Patent Description:
The present invention relates to a method for preparing an acrylic acid, and more particularly, to a method for preparing an acrylic acid by a dehydration reaction of a lactic acid, which reduces energy used while reducing an acrylic acid loss.

An acrylic acid is used as a polymer raw material used in fiber, adhesives, paint, fiber processing, leather, building materials, and the like, and its demand is growing. In addition, the acrylic acid is also used as a raw material of an absorbent resin and is industrially used a lot in absorbent articles such as paper diapers and sanitary napkins, agricultural and horticultural water retaining agents, industrial water stop materials, and the like.

A conventional method for preparing an acrylic acid is generally a method of oxidizing propylene in the air, but the method is a method of converting propylene into acrolein by a gaseous contact oxidation reaction and subjecting the acrolein to a gaseous contact oxidation reaction to prepare an acrylic acid, and the method produces an acetic acid as a by-product, which is difficult to separate from the acrylic acid. In addition, the method for preparing an acrylic acid using propylene uses propylene obtained by refining crude oil which is a fossil resource, as a raw material, and considering problems such as a recent rise in crude oil prices or global warming, the method has a problem in terms of raw material costs or environmental pollution.

Thus, a study on a method for preparing an acrylic acid from a carbon-neutral biomass raw material was conducted. For example, there is a method for preparing an acrylic acid (AA) by a gaseous dehydration reaction of a lactic acid (LA). This method is generally a method for preparing an acrylic acid by an intramolecular dehydration reaction of a lactic acid in the presence of a catalyst at a high temperature of <NUM> or higher. In this case, when the lactic acid is used at a high concentration, oligomers such as dimers and trimers are produced to lower the concentration of the lactic acid participating in the reaction. In addition, when the concentration of the lactic acid is lowered, the amount of water is large, and thus, the amount of energy used for removing water is increased. Document <CIT> discloses a process for the preparation of acrylic acid starting from lactic acid via a dehydration reaction.

An object of the present invention is to provide a method of reducing energy required to separate and remove water and minimizing an acrylic acid loss, in preparing an acrylic acid by a dehydration reaction of a lactic acid, in order to solve the problems mentioned in the Background Art.

In one general aspect, a method for preparing an acrylic acid includes: supplying a lactic acid aqueous solution to a reactor and performing a dehydration reaction to prepare a reaction product including an acrylic acid; supplying a reactor discharge stream including the reaction product to a first cooling tower and supplying an upper discharge stream from the first cooling tower to a second cooling tower; supplying a first acrylic acid aqueous solution stream discharged from a lower portion of the second cooling tower to an extraction column; supplying an upper discharge stream from the extraction column and a second acrylic acid aqueous solution stream discharged from a lower portion of the first cooling tower to a distillation column; and separating the acrylic acid from a lower discharge stream from the distillation column.

According to the method for preparing an acrylic acid of the present invention, the amount of energy used for separating water may be reduced and also an acrylic acid loss may be decreased, by separating a reaction product including an acrylic acid into a first acrylic acid aqueous solution stream and a second acrylic acid aqueous solution stream which have a composition advantageous for separation in each of a distillation column and an extraction column, using two cooling towers, and supplying the streams to the extraction column and the distillation column, respectively.

The term "stream" in the present invention may refer to a fluid flow in a process, or may refer to a fluid itself flowing in a pipe. Specifically, the stream may refer to both a fluid itself flowing in a pipe connecting each device and a fluid flow. In addition, the fluid may include any one or more components of gas, liquid, and solid.

Hereinafter, the present invention will be described in more detail for better understanding of the present invention, with reference to <FIG>.

According to the present invention, a method for preparing an acrylic acid is provided. More specifically, the method may include: supplying a lactic acid aqueous solution to a reactor and performing a dehydration reaction to prepare a reaction product including an acrylic acid; supplying a reactor discharge stream including the reaction product to a first cooling tower <NUM> and supplying an upper discharge stream from the first cooling tower <NUM> to a second cooling tower <NUM>; supplying a first acrylic acid aqueous solution stream discharged from a lower portion of the second cooling tower <NUM> to an extraction column <NUM>; supplying an upper discharge stream from the extraction column <NUM> and a second acrylic acid aqueous solution stream discharged from a lower portion of the first cooling tower <NUM> to a distillation column <NUM>; and separating the acrylic acid from a lower discharge stream from the distillation column <NUM>.

Specifically, a conventional method for preparing an acrylic acid is generally a method of oxidizing propylene in the air, but the method is a method of converting propylene into acrolein by a gaseous contact oxidation reaction and subjecting the acrolein to a gaseous contact oxidation reaction to prepare an acrylic acid, and the method produces an acetic acid as a by-product, which is difficult to separate from the acrylic acid. In addition, the method for preparing an acrylic acid using propylene uses propylene obtained by refining crude oil which is a fossil resource, as a raw material, and considering problems such as a recent rise in crude oil prices or global warming, the method has a problem in terms of raw material costs or environmental pollution.

In order to solve the problems of the conventional method for preparing an acrylic acid, a study on a method for preparing an acrylic acid from a carbon-neutral biomass raw material was conducted. For example, there is a method for preparing an acrylic acid (AA) by a gaseous dehydration reaction of a lactic acid (LA). This method is generally a method for preparing an acrylic acid by an intramolecular dehydration reaction of a lactic acid in the presence of a catalyst at a high temperature. However, when a high concentration of a lactic acid aqueous solution is used as a raw material, oligomers such as dimers and trimers are formed by an equilibrium reaction to lower the content of a lactic acid monomer participating in the reaction, and when the concentration of the lactic acid aqueous solution is lowered and used as a raw material, the content of water in a reaction product of a lactic acid dehydration reaction is significantly higher than that in a conventional process of preparing an acrylic acid by a propylene oxidation reaction, and thus, the amount of energy used required for water separation is greatly increased.

In this regard, in order to solve the conventional problems, the present invention is intended to provide a method for preparing an acrylic acid by a dehydration reaction of a lactic acid, which reduces the amount of energy used required for water separation and also minimizes an acrylic acid loss.

According to an exemplary embodiment of the present invention, a lactic acid is supplied to a reactor and a dehydration reaction is performed to prepare a reaction product including an acrylic acid. Here, the lactic acid may be introduced to the reactor in an aqueous solution state, and the dehydration reaction may be performed in a gaseous reaction in the presence of a catalyst. For example, the concentration of the lactic acid in the lactic acid aqueous solution may be <NUM> wt% or more, <NUM> wt% or more, or <NUM> wt% or more and <NUM> wt% or less, <NUM> wt% or less, <NUM> wt% or less, or <NUM> wt% or less.

The reactor may be a reactor capable of a common dehydration reaction of a lactic acid, the reactor may include a reaction tube filled with a catalyst, and while a reaction gas including volatile components of a lactic acid aqueous solution as a raw material is passed through the reaction tube, a lactic acid may be dehydrated by a gaseous contact reaction to produce an acrylic acid. The reaction gas may further include any one or more dilution gases of water vapor, nitrogen gas, and air for adjusting a concentration, in addition to the lactic acid.

Operation conditions of the reactor may be common dehydration reaction conditions of a lactic acid. Here, the operation temperature of the reactor may refer to a set temperature of a heating medium or the like used for controlling the temperature of the reactor.

A catalyst used in the dehydration reaction of the lactic acid may include, for example, one or more selected from the group consisting of sulfate-based catalysts, phosphate-based catalysts, and nitrate-based catalysts. As a specific example, the sulfate may include Na<NUM>SO<NUM>, K<NUM>SO<NUM>, CaSO<NUM>, and Al<NUM>(SO<NUM>)<NUM>, the phosphate may include Na<NUM>PO<NUM>, Na<NUM>HPO<NUM>, NaH<NUM>PO<NUM>, K<NUM>PO<NUM>, K<NUM>HPO<NUM>, KH<NUM>PO<NUM>, CaHPO<NUM>, Ca<NUM>(PO<NUM>)<NUM>, AlPO<NUM>, CaH<NUM>P<NUM>O<NUM>, and Ca<NUM>P<NUM>O<NUM>, and the nitrate may include NaNO<NUM>, KNO<NUM>, and Ca(NO<NUM>)<NUM>. In addition, the catalyst may be supported on a support. The support may include one or more selected from the group consisting of, for example, diatomaceous earth, alumina, silica, titanium dioxide, carbides, and zeolite.

A reaction product prepared from the dehydration reaction of the lactic acid may further include by-products such as water (H<NUM>O), acetaldehyde (ACHO), carbon monoxide (CO), carbon dioxide (CO<NUM>), and low-boiling point materials and high-boiling point materials of dilution gas, in addition to the acrylic acid as a product to be desired.

A content ratio of water to the acrylic acid in the reaction product may be <NUM> or more, <NUM> or more, or <NUM> or more and <NUM> or less, <NUM> or less, <NUM> or less, or <NUM> or less. When a reaction product having the content ratio of water to the acrylic acid within the range is prepared and the acrylic acid is separated from the reaction product by the method according to the present invention, water is effectively separated using less energy and an acrylic acid loss is reduced to increase a recovery rate.

According to an exemplary embodiment of the present invention, a reactor discharge stream including the reaction product may be supplied to a first cooling tower <NUM> and cooled. Specifically, since the reactor discharge stream including the reaction product is discharged in a gas phase, it may be supplied to the first cooling tower <NUM> and condensed. A condensate condensed in this process may be discharged as a lower discharge stream from the first cooling tower <NUM>, and an upper discharge stream from the first cooling tower <NUM> including gaseous components may be supplied to a second cooling tower <NUM>.

A part of the stream of a lower discharge stream from the first cooling tower <NUM> may be refluxed to the first cooling tower <NUM> via a cooler, and the rest of the stream may be supplied to a distillation column <NUM> as a second acrylic acid aqueous solution stream.

The upper discharge stream from the first cooling tower <NUM> may include water, an acrylic acid, and gas components, the second acrylic acid aqueous solution stream may include water and an acrylic acid, and the upper discharge stream from the first cooling tower <NUM> may have a higher content of water and a lower content of the acrylic acid than the second acrylic acid aqueous solution stream.

A content ratio of water to the acrylic acid in the second acrylic acid aqueous solution stream may be for example, <NUM> or more, <NUM> or more, or <NUM> or more and <NUM> or less, <NUM> or less, <NUM> or less, or <NUM> or less. By controlling the composition of the second acrylic acid aqueous solution stream to be within the above range, it may be advantageous in terms of energy and prevention of acrylic acid loss in separation by supplying to the distillation column <NUM> without passing through an extraction column <NUM>.

According to an exemplary embodiment of the present invention, the upper discharge stream from the first cooling tower <NUM> may be supplied to a second cooling tower <NUM>, and the gas components may be removed in the second cooling tower <NUM>. Specifically, the upper discharge stream from the first cooling tower <NUM> supplied to the second cooling tower <NUM> is gaseous components, and may be condensed in the second cooling tower <NUM>. In this process, the condensed condensate may be discharged to the lower portion of the second cooling tower <NUM> as the first acrylic acid aqueous solution stream and supplied to the extraction column <NUM>. Specifically, a part of the first acrylic acid aqueous solution stream may be refluxed to the second cooling tower <NUM> through a cooler and the rest of the stream may be supplied to the extraction column <NUM>.

In addition, in the second cooling tower <NUM>, the gas components may be removed by separation in the upper portion, and the gas components may include acetaldehyde, with water, carbon monoxide, carbon dioxide, and a dilution gas. When the gas components are separated to the upper portion of the second cooling tower <NUM>, a small amount of an acrylic acid may be separated together, and in the present invention, the reaction product including the acrylic acid is separated using two cooling towers, thereby minimizing the content of the acrylic acid which is discharged with the gas components and lost.

The operation temperature of the second cooling tower <NUM> may be <NUM> or higher, <NUM> or higher, or <NUM> or higher and <NUM> or lower, <NUM> or lower, or <NUM> or lower, and the operation pressure may be <NUM>/cm<NUM> or more, <NUM>/cm<NUM> or more, or <NUM>/cm<NUM> or more and <NUM>/cm<NUM> or less, <NUM>/cm<NUM> or less, or <NUM>/cm<NUM> or less. The operation conditions of the second cooling tower <NUM> are controlled to the operation temperature and the operation pressure within the above range, thereby controlling the composition of the gas components separated to the upper portion of the second cooling tower <NUM> to minimize an acrylic acid loss and removing the dilution gas and acetaldehyde out of the system, and controlling the composition of the first acrylic acid aqueous solution stream discharged from the lower portion of the second cooling tower <NUM>.

A content ratio of water to the acrylic acid in the first acrylic acid aqueous solution stream may be, for example, <NUM> or more, <NUM> or more, <NUM> or more, or <NUM> or more and <NUM> or less, <NUM> or less, or <NUM> or less. The composition of the second acrylic acid aqueous solution stream is controlled to be within the above range, thereby controlling the composition of the first acrylic acid aqueous solution stream to an advantageous composition in terms of energy and prevention of acrylic acid loss when separation is performed by supplying to the distillation column <NUM> after passing through the extraction column <NUM>.

According to an exemplary embodiment of the present invention, the first acrylic acid aqueous solution stream is supplied to the extraction column <NUM>, and in the extraction column <NUM>, the acrylic acid and water may be separated using an extractant. Specifically, an extractant may be supplied to the extraction column <NUM>, and the extractant may include one or more selected from the group consisting of, for example, benzene, toluene, xylene, n-heptane, cycloheptane, cycloheptene, <NUM>-heptene, ethylbenzene, methylcyclohexane, n-butylacetate, isobutylacetate, isobutylacrylate, n-propylacetate, isopropylacetate, methylisobutylketone, <NUM>-methyl-<NUM>-heptene, <NUM>-methyl-<NUM>-heptene, <NUM>-methyl-<NUM>-heptene, <NUM>-ethyl-<NUM>-hexene, ethylcyclopentane, <NUM>-methyl-<NUM>-hexene, <NUM>,<NUM>-dimethylpentane, <NUM>-methyl-<NUM>-hexene, and isopropylbutylether. As a specific example, the extractant may be toluene.

In the extraction column <NUM>, the first acrylic acid aqueous solution stream and the extractant are brought into contact and an extract and an extraction residue solution may be separated. For example, the extract may be an acrylic acid dissolved in the extractant, and the extract may be discharged as an upper discharge stream from the extraction column <NUM>. In addition, the extraction residue solution is wastewater including water and may be separated as a lower discharge stream from the extraction column <NUM>. Here, the lower discharge stream from the extraction column <NUM> may include a small amount of an acrylic acid in addition to water, and in the present invention, the reaction product including the acrylic acid is separated into the first acrylic acid aqueous solution stream and the second acrylic acid aqueous solution stream which have advantageous compositions for separation in the distillation column <NUM> and the extraction column <NUM>, respectively, using two cooling towers, and the streams are supplied to the extraction column <NUM> and the distillation column <NUM>, respectively, thereby minimizing an acrylic acid loss included in wastewater and discharged.

According to an exemplary embodiment of the present invention, the upper discharge stream from the extraction column <NUM> and the second acrylic acid aqueous solution stream discharged from the lower portion of the first cooling tower <NUM> may be supplied to the distillation column <NUM>, and components may be separated by distillation.

The upper discharge stream from the extraction column <NUM> and the second acrylic acid aqueous solution stream may form a mixed stream and be supplied to the distillation column <NUM>. The mixed stream having the flow ratio within the range is supplied to the distillation column <NUM>, thereby decreasing the amount of energy used required for separation in the distillation column <NUM>, and separating water and the acrylic acid using the extractant included in the upper discharge stream from the extraction column <NUM> without using an additional azeotropic agent.

In the distillation column <NUM>, the extractant included in the mixed stream may be separated to the upper portion, circulated to the extraction column <NUM>, and reused. In addition, in the distillation column <NUM>, the acrylic acid included in the mixed stream is separated as a lower discharge stream, and water may be separated as a side discharge stream.

The operation temperature of the distillation column <NUM> may be <NUM> or higher, <NUM> or higher, or <NUM> or higher and <NUM> or lower, <NUM> or lower, or <NUM> or lower, and the operation pressure may be <NUM> kPa (<NUM> torr) or more, <NUM> kPa (<NUM> torr) or more, or <NUM> kPa (<NUM> torr) or more and <NUM> kPa (<NUM> torr) or less, <NUM> kPa (<NUM> torr) or less, or <NUM> kPa (<NUM> torr) or less. The operation conditions of the distillation column <NUM> are controlled to the operation temperature and the operation pressure within the above range, thereby effectively separating the extractant from the upper portion, water from the side portion, and the acrylic acid from the lower portion of the distillation column <NUM>.

The lower discharge stream from the distillation column <NUM> may include an acryl and a small amount of by-products. Therefore, if necessary, the lower discharge stream from the distillation column <NUM> is supplied to the refining unit to remove the by-products, thereby obtaining a high-purity acrylic acid.

According to an exemplary embodiment of the present invention, in the method for preparing an acrylic acid, if necessary, devices such as a distillation column, a condenser, a reboiler, a valve, a pump, a separator, a mixer, and the like may be further installed.

Hereinabove, the method for preparing an acrylic acid according to the present invention has been described and illustrated in the drawings, but the description and the illustration in the drawings are the description and the illustration of only core constitutions for understanding of the present invention, and in addition to the process and devices described above and illustrated in the drawings, the process and the devices which are not described and illustrated may be appropriately applied and used for carrying out the method for preparing an acrylic acid according to the present invention.

Hereinafter, the present invention will be described in more detail by the examples. However, the following examples are provided for illustrating the present invention, and it is apparent to a person skilled in the art that various modifications and alterations may be made without departing from the scope of the present invention and the scope of the present invention is not limited thereto.

According to the process flow diagram illustrated in <FIG>, a process of preparing an acrylic acid was simulated, using an Aspen Plus simulator from Aspen Technology, Inc.

Specifically, a lactic acid aqueous solution and nitrogen (N<NUM>) as a dilution gas were supplied to a reactor to prepare a reaction product including an acrylic acid (AA) by a dehydration reaction, and at this time, a content ratio of water to the acrylic acid in the reaction product was adjusted to <NUM>.

The reactor discharge stream including the reaction product was supplied to the first cooling tower <NUM>, a part of the stream of a lower discharge stream from the first cooling tower <NUM> was refluxed to the first cooling tower <NUM> through a cooler, and the rest of the stream, that is, a second acrylic acid aqueous solution stream was supplied to a distillation column <NUM>. At this time, the operation temperature of the first cooling tower <NUM> was controlled to <NUM> in the upper portion and <NUM> in the lower portion, and the operation pressure was controlled to <NUM>/cm<NUM>.

The reactor discharge stream was condensed in the first cooling tower <NUM>, the upper discharge stream from the first cooling tower <NUM> was supplied to a second cooling tower <NUM>, gas components were discharged from the upper portion of the second cooling tower <NUM>, a part of the stream of the lower discharge stream of the second cooling tower <NUM> was refluxed to the second cooling tower <NUM> through the cooler, and the rest of the stream, that is, the first acrylic acid aqueous solution stream, was supplied to the extraction column <NUM>. At this time, the operation temperature of the second cooling tower <NUM> was controlled to <NUM> in the upper portion and <NUM> in the lower portion, and the operation pressure was controlled to <NUM>/cm<NUM>.

In the extraction column <NUM>, toluene was used as an extractant to dissolve the acrylic acid, which was separated as the upper discharge stream from the extraction column <NUM>, and water was separated as the lower discharge stream.

The upper discharge stream from the extraction column <NUM> and the second acrylic acid aqueous solution stream formed a mixed stream and were supplied to the distillation column <NUM>.

In the distillation column <NUM>, the extractant was separated to the upper portion and refluxed to the extraction column <NUM>, and a side discharge stream including water and a lower discharge stream including the acrylic acid were separated.

At this time, a flow rate (kg/hr) for each component in each stream is shown in the following Table <NUM>:.

The total is a value obtained by rounding the value determined in the Aspen Plus simulator to one decimal place.

Referring to Table <NUM>, it was confirmed in Example <NUM> that the content ratio of water to the acrylic acid in the first acrylic acid aqueous solution stream was <NUM>, the content ratio of water to the acrylic acid in the second acrylic acid aqueous solution stream was <NUM>, the amount of acrylic acid loss when gas components were separated to the upper portion of the second cooling tower <NUM> was <NUM>/hr, and the amount of acrylic acid loss when water was removed from the lower portion of the extraction column <NUM> was <NUM>/hr.

In addition, the amount of energy used in the distillation column <NUM> was confirmed to be <NUM> Gcal/hr.

In addition, the recovery rate of the acrylic acid of Example <NUM>, which was calculated by a ratio of the flow rate of the acrylic acid in the lower discharge stream from the distillation column <NUM> to the flow rate of the acrylic acid in the reactor discharge stream, was <NUM>%.

Specifically, a lactic acid aqueous solution was supplied to a reactor to prepare a reaction product including an acrylic acid (AA) by a dehydration reaction, and at this time, a content ratio of water to the acrylic acid in the reaction product was adjusted to <NUM>.

The reactor discharge stream was condensed in the first cooling tower <NUM>, the upper discharge stream from the first cooling tower <NUM> was supplied to a second cooling tower <NUM>, gas components were discharged from the upper portion of the second cooling tower <NUM>, a part of the stream of the lower discharge stream of the second cooling tower <NUM> was refluxed to the second cooling tower <NUM> through the cooler, and the rest of the stream, that is, the first acrylic acid aqueous solution stream was supplied to the extraction column <NUM>. At this time, the operation temperature of the second cooling tower <NUM> was controlled to <NUM> in the upper portion and <NUM> in the lower portion, and the operation pressure was controlled to <NUM>/cm<NUM>.

The upper discharge stream from the extraction column <NUM> and the second acrylic acid aqueous solution stream formed a mixed stream and was supplied to the distillation column <NUM>.

In addition, the recovery rate of the acrylic acid in Example <NUM> was <NUM>%.

A reactor discharge stream including the reaction product was supplied to the cooling tower <NUM>, a part of the lower discharge stream from the cooling tower <NUM> was refluxed to the cooling tower <NUM> through a cooler, the rest of the stream was supplied to an azeotropic distillation column <NUM>, and gas components were discharged from the upper portion of the cooling tower <NUM>. At this time, the operation temperature of the cooling tower <NUM> was controlled to <NUM> in the upper portion and <NUM> in the lower portion, and the operation pressure was controlled to <NUM>/cm<NUM>.

In the azeotropic distillation column <NUM>, toluene was used as an azeotropic agent, the azeotropic agent was separated from the upper discharge stream and refluxed to the azeotropic distillation column <NUM>, water was separated as the remaining stream, and the lower discharge stream including an acrylic acid was separated.

Referring to Table <NUM>, it was confirmed in Comparative Example <NUM> that the content ratio of water to the acrylic acid in the stream supplied to the azeotropic distillation column <NUM> was <NUM>, the amount of acrylic acid loss when the gas components were separated to the upper portion of the cooling tower <NUM> was <NUM>/hr, and the amount of acrylic acid loss when water was removed from the upper portion of the azeotropic distillation column <NUM> was <NUM>/hr.

In addition, the amount of energy used in the azeotropic distillation column <NUM> was confirmed to be <NUM> Gcal/hr.

In addition, the recovery rate of the acrylic acid of Comparative Example <NUM>, which was calculated by a ratio of the flow rate of the acrylic acid in the lower discharge stream from the azeotropic distillation column <NUM> to the flow rate of the acrylic acid in the reactor discharge stream, was <NUM>%.

In this case, it was confirmed that the total amount of the lower discharge stream from the cooling tower <NUM> was supplied to the azeotropic distillation column <NUM> and water and an acrylic acid were azeotropically distilled, thereby increasing the amount of energy used in the azeotropic distillation column <NUM> as compared with Examples <NUM> and <NUM>.

The reactor discharge stream including the reaction product was supplied to the cooling tower <NUM>, a part of the stream of the lower discharge stream from the cooling tower <NUM> was refluxed to the cooling tower <NUM> through a cooler, the rest of the stream was split into a first stream and a second stream, and the first stream was supplied to an extraction column <NUM> and the second stream was supplied to a distillation column <NUM>. In addition, gas components were discharged from the upper portion of the cooling tower <NUM>. At this time, the operation temperature of the cooling tower <NUM> was controlled to <NUM> in the upper portion and <NUM> in the lower portion, and the operation pressure was controlled to <NUM>/cm<NUM>.

The upper discharge stream from the extraction column <NUM> was supplied to the distillation column <NUM> with the second stream, an extractant was separated to the upper portion in the distillation column <NUM> and refluxed to the extraction column <NUM>, and a side discharge stream including water and a lower discharge stream including an acrylic acid were separated.

Referring to Table <NUM>, it was confirmed in Comparative Example <NUM> that the content ratios of water to the acrylic acid in the stream supplied to the extraction column <NUM> and the stream supplied to the azeotropic distillation column <NUM> were the same at <NUM>, the amount of acrylic acid loss when the gas components were separated to the upper portion of the cooling tower <NUM> was <NUM>/hr, and the amount of acrylic acid loss when water was removed from the upper portion of the extraction column <NUM> was <NUM>/hr.

In addition, the recovery rate of the acrylic acid of Comparative Example <NUM>, which was calculated by a ratio of the flow rate of the acrylic acid in the lower discharge stream from the distillation column <NUM> to the flow rate of the acrylic acid in the reactor discharge stream, was <NUM>%.

Claim 1:
A method for preparing an acrylic acid, the method comprising:
supplying a lactic acid aqueous solution to a reactor and performing a dehydration reaction to prepare a reaction product including an acrylic acid;
supplying a reactor discharge stream including the reaction product to a first cooling tower and supplying an upper discharge stream from the first cooling tower to a second cooling tower;
supplying a first acrylic acid aqueous solution stream discharged from a lower portion of the second cooling tower to an extraction column;
supplying an upper discharge stream from the extraction column and a second acrylic acid aqueous solution stream discharged from a lower portion of the first cooling tower to a distillation column; and
separating the acrylic acid from a lower discharge stream from the distillation column.