KR102622674B1 - Gelatin chiller module capable of manufacturing sophisticated soft capsules and soft capsule forming device including the same - Google Patents

Abstract

A gelatin chiller module capable of manufacturing sophisticated soft capsules through uniform cooling of gelatin and a soft capsule molding device including the same are provided.
The gelatin chiller module according to one aspect of the present invention is a cooling drum configured to receive gelatin from a gelatin supply module, apply gelatin to the outer surface, and have a coolant flow space inside where coolant can circulate to cool the gelatin. and a cooling water circulation unit having a cooling circulation passage configured to guide circulation of the cooling water flowing into the cooling water flow space in the cooling drum.

Description

Gelatin chiller module capable of manufacturing sophisticated soft capsules and soft capsule forming device including the same {GELATIN CHILLER MODULE CAPABLE OF MANUFACTURING SOPHISTICATED SOFT CAPSULES AND SOFT CAPSULE FORMING DEVICE INCLUDING THE SAME}

The present invention relates to a gelatin chiller module and a soft capsule molding device including the same. More specifically, it relates to a gelatin chiller module capable of manufacturing sophisticated soft capsules through uniform cooling of gelatin and a soft capsule molding device including the same. .

The soft capsule manufacturing device is a device that manufactures various types of gelatin soft capsules for easy ingestion of drugs or health functional ingredients contained in the liquid content.

In a typical soft capsule manufacturing device, molten gelatin is discharged from a spreader box and supplied to a frozen molding drum, and the gelatin applied to the frozen molding drum is molded into a sheet. This sheet-shaped gelatin is supplied to the point where the content injection segment and die roll intersect through a plurality of transfer rollers.

Meanwhile, the content liquid is supplied from the hopper to the nozzle in the content injection segment through a transfer hose and is encapsulated in gelatin in the form of a capsule at the end of the segment. At this time, in order to stably encapsulate the contents within the gelatin sheet, precise manufacturing of the gelatin sheet is first required.

However, the conventional soft capsule manufacturing apparatus has a problem in that the gelatin sheet is not manufactured uniformly because the gelatin is not properly cooled, and thus the contents are not stably encapsulated in the gelatin sheet.

The present invention was devised to solve the above-described problems, and its purpose is to provide a gelatin chiller module capable of producing sophisticated soft capsules through uniform cooling of gelatin and a soft capsule molding device including the same.

However, the technical problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems not mentioned will be clearly understood by those skilled in the art from the description of the invention described below.

The gelatin chiller module according to one aspect of the present invention is a cooling drum configured to receive gelatin from a gelatin supply module, apply gelatin to the outer surface, and have a coolant flow space inside where coolant can circulate to cool the gelatin. and a cooling water circulation unit having a cooling circulation passage configured to guide circulation of the cooling water flowing into the cooling water flow space in the cooling drum.

Preferably, the cooling drum includes a first part to which the gelatin is supplied on the outer surface and a second part provided inside the radial direction of the first part, between the first part and the second part. The coolant flow space may be provided.

Preferably, the cooling circulation flow path includes a first flow path configured to guide the inflow of the coolant into the coolant flow space, and a first flow path configured to guide the outflow of the coolant flowing from the coolant flow space to the outside of the cooling drum. May include a second euro.

Preferably, the first flow path includes a first main flow path configured to extend from the outside of the cooling drum into the cooling drum, and an inlet side inside the cooling drum is connected to the first main flow path, and an outlet side is connected to the first main flow path. It includes a first main flow path connection part connected to the coolant flow space, wherein the second flow path is configured to extend from the inside of the cooling drum to the outside of the cooling drum, and the inlet side is formed from the inside of the cooling drum. It may include a second main flow path connection part connected to the coolant flow space and having an outlet side connected to the second main flow path.

Preferably, the first flow path includes a branch part connected to the first main flow path connection part and configured to introduce the coolant supplied from the first main flow path into the coolant flow space through at least two branch paths, and It further includes at least two flow space connectors provided in a number corresponding to at least two branch paths and connected to each branch path and configured to guide the inflow of the coolant into the coolant flow space, wherein the at least two flow spaces The connection parts may be arranged to be spaced apart in the circumferential direction of the cooling drum.

Preferably, the second flow path is connected to the coolant flow space, and is provided in at least two, a flow space outlet configured to flow the coolant into the second main flow path connection portion, and connected to the flow space outlet. , a branch coupling unit configured to receive the coolant through a number of connections corresponding to the at least two flow space outlets, integrate the flow of the coolant from each connection and guide it toward the second main flow path connection. and the at least two flow space outlets may be arranged to be spaced apart in a circumferential direction of the cooling drum.

Preferably, the cooling water circulation unit is configured to accommodate the first main flow path and the second main flow path therein, and includes a housing that penetrates a side of the cooling drum and is axially coupled to the inside of the cooling drum, The interior of the cooling drum is divided into a first area and a second area by a partition to which the end of the housing is coupled, the flow space connection part is disposed in the first area, and the flow space outlet part is disposed in the second area. It can be.

Preferably, the flow space connection portion and the flow space outlet portion may be located on opposite sides of each other when viewed in a radial direction inside the cooling drum.

Preferably, the cooling water circulation unit may further include a drum driving unit configured to rotate the housing to rotate the cooling drum.

The soft capsule molding device according to one aspect of the present invention may include the gelatin chiller module according to one aspect of the present invention described above.

According to an embodiment of the present invention, gelatin can be stably cooled through the configuration of the cooling drum and cooling water circulation part of the gelatin chiller module.

Specifically, the cooling drum isolates the coolant flow space and the part where the gelatin is placed, preventing direct contact between the coolant and gelatin, while cooling the gelatin applied to the outside by the coolant circulating in the coolant flow space. It can induce gelatin to be stably formed into a sheet form.

In addition, the cooling circulation passage of the cooling water circulation unit continuously circulates the cooling water in a cooling drum configured to cool the gelatin, thereby maintaining the temperature of the cooling water in the cooling water flow space below a certain temperature that is convenient for cooling the gelatin. .

In addition, when coolant is introduced into the coolant flow space through flow space connections spaced apart from each other in the circumferential direction of a cooling drum having a circular cross-section along the two branch paths of the cooling circulation flow path, the coolant flows into the coolant flow space in the circumferential direction of the coolant flow space. Since the coolant can be injected into the coolant flow space on the opposite side, the coolant can flow more evenly and quickly within the coolant flow space. Accordingly, the forming of the gelatin sheet in the cooling drum can be performed more stably.

In addition, various other additional effects can be achieved by various embodiments of the present invention. These various effects of the present invention will be described in detail in each embodiment, or descriptions of effects that can be easily understood by those skilled in the art will be omitted.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the invention described later. Therefore, the present invention includes the matters described in such drawings. It should not be interpreted as limited to only .
Figure 1 is a diagram showing the overall shape of a gelatin chiller module and a soft capsule molding device including the same according to an embodiment of the present invention.
Figures 2 to 4 are diagrams showing the detailed shape of the gelatin chiller module of Figure 1.
Figure 5 is a cross-sectional view taken along line AA' of Figure 2.
Figures 6 to 9 are diagrams showing the gelatin cooling mechanism in the gelatin chiller module of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. Prior to this, the terms or words used in this specification and claims should not be construed as limited to their usual or dictionary meanings, and the inventor must appropriately use the concept of terms to explain his or her invention in the best way. It must be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle of definability.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not entirely represent the technical idea of the present invention, so at the time of filing the present application, various options that can replace them are available. It should be understood that equivalents and variations may exist.

Figure 1 is a diagram showing the overall shape of a gelatin chiller module (10) and a soft capsule molding device (1) including the same according to an embodiment of the present invention, and Figures 2 to 4 show the gelatin chiller module of Figure 1 This is a diagram showing the detailed shape of the chiller module 10, and FIG. 5 is a cross-sectional view taken in the direction A-A' of FIG. 2.

In an embodiment of the present invention, the X-axis direction shown in the drawing is the front-back direction of the soft capsule molding device (1), and the Y-axis direction is the The left-right direction and the Z-axis direction may mean up and down directions perpendicular to both the X-axis direction and the Y-axis direction.

Referring to Figures 1 to 5, the gelatin chiller module 10 according to an embodiment of the present invention may include a cooling drum 100 and a cooling water circulation unit 200.

The cooling drum 100 may receive gelatin (not shown) from the gelatin supply module 20 and apply gelatin to its outer surface. As an example, the gelatin supply module 20 may be a device that supplies molten gelatin to the outer surface of the cooling drum 100. At this time, the temperature of the molten gelatin applied by the gelatin supply module 20 may be approximately 50°C.

This cooling drum 100 has a circular cross-section and is driven to rotate by a drum driving unit 230, which will be described later, so that the gelatin applied to the outer surface can be molded into a sheet.

In addition, the cooling drum 100 may be configured to cool the gelatin applied to the outer surface by having a coolant flow space (S) inside which coolant (not shown) can circulate. At this time, the temperature of the gelatin after being cooled by the cooling water may be approximately 25°C.

That is, the cooling drum 100 isolates the coolant flow space (S) from the portion where the gelatin is disposed to prevent direct contact between the coolant and the gelatin, while also preventing direct contact between the coolant and the gelatin by the coolant circulating within the coolant flow space (S). By cooling the gelatin applied to the outside, the gelatin can be stably formed into a sheet form.

The coolant circulation unit 200 may include a cooling circulation flow path 210 configured to guide the circulation of coolant flowing into the coolant flow space S in the cooling drum 100 .

This cooling circulation flow path 210 continuously circulates the coolant within the cooling drum 100 configured to cool the gelatin, thereby lowering the temperature of the coolant within the coolant flow space S to a certain temperature or below that is convenient for cooling the gelatin. can be maintained. Additionally, the cooling circulation passage 210 may receive coolant from a separate coolant storage unit (not shown).

According to this implementation configuration of the present invention, gelatin can be stably cooled through the configuration of the cooling drum 100 and the cooling water circulation unit 200.

Meanwhile, the soft capsule molding device 1 according to an embodiment of the present invention may include the gelatin chiller module 10 and the gelatin supply module 20 described above. Although not shown in detail, the gelatin chiller module 10 may be configured to face each other in pairs when viewed from the left and right directions (Y-axis direction) of the soft capsule molding device 1.

Additionally, as shown in FIG. 1 , the soft capsule molding device 1 may further include a gelatin transfer module 30, a drug injection module 40, and a soft capsule molding module 50.

The gelatin transfer module 30 may be configured to transfer the gelatin sheet cooled by the gelatin chiller module 10 and formed into a sheet shape through at least one transfer roller.

The chemical injection module 40 may be configured to inject a chemical solution into the gelatin sheet transferred through the gelatin transfer module.

The soft capsule molding module 50 may be configured to mold the gelatin sheet into a capsule shape while the drug solution is injected into the gelatin sheet.

2 to 4, the cooling drum 100 may include a first part 110 and a second part 120.

The gelatin may be supplied to the outer surface of the first part 110.

The second part 120 may be provided inside the first part 110 in the radial direction.

At this time, a coolant flow space S may be provided between the first part 110 and the second part 120. As an example, the first part 110 may include a material with high thermal conductivity so that the cold air of the coolant in the coolant flow space S can be transferred to the gelatin.

Referring to FIGS. 2 to 5 , the cooling circulation flow path 210 may include a first flow path 212 and a second flow path 214.

The first flow path 212 may be configured to guide the inflow of coolant into the coolant flow space (S).

The second flow path 214 may be configured to guide the outflow of the coolant flowing in from the coolant flow space S to the outside of the cooling drum 100.

In one embodiment, as shown in FIG. 1, the soft capsule molding device 1 may further include a separate control module 60.

This control module 60 may be configured to control the temperature of coolant flowing into or flowing out of the coolant flow space (S). As an example, the control module 60 may be configured to control the temperature of the coolant within the range of 0°C to 70°C by controlling a temperature controller (not shown) provided in the coolant storage unit described above. That is, the control module 60 can perform not only cooling but also heating operations on gelatin.

In particular, the first flow path 212 may include a first main flow path 212a and a first main flow path connection portion 212b.

The first main flow path 212a may be configured to extend from the outside of the cooling drum 100 (coolant storage unit) into the cooling drum 100.

The first main flow path connection portion 212b may have an inlet side connected to the first main flow path 212a and an outlet side connected to the coolant flow space S inside the cooling drum 100. At this time, the first main flow path connection portion 212b and the coolant flow space S may be connected through a hose H.

Additionally, the second flow path 214 may include a second main flow path 214a and a second main flow path connection portion 214b.

The second main flow path 214a may be configured to extend from the inside of the cooling drum 100 to the outside of the cooling drum 100 (coolant storage unit).

The second main flow path connection portion 214b may have an inlet side connected to the coolant flow space S inside the cooling drum 100 and an outlet side connected to the second main flow path 214a. At this time, the second main flow path connection portion 214b and the coolant flow space (S) may be connected through a hose (H).

According to this implementation configuration, the coolant can be stably circulated in and out of the coolant flow space (S) through the flow path configuration, so the temperature of the coolant in the coolant flow space (S) can be more stably lowered to a certain temperature or below that is convenient for gelatin cooling. It can be maintained.

Figures 6 to 9 are diagrams showing the gelatin cooling mechanism in the gelatin chiller module 10 of the present invention.

Referring to FIGS. 5 to 9 , the first flow path 212 may further include a branch portion 212c and at least two flow space connection portions 212d.

The branch portion 212c is connected to the first main flow path connection portion 212b and is configured to allow coolant supplied from the first main flow path 212a to flow into the coolant flow space S through at least two branch paths. It can be. At this time, the inlet side of the branch portion 212c may be connected to the first main flow path connection portion 212b and the hose H.

As an example, the at least two branch paths may include a first branch path 212c1 and a second branch path 212c2.

The first branch path 212c1 and the second branch path 212c2 are outlet sides of the branch portion 212c and may be configured to extend in the left and right direction (Y-axis direction) of the cooling drum 100. And the first branch path 212c1 and the second branch path 212c2 may be connected to the coolant flow space S through a hose H, respectively.

In addition, the at least two flow space connection parts 212d may be provided in a number corresponding to at least two branch paths and may be connected to each branch path to guide the inflow of coolant into the coolant flow space S. there is.

That is, the two flow space connection parts 212d may be connected to the first branch path 212c1 and the second branch path 212c2 through the hose H, respectively.

At this time, at least two flow space connection parts 212d may be arranged to be spaced apart in the circumferential direction of the cooling drum 100.

In this way, coolant is introduced into the coolant flow space (S) through the flow space connection portions (212d) spaced apart from each other in the circumferential direction of the cooling drum (100) having a circular cross-section along the two branch paths (212c1, 212c2). In this case, since the coolant can be injected into the coolant flow space (S) from opposite sides in the circumferential direction of the coolant flow space (S), the coolant can flow more evenly and quickly within the coolant flow space (S). Accordingly, the forming of the gelatin sheet in the cooling drum 100 can be performed more stably.

Referring again to FIGS. 5 to 9 , the second flow path 214 may further include a flow space outlet portion 214c and a branch coupling portion 214d.

The flow space outlet 214c is connected to the coolant flow space S, and may be provided in at least two pieces to allow coolant to flow into the second main flow passage connection part 214b. At this time, the flow space outlet 214c and the second main flow path connection part 214b may be connected through a hose (H).

The branch coupling portion 214d is connected to the flow space outlet 214c, receives coolant through connections provided in numbers corresponding to at least two flow space outlets 214c, and receives coolant from each connection portion. It may be configured to integrate the flow of coolant and guide it toward the second main flow passage connection portion 214b.

As an example, the at least two connection parts may include a first connection part 214d1 and a second connection part 214d2.

The first connection part 214d1 and the second connection part 214d2 are the inlet side of the branch coupling part 214d, and may be configured to extend in the left and right direction (Y-axis direction) of the cooling drum 100. At this time, the two flow space outlets 214c may be connected to the first connection part 214d1 and the second connection part 214d2 through hoses H, respectively. And, the outlet side of the branch coupling portion 214d may be connected to the second main flow path connection portion 214b through a hose H.

Additionally, at least two flow space outlets 214c may be arranged to be spaced apart in the circumferential direction of the cooling drum 100.

In this way, the coolant is discharged from the coolant flow space S along the flow space outlet portions 214c spaced apart from each other in the circumferential direction of the cooling drum 100 having a circular cross-section through the two connection portions 214d1 and 214d2. When flowing into the second flow path 214, the coolant may be discharged from the coolant flow space (S) from opposite sides in the circumferential direction within the coolant flow space (S), thereby transferring cold air to the gelatin and increasing the temperature. Coolant can be discharged to the outside of the coolant flow space (S) more quickly. Accordingly, the cooling water circulates more smoothly within the cooling water flow space (S), so that the forming of the gelatin sheet in the cooling drum 100 can be performed more stably.

Meanwhile, the coolant circulation unit 200 may further include a flow path supporter 220 configured to support the first flow path 212 and the second flow path 214.

Specifically, the flow path support portion 220 may include a housing 222.

The housing 222 is configured to accommodate the first main flow path 212a and the second main flow path 214a therein, It may penetrate the side of the cooling drum 100 and be axially coupled to the inside of the cooling drum 100. As an example, the housing 222 may be coupled to the side of the cooling drum 100 in the front-back direction (X-axis direction) of the cooling drum 100.

At this time, the housing 222 may be rotationally driven by the drum driving unit 230, which will be described later, to rotate the cooling drum 100.

In particular, the interior of the cooling drum 100 can be divided into a first area (B1) and a second area (B2) by the partition 130 of the cooling drum 100 to which the end of the housing 222 is coupled. there is. At this time, the first area B1 and the second area B2 may be divided based on the partition 130 in the front-back direction (X-axis direction) of the cooling drum 100.

Here, the flow space connection portion 212d of the above-described first flow path 212 is disposed in the first area (B1), and the flow space outlet portion 214c of the second flow path 214 is located in the second area (B2). can be placed.

That is, when viewed from the front-back direction (X-axis direction) of the cooling drum 100, the flow space connection portion 212d through which coolant flows into the coolant flow space S and the flow space through which coolant is discharged from the coolant flow space S The outlet portions 214c may be disposed on opposite sides of the partition portion 130 .

According to this implementation configuration, the flow space connection part 212d and the flow space outlet part 214c are physically separated, and when the cooling drum 100 rotates, the flow space connection part 212d and the first main flow path connection part 212b are connected. Interference between the hoses H and the hoses H connected between the flow space outlet 214c and the second main flow path connection part 214b can be minimized.

In addition, the flow space connection portion 212d through which coolant flows into the coolant flow space S and the flow space outlet portion 214c through which coolant is discharged from the coolant flow space S are viewed from the front and rear directions of the cooling drum 100. Since they are disposed on opposite sides, the coolant flow can be formed evenly when viewed from the front and back directions of the cooling drum 100 within the coolant flow space S. Accordingly, the molding of the gelatin sheet can be performed more stably.

In one embodiment, the flow path support part 220 may further include an adapter 224 including a first adapter 224a and a second adapter 224b.

The first adapter 224a may guide the inflow of coolant from the outside of the cooling drum 100 (coolant storage unit) into the first main flow path 212a.

The second adapter 224b may guide the discharge of coolant from the inside of the cooling drum 100 to the outside of the second main passage 214a (coolant storage unit).

In particular, as shown in FIGS. 5 to 9, the flow space connection portion 212d and the flow space outlet portion 214c may be located on opposite sides of each other when viewed in the radial direction inside the cooling drum 100.

That is, when viewed from the radial direction inside the cooling drum 100, the flow space connection portion 212d through which coolant flows into the coolant flow space S and the flow space outlet 214c through which coolant is discharged from the coolant flow space S ) can be placed on opposite sides of each other.

According to this implementation configuration, the flow space connection part 212d and the flow space outlet part 214c are physically separated, and when the cooling drum 100 rotates, the flow space connection part 212d and the first main flow path connection part 212b are connected. Interference between the hoses H and the hoses H connected between the flow space outlet 214c and the second main flow path connection part 214b can be minimized.

In addition, the flow space connection portion 212d through which coolant flows into the coolant flow space S and the flow space outlet portion 214c through which coolant is discharged from the coolant flow space S are visible in the radial direction of the cooling drum 100. Since they are disposed on opposite sides, the coolant can flow evenly in the entire circumferential direction of the cooling drum 100 within the coolant flow space S. Accordingly, the molding of the gelatin sheet can be performed more stably.

Referring to FIGS. 1 to 9 , the coolant circulation unit 200 may further include the drum driving unit 230 described above.

The drum driving unit 230 may be configured to rotate the housing 222 to rotate the cooling drum 100.

Specifically, the drum driving unit 230 may include a first gear 232, a second gear 234, and a driving motor 236.

The first gear 232 may be configured to be axially coupled to the housing 222 to rotate the housing 222.

The second gear 234 may be configured to be engaged and coupled to the first gear 232.

The drive motor 236 may be configured to provide rotational driving force to the second gear 234 to rotate the second gear 234 and the first gear 232 coupled thereto.

As described above, although the present invention has been described with limited examples and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following will be understood by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalence of the patent claims to be described.

Meanwhile, in the present invention, terms indicating directions such as up, down, left, right, front, and back are used, but these terms are only for convenience of explanation and may vary depending on the location of the target object or the location of the observer. It is obvious to those skilled in the art that this can be done.

1: Soft capsule forming device
10: Gelatin chiller module
100: cooling drum
110: first part
120: second part
130: compartment
200: Coolant circulation unit
210: Cooling circulation flow path
212: 1st Euro
212a: 1st main euro
212b: First main flow path connection part
212c: bifurcation
212d: floating space connection
214: 2nd euro
214a: 2nd main flow path
214b: 2nd main flow path connection part
214c: flow space outlet
214d: branch joint
220: Euro support
222: housing
224: adapter
230: Drum supply unit
20: Gelatin supply module

Claims (10)

A cooling drum configured to receive gelatin from a gelatin supply module, apply the gelatin to the outer surface, and have a cooling water flow space inside through which the cooling water can circulate to cool the gelatin; and
A cooling water circulation unit having a cooling circulation passage configured to guide circulation of the cooling water flowing into the cooling water flow space in the cooling drum,
The cooling circulation flow path is,
a first flow path configured to guide the inflow of the coolant into the coolant flow space; and
It includes a second flow path configured to guide the outflow of the coolant flowing in from the coolant flow space to the outside of the cooling drum,
The first flow path is,
a first main flow path extending from the outside of the cooling drum into the cooling drum; and
Inside the cooling drum, the inlet side is connected to the first main flow path, and the outlet side is connected to the coolant flow space, including a first main flow path connection part,
The second euro is,
a second main flow path extending from the inside of the cooling drum to the outside of the cooling drum; and
A gelatin chiller module, characterized in that it includes a second main flow path connection part whose inlet side is connected to the cooling water flow space inside the cooling drum and whose outlet side is connected to the second main flow path. According to clause 1,
The cooling drum is,
A first part to which the gelatin is supplied to the outer surface; and
It includes a second part provided inside the radial direction of the first part,
Between the first part and the second part,
A gelatin chiller module, characterized in that the coolant flow space is provided. delete delete According to clause 1,
The first flow path is,
a branch connected to the first main flow path connection part and configured to allow coolant supplied from the first main flow path to flow into the coolant flow space through at least two branch paths; and
Further comprising at least two flow space connection parts provided in a number corresponding to the at least two branch paths and connected to each branch path to guide the inflow of the coolant into the coolant flow space,
The at least two flow space connections,
A gelatin chiller module, characterized in that it is arranged to be spaced apart in the circumferential direction of the cooling drum. According to clause 5,
The second euro is,
At least two flow space outlets connected to the coolant flow space and configured to flow the coolant into the second main flow path connection part; and
It is connected to the flow space outlet, receives the coolant through a number of connections corresponding to the at least two flow space outlets, and integrates the flow of coolant from each connection to the second main flow path connection. Further comprising a branch coupling configured to guide to the side,
The at least two flow space outlets,
A gelatin chiller module, characterized in that it is arranged to be spaced apart in the circumferential direction of the cooling drum. According to clause 6,
The coolant circulation unit,
A housing configured to accommodate the first main flow path and the second main flow path therein, penetrating a side of the cooling drum and axially coupled to the inside of the cooling drum,
The inside of the cooling drum is,
The housing is divided into a first area and a second area by a partition joined to an end of the housing,
The flow space connection portion is disposed in the first area,
Gelatin chiller module, characterized in that the flow space outlet is disposed in the second area. According to clause 6,
The flow space connection portion and the flow space outlet portion,
Gelatin chiller modules, characterized in that they are located on opposite sides of each other when viewed in the radial direction inside the cooling drum. According to clause 7,
The coolant circulation unit,
A gelatin chiller module further comprising a drum driving unit configured to rotate the housing to rotate the cooling drum. A soft capsule forming device comprising a gelatin chiller module according to any one of claims 1, 2, and 5 to 9.

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