KR102631642B1 - Spray drying system and spray drying method - Google Patents

Abstract

The spray drying system of the present invention includes a drying device that sprays liquid raw materials and mixes the sprayed raw materials with a drying gas to dry the raw materials; a collection device connected to the drying device, separating the product dried from the raw material and the remaining gas, collecting the product, and discharging the remaining gas; a foreign matter removal device connected to the collection device, removing foreign matter contained in the gas discharged from the collection device, and discharging remaining gas; an exhaust gas condensation device connected to the foreign matter removal device and condensing gas discharged from the foreign matter removal device; and a volatile substance recovery device connected to the exhaust gas condensation device, removing moisture contained in the condensed solution, and recovering volatile substances contained in the condensed solution.

Description

Spray drying system and spray drying method {Spray drying system and spray drying method}

The present invention relates to a spray drying system and a spray drying method, and more specifically, to a spray drying system and a spray drying method that can be used to convert liquid raw materials into powder form by spraying them inside a chamber and drying them with high-temperature and high-pressure air. will be.

Unless otherwise indicated herein, the material described in this section is not prior art to the claims of this application, and is not admitted to be prior art by inclusion in this section.

In general, spray drying is a method used to produce particles of various sizes, including micro particles, and particles dried by spraying are useful in many biomedical and pharmaceutical applications.

In particular, the spray drying method is mainly used to produce particles used in many fields, and can be used to manufacture food, cosmetics, fertilizers, dyes, and abrasives.

A typical process for making particles using a spray drying process is to create a solution by dissolving a solid forming material such as a polymer in an appropriate solvent to create bulk of particles. The solution is sprayed to form fine mist droplets. Next, the microdroplets are introduced into the drying chamber and come into contact with the drying gas. In the dry gas, the fine droplets solidify to form particles after the solvent evaporates. Next, the particles are separated from the dry gas and collected.

The gas discharged during this spray drying process may contain volatile substances. If these volatile substances are emitted into the atmosphere, they may cause environmental problems. In addition, during the spray drying process, the product may be oxidized as the particles are oxidized by moisture contained in the drying gas.

Republic of Korea Patent Publication No. 2018-0080285

An object of the present invention is to provide a spray drying system and a spray drying method that can prevent volatile substances from being released.

A spray drying system according to one aspect of the present invention includes a drying device that sprays a liquid raw material and mixes the sprayed raw material with a drying gas to dry the raw material; a collection device connected to the drying device, separating the product dried from the raw material and the remaining gas, collecting the product, and discharging the remaining gas; a foreign matter removal device connected to the collection device, removing foreign matter contained in the gas discharged from the collection device, and discharging remaining gas; an exhaust gas condensation device connected to the foreign matter removal device and condensing gas discharged from the foreign matter removal device; and a volatile substance recovery device connected to the exhaust gas condensation device, removing moisture contained in the condensed solution, and recovering volatile substances contained in the condensed solution.

Meanwhile, a moisture removal device that removes moisture contained in external air supplied to the drying device may be further included.

Meanwhile, the moisture removal device includes a flow measurement line that measures the flow rate of air flowing in from the outside; a dry air supply line connected to the flow measurement line and supplying air to the drying device; and one or more moisture absorbing members installed on the dry air supply line.

Meanwhile, it may include a first circulation line that connects the exhaust gas condensation device and the drying device and transfers gas other than the solution condensed in the exhaust gas condensation device to the drying device.

Meanwhile, it may include a second circulation line that connects the volatile material recovery device and the exhaust gas condensation device and transfers the remaining gas of the volatile material recovery device to the exhaust gas condensation device.

Meanwhile, it may further include an oxygen concentration measuring member installed on the first circulation line to measure the concentration of oxygen contained in the gas transported along the first circulation line.

Meanwhile, the volatile material recovery device can increase the concentration of the volatile solution by removing moisture contained in the condensed solution using a pervaporation method.

The spray drying method according to one aspect of the present invention includes a drying step of drying the raw material; A collection step of collecting the dried product from the raw material in the drying step; A foreign matter removal step of removing foreign substances contained in the gas discharged in the collection step; An exhaust gas condensation step of condensing the gas discharged in the foreign matter removal step; and a volatile material recovery step of receiving the solution condensed in the exhaust gas condensation step, removing moisture, and recovering volatile materials.

Meanwhile, in the volatile material recovery step, the concentration of the volatile solution can be increased by removing moisture contained in the condensed solution by pervaporation.

Meanwhile, a dry air generating step of removing moisture from the gas used for drying the raw material may be further included.

The spray drying method according to one aspect of the present invention includes a drying step of drying the raw material; A collection step of collecting the dried product from the raw material in the drying step; A foreign matter removal step of removing foreign substances contained in the gas discharged in the collection step; An exhaust gas condensation step of condensing the gas discharged in the foreign matter removal step; and a volatile material recovery step of receiving the solution condensed in the exhaust gas condensation step, removing moisture, and recovering volatile materials.

Meanwhile, in the volatile material recovery step, the concentration of the volatile solution can be increased by removing moisture contained in the condensed solution by pervaporation.

Meanwhile, a dry air generating step of removing moisture from the gas used for drying the raw material may be further included.

A spray drying system according to one embodiment of the present invention includes a volatile material recovery device. A volatile substance recovery device recovers volatile substances contained in the condensed solution.

This volatile material recovery device can increase the purity of volatile materials that could otherwise be discarded so that they can be reused. Additionally, the volatile material recovery device not only prevents alcohol from being released into the atmosphere, but also allows volatile materials such as alcohol to be obtained and reused without additional costs.

Additionally, the spray drying system according to the present invention includes a moisture removal device. Moisture removal devices remove moisture contained in outside air. Dry air from which moisture has been removed may be supplied to the drying device. Therefore, it is possible to prevent the raw materials from being oxidized by contact with moisture during the drying process. Therefore, the spray drying system according to the present invention can improve the quality of the final product manufactured compared to the product manufactured with a conventional spray drying system.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a configuration diagram showing a spray drying system according to an embodiment of the present invention.
Figure 2 is a configuration diagram showing a spray drying system according to another embodiment of the present invention.
Figure 3 is a block diagram showing an excerpt of a moisture removal device.
Figure 4 is a flow chart showing a spray drying method according to an embodiment of the present invention.
Figure 5 is a flow chart showing a spray drying method according to another embodiment of the present invention.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily practice the present invention. The invention may be implemented in many different forms and is not limited to the embodiments described herein.

In order to clearly explain the present invention, parts that are not relevant to the description are omitted, and identical or similar components are assigned the same reference numerals throughout the specification.

Additionally, in various embodiments, components having the same configuration will be described using the same symbols only in the representative embodiment, and in other embodiments, only components that are different from the representative embodiment will be described.

Throughout the specification, when a part is said to be “connected” to another part, this includes not only “directly connected” but also “indirectly connected” through another member. Additionally, when a part “includes” a certain component, this means that it may further include other components rather than excluding other components, unless specifically stated to the contrary.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the technical field to which the present invention pertains. Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and unless explicitly defined in the present application, should not be interpreted in an ideal or excessively formal sense. No.

Referring to Figure 1, the spray drying system 100 according to an embodiment of the present invention includes a drying device 110, a collection device 120, a foreign matter removal device 130, an exhaust gas condensation device 140, and a volatile material Includes a recovery device (150).

The drying device 110 sprays liquid raw materials and mixes the sprayed raw materials with a drying gas to dry the raw materials. The drying device 110 for this may include a vacuum drying chamber 111, a heater 112, a storage tank 113, a supply pump 115, and a sprayer 114. The sprayer 114 may be, for example, a pressure nozzle, compressed air nozzle, sonic nozzle, or rotary nozzle, but is not limited thereto.

The vacuum drying chamber 111 is a part where raw materials and drying gas are mixed. The heater 112 heats the drying gas supplied to the vacuum drying chamber 111. The vacuum drying chamber 111 can produce finely powdered products by rapidly diffusing liquid raw materials sprayed with high-pressure and high-temperature drying gas into the internal space in small amounts.

The heater 112 can heat the drying gas to the target temperature. Here, the target temperature is a temperature that is sufficient to dry the raw material. The target temperature may be 200 degrees or more, but may vary depending on the design of the drying device 110, so it is not limited to a specific temperature.

The storage tank 113 can mix and store raw materials. The raw spray solution may contain drugs and polymers dissolved in a solvent. The substance used as a solvent may be, for example, a volatile substance such as alcohol, but is not limited thereto.

The supply pump 115 may be installed between the vacuum drying chamber 111 and the storage tank 113. The supply pump 115 can pump raw materials and supply them to the vacuum drying chamber 111.

The sprayer 114 may be installed on the upper side of the vacuum drying chamber 111. The sprayer 114 can receive raw materials from the storage tank 113 by the supply pump 115 and spray them into the inside of the vacuum drying chamber 111. At this time, the drying gas heated by the heater 112 may be sprayed around the sprayer 114.

Thereafter, the solvent is evaporated in the vacuum drying chamber 111, thereby producing solid amorphous dispersion particles of the drug and polymer. The solid amorphous dispersion particles and discharged drying gas (cooled drying gas and evaporated solvent) may be discharged through the bottom of the vacuum drying chamber 111.

The collection device 120 is connected to the drying device 110 and separates the dried product from the raw materials and the remaining gas. Collection device 120 collects the product and exhausts the remaining gas.

The collection device 120 for this may be, for example, a centrifugal force dust collector (Cyclone). A centrifugal force dust collector may be a device that removes gas and dust by using the difference between centrifugal force and inertial force without using other devices such as filters, water, or electricity. A detailed description of the collection device 120 as described above will be omitted. The raw material is discharged from the bottom of the collection device 120 in powder form, and the remaining gas may be transferred to the foreign matter removal device 130, which will be described later.

The foreign matter removal device 130 is connected to the collection device 120, removes foreign materials included in the gas discharged from the collection device 120, and discharges remaining gas. A forced circulation fan (F) is installed between the foreign matter removal device 130 and the exhaust gas condensation device 140, which will be described later, to prevent gas from flowing back into the foreign matter removal device 130.

The exhaust gas condensation device 140 is connected to the foreign matter removal device 130 and condenses the gas discharged from the foreign matter removal device 130. The exhaust gas condensation device 140 may separate volatile substances from the exhaust gas discharged from the foreign matter removal device 130.

This exhaust gas condensation device 140 uses a cooler 141 to cool the dry gas and remove the solvent. The condensed condensate may be transferred to a volatile material recovery device 150, which will be described later, through a drain at the bottom of the exhaust gas condensation device 140.

The volatile material recovery device 150 is connected to the exhaust gas condensation device 140 and removes moisture contained in the condensed solution. The volatile material recovery device 150 recovers volatile materials contained in the condensed solution. This volatile material recovery device 150 can increase the concentration of the volatile solution by removing moisture contained in the condensed solution using a pervaporation method.

Pervaporation is a method of separating alcohol and water using the separation characteristics of a membrane. The temperature and pressure of the condensed solution that can be set in the pervaporation method may vary depending on the design of the volatile material recovery device 150, and are not limited to specific values. And, the membrane used in the pervaporation method may be a membrane used to separate alcohol and water.

As described above, the substance that can be used in the spray drying system 100 according to an embodiment of the present invention may be alcohol, and the volatile substance recovery device 150 removes moisture contained in the alcohol discharged after use to provide high purity. of alcohol can be recovered. The recovered alcohol may be reused in the spray drying system 100 according to an embodiment of the present invention, or may be used for a separate purpose.

In the case of a spray drying system in which the volatile material recovery device 150 is not installed, the condensed volatile material is generally discarded due to its low purity. As described above, the volatile material recovery device 150 can increase the purity of volatile materials that could otherwise be discarded so that they can be reused. In addition, the volatile material recovery device 150 can not only prevent alcohol from being released into the atmosphere, but can also obtain and reuse volatile materials such as alcohol without additional costs.

Meanwhile, the spray drying system 100 according to an embodiment of the present invention may include a first circulation line (C1).

The first circulation line (C1) connects the exhaust gas condensation device 140 and the drying device 110, and supplies gas other than the solution condensed in the exhaust gas condensation device 140 to the drying device 110. It can be transported.

The spray drying process performed in the spray drying system 100 according to an embodiment of the present invention may require a large amount of drying gas. The first circulation line C1 may re-supply the gas discharged from the exhaust gas condensation device 140 to the drying device 110. Additionally, the spray drying system 100 according to an embodiment of the present invention may implement a closed loop that does not communicate with the outside, including the first circulation line C1.

Meanwhile, the spray drying system 100 according to an embodiment of the present invention may include a second circulation line (C2).

The second circulation line (C2) connects the volatile material recovery device 150 and the exhaust gas condensation device 140, and transfers the remaining gas of the volatile material recovery device 150 to the exhaust gas condensation device 140. It can be transported. Accordingly, the second circulation line C2 can enable the spray drying system 100 according to an embodiment of the present invention to be implemented as a closed loop.

Meanwhile, the spray drying system 100 according to an embodiment of the present invention may further include an oxygen concentration measuring member 170.

The oxygen concentration measuring member 170 is installed on the first circulation line (C1) and can measure the concentration of oxygen contained in the gas transported along the first circulation line (C1). The oxygen concentration measuring member 170 may transmit the measured oxygen concentration to a monitoring device. Users can check oxygen levels by checking the monitoring device.

The air in the first circulation line C1 may be supplied to the drying device 110 and heated by the heater 112. When the user determines that the oxygen concentration of the air in the first circulation line C1 is close to a value that can cause a fire, the user may stop the operation of the spray drying system 100.

In this way, the oxygen concentration measuring member 170 allows the user to easily monitor the oxygen concentration of the air in the first circulation line C1, thereby preventing fires from occurring and safety accidents from occurring. .

As described above, the spray drying system 100 according to an embodiment of the present invention includes a volatile material recovery device 150. The volatile material recovery device 150 recovers volatile materials contained in the condensed solution.

This volatile material recovery device 150 can increase the purity of volatile materials that could otherwise be discarded so that they can be reused. Not only can it prevent alcohol from being released into the atmosphere, but it can also obtain and reuse volatile substances such as alcohol without spending any extra money.

Hereinafter, a spray drying method for drying raw materials using the spray drying system described above will be described with reference to the drawings.

Referring to Figure 4, the spray drying method (S100) according to an embodiment of the present invention includes a drying step (S110), a collection step (S120), a foreign matter removal step (S130), an exhaust gas condensation step (S140), and a volatile material Includes a recovery step (S150).

In the drying step (S110), the raw materials are dried. The drying step (S110) may be performed in the drying device described above.

The collection step (S120) collects the product dried from the raw materials in the drying step (S110). The collection step (S120) may be performed in the above-described collection device.

The foreign matter removal step (S130) removes foreign materials included in the gas discharged in the collection step (S120). The foreign matter removal step (S130) may be performed in the foreign matter removal device described above.

The exhaust gas condensation step (S140) condenses the gas discharged in the foreign matter removal step (S130). The exhaust gas condensation step (S140) may be performed in an exhaust gas condensation device.

The volatile material recovery step (S150) receives the solution condensed in the exhaust gas condensation step (S140), removes moisture, and recovers volatile materials. In the volatile material recovery step (S150), the concentration of the volatile solution can be increased by removing moisture contained in the condensed solution by pervaporation. This volatile material recovery step (S150) may be performed in a volatile material recovery device.

Referring to Figures 2 and 3, the spray drying system 200 according to another embodiment of the present invention may further include a moisture removal device 160.

The moisture removal device 160 can remove moisture contained in external air supplied to the drying device 110. The moisture removal device 160 for this may include, for example, a flow measurement line 161, a dry air supply line 162, and one or more moisture absorption members 163.

The flow measurement line 161 can measure the flow rate of air flowing in from the outside.

The dry air supply line 162 is connected to the flow measurement line 161 and can supply air to the drying device 110. The input terminals of the dry air supply line 162 and the flow measurement line 161 may be connected to each other. Air flows in from the outside through one inlet (H) and can be transferred to the dry air supply line 162 and the flow measurement line 161, respectively.

The moisture absorbing member 163A is installed on the dry air supply line 162 and can remove moisture contained in the air introduced into the moisture removal device 160. Meanwhile, the moisture absorption member 163B may also be installed on the flow measurement line 161.

There may be a plurality of such moisture absorbing members 163. A plurality of moisture absorbing members 163 may be disposed at regular intervals on the dry air supply line 162.

Meanwhile, the moisture removal device 160 may include one or more valves V1 and V2. One valve (V1) may be installed in the inlet (H), and the other valve (V2) may be installed in the dry air supply line (162). The valves V1 and V2 may control the flow of gas transported through the moisture removal device 160.

The operation process of the moisture removal device 160 as described above will be described. Air is supplied from the outside through the inlet (H) and can be divided into a flow measurement line 161 and a dry air supply line 162.

A flow meter may be installed on the flow measurement line 161 to measure the amount of air supplied. Additionally, the moisture contained in the external air is removed while passing through the plurality of moisture absorption members 163A and 163B, and the dry air from which the moisture has been removed can be supplied to the drying device 110.

At this time, the moisture removal device 160 may purge oxygen and supply it to the drying device 110. Accordingly, it is possible to prevent an explosion caused by oxygen contained in the dry air as the dry air is heated by the heater 112.

Meanwhile, the moisture removal device 160 may be connected to the above-described first circulation line (C1). That is, external air may be supplied to the first circulation line C1 with moisture removed, and dry air with moisture removed may be supplied to the drying device 110.

Accordingly, the moisture removal device 160 can prevent the raw material from being oxidized by contact with moisture during the drying process. Therefore, the spray drying system 200 according to another embodiment of the present invention can improve the quality of the final product manufactured compared to the product manufactured by the conventional spray drying system.

Referring to FIG. 5, the spray drying method (S200) according to another embodiment of the present invention may further include a dry air generating step (S160).

The dry air generation step (S160) can remove moisture from the gas used to dry the raw materials. The dry air generating step (S160) may be performed in the moisture removal device described above.

As described above, each step of the spray drying method (S200) has been described in detail while explaining the spray drying system (200, see FIG. 2), so detailed description thereof will be omitted.

Although several embodiments of the present invention have been described above, the drawings and detailed description of the invention referred to so far are merely illustrative of the present invention, which are used only for the purpose of explaining the present invention and are not intended to limit the meaning or apply for patent claims. It is not used to limit the scope of the present invention described in the scope. Therefore, those skilled in the art will understand that various modifications and other equivalent embodiments are possible therefrom. Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the appended claims.

100, 200: Spray drying system
110: drying device
120: collection device
130: Foreign matter removal device
140: exhaust gas condensation device
150: Volatile material recovery device
160: Moisture removal device
161: flow measurement line
162: Dry air supply line
163: Absence of moisture absorption
170: Absence of oxygen concentration measurement
C1: first circulation line
C2: second circulation line

Claims (10)

A drying device that sprays liquid raw materials and mixes the sprayed raw materials with a drying gas to dry the raw materials;
a collection device connected to the drying device, separating the product dried from the raw material and the remaining gas, collecting the product, and discharging the remaining gas;
a foreign matter removal device connected to the collection device, removing foreign matter contained in the gas discharged from the collection device, and discharging remaining gas;
an exhaust gas condensation device connected to the foreign matter removal device and condensing gas discharged from the foreign matter removal device;
a volatile substance recovery device connected to the exhaust gas condensation device, removing moisture contained in the condensed solution, and recovering volatile substances contained in the condensed solution; and
It includes a moisture removal device that removes moisture contained in the external air supplied to the drying device,
The moisture removal device,
A flow measurement line that measures the flow rate of air flowing in from the outside;
a dry air supply line connected to the flow measurement line and supplying air to the drying device; and
It includes one or more moisture absorbing members installed on the dry air supply line,
It is connected through a valve to a first circulation line that communicates with the drying device and the exhaust gas condensation device, and purges oxygen from the external air to supply dry air from which moisture has been removed from the external air to the drying device through the first circulation line. supply,
The volatile material recovery device,
A closed loop is formed with the exhaust gas condensation device through a second circulation line to separate the condensed solution supplied from the exhaust gas condensation device into water and volatile substances, and then the water and volatile substances are supplied to the outside to recover the volatile substances. A spray drying system that removes and transfers residual gas inside to the exhaust gas condensation device. delete delete delete delete According to paragraph 1,
A spray drying system further comprising an oxygen concentration measuring member installed on the first circulation line to measure the concentration of oxygen contained in the gas transported along the first circulation line. delete In the spray drying method of drying raw materials with the spray drying system according to any one of claims 1 and 6,
A drying step of drying the raw materials;
A collection step of collecting the dried product from the raw material in the drying step;
A foreign matter removal step of removing foreign substances contained in the gas discharged in the collection step;
An exhaust gas condensation step of condensing the gas discharged in the foreign matter removal step; and
A spray drying method comprising a volatile material recovery step of receiving the solution condensed in the exhaust gas condensation step and removing moisture to recover volatile materials. According to clause 8,
In the volatile material recovery step, a spray drying method that increases the concentration of the volatile solution by removing moisture contained in the condensed solution by pervaporation. According to clause 8,
Spray drying method further comprising: generating dry air to remove moisture from the gas used for drying the raw material.

Images