids, a pulverizing apparatus for pulverizing the purified fatty acid derivatives in the purifying apparatus, and a packaging apparatus for packaging the pulverized fatty acid derivatives, Wherein the regenerating apparatus further comprises a byproduct storage tank for storing byproducts generated in the processing apparatus, a regeneration reaction apparatus for regenerating the byproducts stored in the byproduct storage tank, A water tank for supplying water to the reaction apparatus and a sulfuric acid Storing the reproduced fatty acid in the regeneration reactor and the feed sulfuric acid tank for storage reproducing fatty acid can comprise a purification unit for purifying waste water by receiving subjected to the regeneration reactor and the tank.

In a preferred embodiment of the present invention, the regeneration reaction apparatus is characterized in that water and sulfuric acid are injected into the water tank and the sulfuric acid tank, respectively, and an aqueous sulfuric acid solution of 5 to 25% is supplied.

In a preferred embodiment of the present invention, a heating device is provided on the inside or outside of the regeneration reaction apparatus, and the regeneration reaction apparatus is provided with a heat insulation unit on the outside of the regeneration reaction apparatus to heat and maintain the regeneration reaction apparatus at 50 to 150 degrees, In the regeneration reactor filled with the aqueous solution, by-products discharged from the treatment apparatus are injected and reacted while mixing.

In a preferred embodiment of the present invention, the reaction time in the regeneration reaction apparatus is 5 to 9 hours.

In a preferred embodiment of the present invention, the regenerated fatty acid storage tank further comprises a cleaning device, wherein the reduced fatty acid in the regeneration reaction apparatus is washed with water.

The by-product regeneration apparatus applied to the fatty acid derivative production process according to the present invention has the effect of reducing the waste of raw materials by using the by-product generated in the process of producing the fatty acid derivative by using the aqueous dilute sulfuric acid solution and then reducing it to fatty acid. In addition, there is also an advantage in that it is possible to reduce the cost of processing the by-products as well as the raw materials by recycling the by-products which have conventionally been treated as industrial wastes at a high cost.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram showing a conventional process for producing fatty acid derivatives using ammonia in the prior art. FIG.
2 is a view showing an example of a by-product recycling apparatus applied to the production process of a fatty acid derivative according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing an example of a by-product regeneration apparatus applied to a fatty acid derivative production process according to the present invention.

1 and 2, the by-product regeneration apparatus to be used in the fatty acid derivative production process according to the present invention comprises a reaction apparatus 10 for reacting fatty acids, a fatty acid reacted in the reaction apparatus 10, (50) for purifying the reacted fatty acid separated from the treatment device (30), and a pulverizing step of pulverizing the purified fatty acid derivative in the purifying device (50) A device 70 and a packaging device 90 for packing the powdered fatty acid derivative. The processing device 30 is further provided with a reproducing device 200. The regeneration apparatus 200 may include a byproduct storage tank 210, a regeneration reaction apparatus 230, a water tank 250, a sulfuric acid tank 270, a regenerant fatty acid storage tank 280, and a purifier 290 .

The reaction apparatus 10 is a device for carrying out a reaction process in which a fatty acid is reacted with ammonia (NH ₃ ) to produce a fatty acid derivative. In the reaction step, the fatty acid is introduced into the reactor 10 to perform nitrogen purging first, followed by heating to a temperature required for the reaction, and ammonia is added to the reactor in which the reaction is completed. Reaction process. The reaction is carried out at a reaction temperature of about 150 to 250 ° C and a reaction pressure of 5 to 15 kg / cm ² for several hours, and the fatty acid that has undergone the reaction process is sent to the treatment device 30. In the treatment apparatus 30, caustic soda (NaOH, sodium hydroxide) is added to the reacted fatty acid to separate unreacted fatty acids. In the refining apparatus 50, the fatty acid derivative separated from the treatment device 30 is purified And the powdering device 70 is used to powder the high-purity fatty acid derivatives and pack them in a predetermined amount in the packaging device 90. The apparatus and method for producing a fatty acid derivative in the above process are well known in the art and will not be described in detail.

The by-product regeneration apparatus applied to the fatty acid derivative production process according to the present invention is characterized in that the regeneration apparatus 200 is additionally provided in the treatment apparatus 30. In the reaction apparatus 10, the reacted fatty acid is not 100% reacted, but usually about 85 to 95% of the reacted fatty acid has been reacted, and thus about 5 to 15% of the unreacted fatty acid is present. The longer the reaction time of the fatty acid, the higher the reaction yield. However, the longer the reaction time, the lower the productivity and the higher the product cost. Therefore, when the reaction is completed with a good yield in terms of time, the reaction process is stopped and the unreacted fatty acid and the completed fatty acid are separated from the treatment device. The fatty acid that has undergone the reaction is passed through the purification apparatus 50, the pulverization apparatus 70 and the packaging apparatus 90 as described above to be a finished product. However, the untreated fatty acid separated from the treatment apparatus is discharged as a by-product in the form of sodium salt. In the past, the byproduct discharged from the treatment apparatus 30 was treated as waste. However, the by-products discharged from the treatment device 30 are classified as industrial wastes, so that the treatment cost is high, resulting in a loss of the wastes of the raw materials.

The by-product regeneration apparatus applied to the fatty acid derivative production process according to the present invention can reduce the by-products generated in the treatment apparatus 30 to fatty acids and reuse them.

The byproduct storage tank 210 is connected to the processing unit 30 by piping to temporarily store the by-products discharged from the processing unit 30. [ The regeneration reaction apparatus 230 performs a reaction for reducing the byproducts stored in the byproduct storage tank 210 to fatty acids and includes a regeneration tank 231 and a heating apparatus 233 for heating the regeneration tank 231 And a heat insulating portion 235 for insulating the regeneration tank 231 heated by the heating device 233. In addition, an agitation device 237 is further provided in the regeneration tank 231 to stir the aqueous solution of sulfuric acid used for the by-product and the reduction reaction in the regeneration process. In the preferred embodiment of the present invention, the heating device 233 may be equipped with various known heating means and may be provided inside or outside the regeneration tank 231. The heat insulating portion 235 is configured to surround all or a part of the regenerating tank 231, and may preferably be composed of an airgel insulating layer. In addition, the stirring device 237 is provided with a spiral blade inside the regeneration tank 231 so that the blade can be rotated using a motor.

Meanwhile, the regeneration reaction apparatus 230 is connected to the water tank 250 and the sulfuric acid tank 270 through piping. Thus, the water supplied from the water tank 250 and the sulfuric acid (H ₂ SO ₄ ) supplied from the sulfuric acid tank 270 are mixed with each other to form an aqueous sulfuric acid solution of about 5 to 25%.

The regenerated fatty acid storage tank 280 and the purifier 290 are connected to the lower part of the regeneration reaction device through a pipe to receive waste water and fatty acid after the regeneration process is completed. The by-product in the form of a sodium salt reacts with the sulfuric acid aqueous solution in the regeneration reaction unit 230 to convert into fatty acid and water (including sulfuric acid). The fatty acid is floating in water because the specific gravity is about 0.85. Therefore, water and fatty acid are separated after a certain period of time after the completion of the regeneration reaction, and water and fatty acid can be sequentially discharged to the lower part of the regeneration reaction apparatus 230 and separated. First, the discharged water is sent to the purifying device 290, is purified and then discarded, and the fatty acid can be stored in the regenerated fat storage tank 280 and reused. On the other hand, since sulfuric acid is still present on the separated fatty acid, the recycled fatty acid storage tank 280 may further include a cleaning device (not shown) as a preferred embodiment of the present invention. Thus, the fatty acid separated in the regeneration reaction apparatus 230 may be washed with water 5 to 7 times and recovered as a final product.

The by-product recycling apparatus used in the fatty acid derivative production process according to the present invention will be described in detail. First, the by-product discharged to the treatment apparatus 30 during the production of fatty acids is temporarily stored in the by- Lt; / RTI > Then, water and sulfuric acid are supplied to the regeneration reaction tank 230 from the water tank 250 and the sulfuric acid tank 270 to fill the aqueous sulfuric acid solution with about 5 to 25%. Then, the byproducts stored in the byproduct storage tank 210 are introduced into the regeneration reaction apparatus 230 and reacted with stirring. The reaction temperature is preferably from 50 to 150 ° C, and the reaction time is preferably from 5 to 9 hours. As described above, when the by-product is reacted with the aqueous sulfuric acid solution in the regeneration reaction apparatus 230, the sodium salt is reduced to the fatty acid. After a certain period of time after the completion of the reduction process, the fatty acid floats above the regeneration reaction tank 230, and the water (water containing sulfuric acid) falls downward and separates. When the outlet provided at the lower part of the regeneration reaction tank 230 is opened in the above state, the water located in the lower part of the regeneration reaction tank 230 is discharged first and the upper fatty acid is discharged later. Therefore, the recycled fatty acid storage tank 280 connected to the discharge port and the purifier 290 can separate water and fatty acids and store them. The water stored in the purifier 290 is discharged after being purified to a certain level. On the other hand, since the fatty acid stored in the regenerated fatty acid storage tank 280 still contains sulfuric acid, it can be used after being cleaned using a cleaning device.

3 is a view showing still another embodiment of a by-product recycling apparatus applied to a fatty acid derivative production process according to the present invention.

3, the by-product recycling apparatus for use in the fatty acid derivative production process according to the present invention is characterized in that the reaction apparatus 10 comprises a first reaction unit 110 and a second reaction unit 130, While the apparatus 110 is performing the reaction process, the second reaction apparatus 130 may proceed to the reaction preparation process so that the fatty acid after the reaction process can be continuously supplied to the treatment apparatus 30. [ The remaining configuration except for the processing device 30 is the same as that described above.

The reaction apparatus 10 is a reaction process, and the reaction process may include a reaction preparation process and a reaction process. The reaction preparation step comprises the step of feeding the fatty acid into the reaction apparatus, followed by nitrogen purging, and then heating the reaction apparatus to a temperature required for the reaction. The reaction step is a step in which ammonia (NH ₃ ) is introduced into the reaction apparatus 10 while the reaction apparatus is heated to the reaction temperature after nitrogen purging is completed.

The by-product regeneration apparatus applied to the fatty acid derivative production process according to the present invention comprises a first reaction apparatus 110 in which a reaction apparatus 10 performs a reaction preparation process and a second reaction apparatus 130 which performs a reaction process . In general, the time required for the treatment device 30 or the purification device 50 is shorter than the time required for the reaction process. Also, since the time required for the reaction preparation process is considerably long in the reaction process, the time required for the whole process tends to be determined by the time of the reaction process. Therefore, since the time required for the reaction process is a factor for determining the productivity, the productivity can be improved by reducing the reaction process time.

The apparatus for producing a fatty acid derivative according to the present invention comprises at least two or more reaction apparatuses in a reaction process so that a preparatory process necessary for a reaction is performed in another reaction apparatus during a reaction process in one reaction apparatus, The time required can be reduced. According to the method for producing a fatty acid derivative according to the present invention, it is possible to shorten the production process for 4 to 6 hours as compared with a conventional production method.

The first reaction device 110 and the second reaction device 130 may be arranged in parallel as shown in Figure 3. That is, May be directly connected to the processing device 30 in the first reaction device 110 or directly into the processing device 30 in the second reaction device 130. [ The reaction preparation step and the reaction step are performed in the first reaction apparatus 110 and are immediately introduced into the processing apparatus 30 after the completion of the reaction step. In the second reaction apparatus 130, the reaction preparation step and the reaction step And then the reacted fatty acid can be introduced into the treatment step 30. [ At this time, the starting times of the first reaction device 110 and the second reaction device 130 are different from each other. After the process is completed in the process device 30, the reaction in the first reaction device 110 The completed fatty acids are fed to the treatment device 30 and the treated fatty acid is fed to the treatment device 30 in the second reaction device 130 immediately after the treatment process is completed again in the treatment device 30 . The first reactor 110 and the second reactor 130 are connected in series so that one of the reactors performs only the reaction preparation process and the other one of the reactors The apparatus may be adapted to perform only the reaction process. That is, in the first reaction apparatus 110, only the reaction preparation step is performed to transfer the fatty acid having undergone the reaction preparation step to the second reaction apparatus 130. In the second reaction apparatus 130, 30).

In the method for producing a fatty acid derivative according to the present invention, the first reactor 110 and the second reactor 130 are connected to each other by an ammonia pump 150 to transfer ammonia generated in one of the reactors to another reactor .

In the reaction process, the fatty acid reacts with ammonia at about 150 to 250 ° C and a reaction pressure of 5 to 15 kg / cm ² . At this time, in the reaction apparatus in which the reaction process is performed, ammonia partially flows out in a liquid state or a vapor state, and conventionally, the ammonia thus discharged is discarded as it is. However, if the ammonia is discharged as such, it is necessary to compensate for the amount of ammonia lost in the next reaction step. As a result, the raw material used in the reaction step is wasted, and the discharged ammonia not only pollutes the surrounding environment It also causes the environment to deteriorate. An ammonia pump 150 is provided between the first and second reactors 110 and 130 and the ammonia pump 150 is connected to the first and second reactors 110 and 110 through a pipe, Device 130, so that some ammonia discharged from the reaction process can be injected into the reaction preparation process. In this way, recycled waste ammonia can be recycled to reduce production costs, prevent environmental pollution, and improve the working environment.

The ammonia pump 150 serves to transfer the ammonia discharged from the reaction process to the reaction preparation process. Therefore, when the first reactor 110 and the second reactor 130 are connected in parallel, the ammonia pump 150 is fed in a different direction depending on the process performed in each reactor. do. In the case where the reaction apparatuses are connected in parallel, the reaction preparation process proceeds in one reaction apparatus, and in the other reaction apparatus, the ammonia discharged from the reaction apparatus performing the reaction process is subjected to the reaction preparation process It is transferred to another reaction device which is performing. On the other hand, when the first reaction device 110 and the second reaction device 130 are connected in series, that is, the reaction preparation process is performed in the first reaction device 110, In the case where the reaction process is performed, since ammonia flows out from the second reaction device 130 in which the reaction process proceeds, the ammonia discharged from the second reaction device 130 to the first reaction device 110 is transferred do. this

In a preferred embodiment of the present invention, the ammonia is preferably introduced after the completion of the reaction preparation process. Therefore, if necessary, the ammonia pump 150 may further include an ammonia accommodating portion (not shown) capable of temporarily accommodating the ammonia discharged from the reaction process. If ammonia is discharged in the reaction process but the reaction preparation process is not completed yet, ammonia may be temporarily stored and stored, and ammonia may be introduced into the reaction tank for performing the reaction preparation process after completion of the reaction preparation process . At this time, the ammonia pump 150 is further provided with a cooling device (not shown) to liquefy the gaseous ammonia generated in the second reaction device 130 and transfer it to the first reaction device 110, Can be stored. Various known types of cooling devices may be used. For example, a pipe connecting the first and second reaction devices 110 and 130 may be cooled by cooling water or the like to liquefy ammonia in the transfer pipe .

The first reaction unit 110 and the second reaction unit 130 may include a reaction tank 120 and a stirring unit 121 provided in the reaction tank 120, A heating device 123 for heating the reaction tank 120 and a heat insulating part 125 for covering the whole or a part of the heating device 123 and the reaction tank 120 may be provided outside the reaction tank 120, The heat insulating portion 125 may be an airgel heat insulating layer and may be provided to surround all or a part of the reaction tank 120.

The fatty acid derivative producing apparatus according to the present invention has the above-described structure. First, the fatty acid and ammonia are mixed and reacted in the reaction process, and then the reacted fatty acid is transferred to the treatment device 30, The fatty acid is separated from the reacted fatty acid. At this time, in the reaction process, the first reaction device 110 and the second reaction device 130 may be provided to perform the reaction preparation process and the reaction process necessary for the reaction, respectively. Thus, the time required for the reaction process can be shortened. In addition, ammonia discharged from the reaction process is recovered and re-introduced into a reactor for performing a reaction preparation process, thereby preventing waste of raw materials and preventing environmental pollution.

T1, which is not described in the drawing, is a tank in which nitrogen is stored for purging nitrogen, T2 is a tank in which fatty acids are stored, and T3 is a tank in which ammonia is stored. T4 is a tank in which caustic soda is stored, and Re represents a regeneration process.

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the appended claims and equivalents thereof.

210: Byproduct storage tank
230: regeneration reaction tank
231: Regeneration tank
233: Heating device
235:
237: stirring device
250: Water tank
270: Sulfuric acid tank
280: Recycled fatty acid storage tank
290: purifier

Claims (5)

A reaction device for reacting the fatty acid with the fatty acid, a treatment device for separating the reacted fatty acid from the fatty acid reacted in the reaction device, a purification device for purifying the reacted fatty acid separated from the treatment device, A byproduct regeneration apparatus applied to a process for producing a fatty acid derivative comprising a pulverizing apparatus for pulverizing a fatty acid derivative and a packaging apparatus for packaging the pulverized fatty acid derivative,
Wherein the regeneration apparatus further comprises a regeneration reaction apparatus for regenerating the byproducts stored in the byproduct storage tank and the byproduct storage tank storing the byproducts generated in the processing apparatus, A regeneration fatty acid storage tank for storing the regenerated fatty acid in the regeneration reaction apparatus, and a purifying apparatus for receiving and purifying the wastewater through the regeneration reaction apparatus, wherein the regeneration reaction apparatus comprises a water tank for supplying water, a sulfuric acid tank for supplying sulfuric acid to the regeneration reaction apparatus, By-product regeneration device applied to the production process of a fatty acid derivative comprising
The method according to claim 1,
Wherein the regeneration reaction apparatus is fed with water and sulfuric acid in the water tank and in the sulfuric acid tank, respectively, and a 5 to 25% aqueous solution of sulfuric acid is fed.
The method of claim 2,
The regeneration reaction apparatus is provided with a heating device inside or outside the regeneration reaction apparatus and the regeneration reaction apparatus is provided with a heat insulation unit outside the regeneration reaction apparatus to heat and maintain the regeneration reaction apparatus at 50 to 150 degrees, Wherein the by-product discharged from the treatment device is injected and reacted while mixing.
The method of claim 3,
Wherein the reaction time in the regeneration reaction apparatus is 5 to 9 hours.
The method of claim 4,
Wherein the regenerated fatty acid storage tank further comprises a cleaning device to clean the reduced fatty acid in the regeneration reaction device with water.

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