KR100836733B1 - Method to withdrawal of sodium hyaluronate and therefor device - Google Patents

Abstract

The present invention relates to a method for recovering sodium hyaluronate and a device therefor, to which the present invention comprises the steps of simultaneously introducing and mixing the aqueous hyaluronic acid solution and an organic solvent; Generating a precipitate from the mixed liquor; Recovering the precipitate while allowing the mixed solution to pass through the recovery network; Sediment passing through the recovery network is discharged, and the recovery method and recovery device comprising the step of injecting air to the precipitate filtered through the recovery network and to recover the device to minimize the amount of work while preventing contamination regardless of the hyaluronic acid throughput and molecular weight It is to be able to recover a high yield of sodium hyaluronate continuously.

Sodium hyaluronate, precipitation, organic solvent, ethanol, recovery system

Description

Method for recovering sodium hyaluronate and device therefor {Method to withdrawal of sodium hyaluronate and therefor device}             

1 is a block diagram showing a recovery process of sodium hyaluronate according to the present invention,

Figure 2 is a schematic structural diagram showing a recovery apparatus of sodium hyaluronate in accordance with the present invention.

Explanation of symbols on the main parts of the drawings

10: supply part 20: mixing part

21: confluence pipe 22: branch pipe

30: sedimentation part 40: recovery part

41: recovery network

The present invention relates to a method for recovering sodium hyaluronate and a device therefor, and more particularly, to a method for recovering sodium hyaluronate and a device therefor for continuously generating and recovering sodium hyaluronate in high yield during a process. will be.

In general, sodium hyaluronate is a biopolymer widely distributed in animal buffer tissue, chicken rice, cow's eye, placenta, skin, etc., and has a lubricating effect against physical friction, a protective effect against bacterial invasion, and a moisturizing property. Therefore, sodium hyaluronate is widely used as a functional cosmetic additive, an ophthalmic surgical aid, and a treatment for recurrent arthritis.

The sodium hyaluronate is mainly used an organic solvent to purify the sodium hyaluronate in aqueous solution at the time of purification, the representative organic solvent is ethanol, methanol, isopropyl alcohol, acetone and the like. However, there is no problem in the case of small quantity production, but in the case of mass production, there is a problem that the size of the sedimentation tank grows at the same time. It becomes heavy.

Japanese Patent Laid-Open No. 2-142801 proposed an apparatus for precipitating, recirculating, and stirring ethanol and sodium hyaluronate, but as the production scale increases, the settling tank and agitation apparatus also need to grow at the same time, especially when stirring using an impeller. Since sodium hyaluronate is stuck to the impeller and is not easy to recover, there is a disadvantage in that the labor load of the worker is increased and the occurrence of contamination is relatively increased.

In contrast, in Korean Patent Application No. 96-340, ethanol is introduced into an aqueous solution of sodium hyaluronate and an organic solvent into a sedimentation tank with a baffle, and sodium hyaluronate is precipitated while shaking with a shaker. A device for recovering sodium hyaluronate has been proposed. However, even in this case, the loss of sodium hyaluronate from the sediment discharge valve cannot be prevented, and there is still a possibility of contamination through the discharge line.

Meanwhile, Korean Patent Application No. 97-7052 proposed an apparatus for recovering sodium hyaluronate, which exits through the sediment discharge valve, through a recovery network. However, even in this case, when sedimentation of a large amount of sodium hyaluronate occurs, the precipitation is recovered in two places, a sedimentation tank and a recovery tank, which leads to an increase in labor and contamination during recovery, as well as a larger shaker as the sedimentation device becomes larger. There is a problem that the energy cost is increased by increasing the volume of the device.

Accordingly, the present invention has been invented to solve the above-mentioned disadvantages and problems of the prior art, and an object of the present invention is to minimize the size of the device through the continuous generation of sodium hyaluronate precipitate, and to reduce the amount of work and minimize the occurrence of contamination. To recover hyaluronic acid.

In order to achieve the above object, the present invention comprises the steps of mixing the aqueous hyaluronic acid solution and the organic solvent at the same time; Generating a precipitate from the mixed liquid; Recovering the precipitate while allowing the mixed solution to pass through the recovery network; It provides a method for recovering sodium hyaluronate comprising the step of discharging the precipitate passing through the recovery network, by injecting air into the precipitate filtered through the recovery network.

And in order to recover the sodium hyaluronate, the present invention is a supply unit for supplying a hyaluronic acid aqueous solution and an organic solvent in a predetermined ratio; A mixing unit for mixing the hyaluronic acid aqueous solution and an organic solvent; Precipitating unit for passing the mixed liquid mixed in the mixing unit in a spiral flow path to generate a precipitate; A recovery apparatus for introducing the mixed liquid from the precipitation unit to recover sodium hyaluronate through a recovery network, allowing the remaining mixed liquid to be discharged through the discharge port, and performing recovery as a recovery unit for injecting air into the recovered sodium hyaluronate and drying it; to provide.

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

Recovery of sodium hyaluronate according to the present invention is first mixed with the aqueous solution of hyaluronic acid and the organic solvent in a predetermined ratio as shown in Figure 1 (S1), so that the precipitate is produced while passing the mixed liquid mixture (S2) (S2) ). The mixed liquid containing the precipitate produced in the above step is to pass through the recovery network to filter only the precipitate (S3), and other mixed liquid is to be discharged, and the precipitate filtered by the recovery network is injected by air to dry (S4) to be performed as a process.

In this case, the mixing ratio of the aqueous hyaluronic acid solution and the organic solvent is 1: 1.5 to 4, and the organic solvent is added to produce a precipitate using ethanol, acetone, isopropyl alcohol or a mixed solvent thereof.

As described above, the present invention continuously supplies the aqueous hyaluronic acid solution and the organic solvent at a predetermined ratio so that the precipitation and recovery of the hyaluronic acid can be continuously performed.

Meanwhile, the apparatus for recovering sodium hyaluronate according to the present invention is largely composed of a supply part 10, a mixing part 20, a precipitation part 30 and a recovery part 40 as shown in FIG.

The supply part 10 is comprised from each supply pipe 11 which supplies a hyaluronic acid aqueous solution and an organic solvent, and the supply valve 12 provided in these supply pipes 11, The mixing part 20 supplies the supply part 10, and Hyaluronic acid solution supplied through the organic solvent and the flow path configuration to be properly mixed. That is, the mixing section 20 forms a confluence pipe 21 having a predetermined length so that each of the supply pipes 11 on the supply part 10 side joins, and separates the confluence pipe 21 into two pipes again. (22) is a configuration that allows the mixed liquid to pass through the joining pipe 21 and the branch pipe 22 two to ten times in a manner to form a joining pipe 21 by bringing them together again into a single pipe. .

When the mixed solution between the aqueous hyaluronic acid solution and the organic solvent is repeatedly mixed and separated several times, the mixing efficiency between these liquids becomes very good.

Precipitator 30 is a configuration that allows the mixture to pass through the mixing portion 20 while passing through the pipe formed in a spiral to delay the flow time for a certain time to produce a precipitate. That is, the precipitation unit 30 is to allow the precipitate 30 to be generated while allowing the mixed liquid induced in the mixing unit 20 to flow through the spiral tube for a predetermined time.

On the other hand, the recovery section 40 is provided with a recovery network 41 for passing the mixed liquid introduced through the settling section 30 to filter the sediment in the mixed liquid, the mixed liquid with the precipitate filtered through the recovery network 41 It is the structure which formed the discharge port 42 which discharges this. In addition, the precipitate filtered by the recovery network 41 includes a configuration to be dried by the air injected through the air inlet (43).

As a preferred embodiment in the above configuration, the hyaluronic acid supply pipe 11 of the supply unit 10 is about 3 to 15 mm in diameter, the organic solvent supply pipe 11 is about 4 to 20 mm in diameter, and in the mixing unit 20 The diameter of the confluence pipe 21 is 5-30mm, the diameter of the branch pipe 22 is formed as about 4-20mm, and these supply part 10 and the mixing part 20 are made of stainless steel or silicone material. To be done.

The angle between the pipes separated from the confluence pipe 21 in the branch pipe 22 of the mixing section 20 is 20 to 50 °, and between the pipes branched from the confluence pipe 21 to the branch pipe 22. The angle of 20-40 degrees is preferable.

In addition, the spiral tube in the precipitation section 30 is made of stainless steel or silicon material of about 5 ~ 30mm in diameter, 1 ~ 4m in length, it is preferable to have a configuration having a spiral flow path of 3 to 5 times. Do.

In particular, the recovery portion 40 is made of a cylindrical stainless steel having a diameter of about 200 to 500 mm, a height of about 300 to 600 mm, the recovery network 41 in the recovery portion 40 is made of stainless steel, The pore size of the recovery network 41 is appropriately about 200 ~ 1000㎛.

In the above-described configuration, when the aqueous hyaluronic acid solution and the organic solvent are mixed at a ratio of 1: 1.5 to 4, 8 to 9.5 g of sodium hyaluronate can be recovered per 10 liters of the aqueous hyaluronic acid solution (0.1%, w / v).

Meanwhile, according to the type of organic solvent mixed with the aqueous hyaluronic acid solution in the above-described embodiment, sodium hyaluronate can be recovered as follows.

That is, about 165 minutes are required to process 50 liters of aqueous hyaluronic acid solution (0.1%, w / v) by supplying ethanol (95%) at 300 mL / min and 600 mL / min to the aqueous hyaluronic acid solution (1%), respectively. The recovery rate is about 94%, since about 47g of sodium hyaluronate is recovered.

If 300 ml / min and 900 ml / min of acetone is supplied to the aqueous hyaluronic acid solution instead of ethanol, the recovery rate is about 90% because the same 50 liters of the aqueous hyaluronic acid solution (0.1%, w / v) can be recovered. Becomes

On the other hand, 25 liters of sodium hyaluronate was recovered when low molecular weight aqueous solution of hyaluronic acid (0.2%, w / v) and ethanol were supplied at 300 mL / min and 900 mL / min, respectively. Will be%.

As can be seen from these results, the present invention achieves a recovery rate of about 80% to 95% without adding unnecessary labor by an operator while maintaining aseptic state of various molecular weight sodium hyaluronate using various organic solvents. You can do it.

As described above, in the present invention, while mixing the hyaluronic acid aqueous solution and the organic solvent at an appropriate ratio, the confluence pipe 21 and the branch pipe 22 are repeatedly passed through several times to increase the mixing efficiency, and the mixed solution is made of a spiral tube again. While passing through the settling section 30 to continuously produce and recover sodium hyaluronate of various molecular weight through the recovery section 40 to have a high yield recovery and high recovery rate.

In particular, the present invention provides a very economical advantage of minimizing the size of the equipment while minimizing contamination and minimizing energy and labor consumption.

Claims (8)

Mixing the aqueous hyaluronic acid solution and the organic solvent in a ratio of 1: 1.5 to 4; Passing the mixed liquid through a spiral flow path to produce a precipitate; Recovering the precipitate by passing the mixed solution through a recovery network having a pore size of 200 to 1000 µm; And discharge the precipitate passing through the recovery network, and injecting air into the precipitate filtered through the recovery network; The organic solvent is a method of recovering sodium hyaluronate containing ethanol, acetone, isopropyl alcohol or a mixed solvent thereof. The method for recovering sodium hyaluronate according to claim 1, wherein the organic solvent is made of ethanol. The method for recovering sodium hyaluronate according to claim 1, wherein the organic solvent is made of acetone. delete delete A supply unit for supplying an aqueous hyaluronic acid solution and an organic solvent in a ratio of 1: 1.5 to 4; A mixing unit mixing the hyaluronic acid aqueous solution and an organic solvent; Precipitating unit for passing the mixed solution mixed in the mixing unit in a spiral flow path to generate a precipitate; And Recovery section connected to the settling section Including, The recovery unit has a pore size of 200 ~ 1000㎛ recovery network for recovering the sodium hyaluronate by flowing the mixed liquid from the precipitation unit, and A discharge port for discharging the remaining mixed liquid in which the hyaluronic acid aqueous solution is excluded from the mixed liquid Including, The recovered sodium hyaluronate is blown with air and dried, The organic solvent is a sodium hyaluronate recovery device comprising ethanol, acetone, isopropyl alcohol or a mixed solvent thereof. 7. The apparatus for recovering sodium hyaluronate according to claim 6, wherein the mixing unit comprises a conduit pipe for merging two pipes into one tube and a branch pipe for dividing the pipe into two pipes from the conduit pipe two to ten times. . The apparatus for recovering sodium hyaluronate according to claim 6, wherein the precipitation part is formed by rotating the spiral tube 3 to 5 times.

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