KR101689563B1 - The casting drum molding gelatin capsules - Google Patents

Abstract

The present invention relates to a casting drum of a capsule molding machine for forming capsules for pharmaceutical and food products using gelatin as a raw material, in which a pipe connected to a supply line of cooling water is inserted into a drum body of a casting drum, So that cooling water is injected onto the surface of the drum main body and the spray angle is concentratedly injected to a portion where the gelatin sheet is first rubbed on the casting drum to improve the cooling efficiency of the casting drum In addition, the cooling water injected into the drum body is maintained in the drum body for a predetermined period of time to be discharged, and then discharged. Thus, secondary cooling of the casting drum is performed by the fresh water, and at the same time, The temperature is raised to a relatively high temperature in the cooling water in which heat exchange has been performed So that the cooling efficiency of the gelatin sheet is improved.

Description

[0001] The casting drum molding gelatin capsules of a gelatin capsule-

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a casting drum of a capsule molding machine for forming capsules for pharmaceuticals and foods using gelatin as a raw material, and is characterized in that when a liquid gelatin is spread and supplied to a gelatin sheet by improving the structure for cooling the casting drum, So that the cooling efficiency of the driving unit can be improved and the failure rate of the driving unit can be reduced.

In general, a gelatin capsule molding machine comprises a gelatin supply device 1 provided symmetrically on both sides to supply gelatin, as shown in FIG. 1, a casting drum 1 for cooling a gelatin sheet supplied in a thin sheet form from the gelatin supply device 1, A guide roller 3 for pulling the gelatin sheet cooled through the casting drum 3 and a molding device 4 for injecting a chemical solution while molding the gelatin sheet pulled by the guide roller 3 in the form of capsules ), And liquid gelatin is formed into capsules while injecting a chemical solution therein.

The structure of the casting drum 2 for cooling the gelatin sheet is such that a water supply pipe and a water discharge pipe are provided inside the casting drum to supply cooling water and supply water to the casting drum as disclosed in Korean Patent Application No. 2003-0062984 The cooling water is cooled while the cooling water is completely cooled in the casting drum, and the warmed cooling water is discharged through the drain pipe, so that the casting drum is continuously cooled.

In particular, in consideration of the rotating direction of the casting drum, cooling water having a low temperature is designed to stay in the casting drum for a long time.

However, the problem of the method of replacing the cooling water in the state where the cooling water is full is that the cooling efficiency is high at the time of starting the capsule molding machine for the first time, but the cooling efficiency is decreased when the capsule molding machine is driven for a long time.

That is, since the casting drum is supplied with the cooling water in a state in which the cooling water is filled, it is difficult to lower the temperature of the cooling water which is already filled in the casting drum with a small amount of the cooling water that flows into the casting drum. There is a difficulty in lowering the circulation time or shortening the circulation time.

On the other hand, since the casting drum rotates while the cooling water is inside, it is very important to seal the driving part, and it is recommended to use purified water for durability of parts for driving. However, Occasionally, tap water or ground water is used.

However, when the untreated water is used as the cooling water, the foreign substances contained in the cooling water are caught in the sealing part of the driving part or put in the bearing or the like, and a failure occurs.

Therefore, the driving unit may fail, and in particular, since the driving shaft and other accessories for driving are all built in the casting drum, in order to repair the driving unit when it is damaged, The work process is very difficult because it has to be reassembled.

That is, first, the cover of the machine is removed first, the full cooling water is discharged to the casting drum through the drain valve, then the basket case is removed, the seal of the driving part is removed and the damaged part (for example, Bearings, etc.) are removed and replaced, and the procedure is reassembled in the reverse order to complete the repair.

Therefore, maintenance of the drive part is very difficult, and in particular, it is more difficult to maintain the drill since the drill is disassembled and assembled by the operator using the tool in a small diameter drum.

In addition, it takes a very long time to consume maintenance, and since the capsule can not be produced during that time, the productivity is lowered.

KR 1020030062894 A KR 200315638 Y1 KR 200328681 Y1

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a method of cooling a casting drum, in which cooling water is directly applied to the inner surface of a drum, And it is an object of the present invention to provide a casting drum of a gelatin capsule molding machine capable of maximizing cooling efficiency by cooling by direct friction.

Another object of the present invention is to enable the cooling water injected from the casting drum to be exhausted after staying in the casting drum for a predetermined period of time while discharging the cooled water from the cooling water heated to a higher temperature.

According to an aspect of the present invention, there is provided a casting drum comprising: a casting drum; a pipe connected to a supply line of the cooling water into the drum body of the casting drum; and a plurality of nozzles mounted on the inserted pipe, So that the cooling of the casting drum is performed so that the cooling temperature of the casting drum is transferred to the surface of the drum body as it is.

In addition, the spray angle of the nozzle mounted on the pipe concentrates the liquid gelatin toward the spreader box which expands and discharges the gelatin into the gelatin sheet, so that the cooling water is concentrated on the part where the cooling is most needed.

In addition, the cooling water injected into the drum body is dewatered on the lower side to perform secondary cooling of the drum body, and the discharge port connected to the drain line at a height not exceeding the height of the pipe on which the nozzle is mounted is formed, The water level is automatically adjusted while the cooling water is overflowed and the water which has been heated to a relatively high temperature among the fresh water is sequentially discharged by the overflow method.

Further, since the driving part of the casting drum is assembled on the outer side of the drum body, it can be easily disassembled and assembled.

According to the casting drum of the gelatin capsule molding machine of the present invention, the cooling water supplied through the supply passage is sprayed to the upper surface of the drum body through the nozzle, whereby the cooling water having the low temperature initially introduced directly cools the surface of the casting drum, The gelatin is solidified in a shorter time by intensively cooling the portion where the gelatin is discharged in a sheet form, and the gelatin sheet can be stably supplied without deforming the shape of the gelatin.

Further, since the operating structure of the casting drum directly rotates the entire drum by a gear system without using a separate driving shaft, and since the driving unit is assembled from the outside of the drum body, Since the structure is not directly exposed, it is possible to reduce the number of fault elements and there is almost no possibility of failure due to foreign matter of the cooling water even if purified water is not used as cooling water.

Further, since the operator can visually check whether the cooling water is properly injected by using the sight window formed on the drum, it is not necessary to perform any additional inspection and maintenance is very easy, and there is no element such as an oil chamber inside the drum body It is very easy to replace and repair parts because it can easily replace the parts by releasing the joint of the driving part after removing the cover even if the parts of the driving part fail, even if the life of the bearing is not shortened. Time can be remarkably shortened.

1 is an external perspective view of a gelatin capsule molding machine equipped with a casting drum according to the present invention.
Fig. 2 is a front view of the capsule molding machine of Fig. 1
Fig. 3 is an external perspective view showing the connecting structure of the casting drums on both sides of the present invention
4 is an external perspective view showing the structure of the casting drum of the present invention.
Fig. 5 is a cross-sectional view showing the structure of the casting drum of Fig. 4
Fig. 6 is a cross-sectional view showing the cooling water injection structure of the casting drum of Fig. 4
Fig. 7 is a cross-sectional view showing the cooling water discharge structure of the casting drum of Fig. 4
8 is a schematic view of the casting drum of the present invention
Fig. 9 is a perspective view showing the driving device of the casting drum of the present invention and the connection structure of the supply passage and the drain passage. Fig.
10 is a partial enlarged view showing a structure of a driving apparatus according to the present invention;
11 is an exploded perspective view showing an assembling structure of the driving apparatus of Fig.

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

As shown in FIGS. 1 and 2, the capsule molding machine of the present invention includes a gelatin supply device 1 provided symmetrically on both sides to supply gelatin, and a gelatin supplying device 1 for cooling a gelatin sheet supplied in a thin sheet form from the gelatin supply device 1 A guide roller 3 for pulling the gelatin sheet cooled through the casting drum and a gelatin sheet drawn by the guide roller 3 into a capsule form while injecting a chemical solution 3 to FIG. 5, the structure of the casting drum 2 is similar to that of FIG. 3 to FIG. 5. FIG. 3 is a perspective view of the casting drum 2 of FIG. A supply line 30 for supplying the cooling water to the drum main body 10 and a drain line 40 for discharging the cooling water of the drum main body 10 .

The drum body 10 is for allowing a gelatin sheet to be laid when a liquid gelatin is discharged into a sheet form in a spreader box of the gelatin feeding device 1. The gelatin sheet is fed to a molding device 4 And at the same time, keeping the temperature of the surface at a low level so as to cool the gelatin sheet so as to cause solidification.

The drum body 10 has a cylindrical shape. The gelatin sheet is conveyed while being rotated by the driving unit 20, and the inside of the drum body 10 is hollow And the cooling water is injected into the hollow portion 11 to lower the surface temperature of the drum body 10 and lower the temperature of the gelatin sheet laid on the drum body 10 to perform solidification.

The drum body 10 is provided with a supply line 30 for injecting low-temperature cooling water to lower the temperature of the drum body 10 and the drum body 10 to cool the gelatin sheet, A drain line 40 for discharging the cooling water is mounted.

The supply line 30 is formed by inserting a pipe 31 formed with a flow path 31a into the hollow portion 11 of the drum body 10 and supplying cooling water to the hollow portion 11 of the drum body 10 through the supply line 30 And the pipe 31 is provided with a plurality of nozzles 32 for injecting cooling water.

Therefore, when the cooling water supplied through the supply line 30 is injected into the hollow portion 11, the cooling water is injected and the temperature of the cooling water is directly transferred to the surface of the drum body to cool the gelatin sheet, So that the cooling efficiency can be increased.

At this time, the nozzle 32 may be formed by machining a plurality of holes in the pipe 31, or by mounting a separate nozzle unit.

The jetting direction of the nozzle 32 is preferably set so that the spray angle of the nozzle 32 is set to the upper side of the drum body 10, which is the point where the gelatin sheet is discharged from the spreader box and first contacted with the drum body 10 Do.

That is, when the temperature of the gelatin sheet is discharged from the spreader box and rubbed to the surface of the drum body 10 for the first time, the temperature is highest and the temperature is gradually lowered in the process of being conveyed by the casting drum 2, The cooling efficiency can be maximized by concentrating the cooling water to the portion of the surface of the drum body 10 where the temperature of the gelatin sheet is highest.

The drum body 10 can be visually confirmed that the cooling water is sprayed from the nozzle 32 by forming a see-through window 12 on the front surface. The drum body 10 can be visually checked for normal operation or failure, It is easy for the operator to check.

When the drainage line 40 formed in the drum body 10 is formed so that the position of the discharge port 41 through which the warmed cooling water is discharged is set at a predetermined height near the center of the drum body 10, The cooling water supplied through the drum 30 is sprayed, and then the water is drained to the lower portion of the drum body 10 to induce secondary cooling of the casting drum.

The discharge port 41 is preferably formed at a height that does not contact the nozzle 32 of the supply line 30 with respect to the cooling water that is discharged into the drum body 10. Particularly, And is coaxially formed with the rotating shaft of the drum body so as to be sequentially discharged by overflow from the cooling water heated to a relatively high temperature.

5, the pipe 31 of the supply line 30 is installed at the center of the discharge port 41 of the discharge line 40, (31) and the discharge port (41) are formed in a double pipe structure so that the supply flow path and the discharge flow path are separated from each other, so that the cooling water can be supplied and drained.

In addition, the cooling water which is dewatered to the drum body 10 to be subjected to the secondary cooling is elevated to the surface due to the convection phenomenon and is preferentially discharged from the fresh water, so that the cooling efficiency . ≪ / RTI >

At this time, it is preferable that the cooling water discharged to the outside through the drain line (40) is re-supplied to the supply line (30) after performing heat exchange so that the casting drum (2) The heat exchange structure may be a natural heat exchange system or a separate cooler may be installed in the circulation line to effect heat exchange.

The cooling temperature of the casting drum 2 can be controlled by measuring the temperature of the cooling water discharged through the drainage line 40 and controlling the supply amount or the temperature of the cooling water injected through the supply line 30.

A temperature sensor 42 is attached to the drainage line 40 and a valve 33 for controlling the flow rate of the cooling water supplied to the drum body through the nozzle 32 of the pipe 31 is provided in the supply line 30 The temperature of the cooling water contained in the drum body 10 of the casting drum 2 can be adjusted by connecting the temperature sensor 42 and the valve 33 to the control unit 50, respectively.

That is, as shown in FIG. 8, the temperature of the cooling water contained in the drum body 10 and used as cooling water and discharged through the drain line 40 is measured by the temperature sensor 42, The control unit 50 controls the valve 33 of the supply line 30 when the temperature is lower or higher than the set temperature based on the temperature measured by the temperature sensor 42 The cooling water temperature of the casting drum is adjusted to the set temperature by interrupting the quantity of the incoming cooling water.

At this time, the temperature of the cooling water contained in the drum main body 10 is adjusted by controlling the amount of cooling water supplied through the supply line 30, but depending on the embodiment, it includes a cooling device and a heating device, The temperature can also be adjusted.

The driving unit 20 includes a connecting rod 21 protruding from the drum body 10, a driven gear 22 coupled with the connecting rod 21, And a rotation union valve 25 for preventing the rotation of the supply line 30 and the drain line 40 from being interlocked with each other.

The connecting rod 21 is for connecting the drum body 10 and the driven gear 22 so that the drum body 10 is rotated by the rotation of the driven gear 22, The driven gear 22 is connected to the driving gear 24 of the driving motor 23 in a gear engaging manner to drive the driving motor 23 The drum body 10 is rotated.

By installing the rotation union valve 25 as a structure for forming the supply line 30 and the drain line 40 in the drive device 20, the pipe 31 of the supply line 30 and the drain line The supply line 30 and the drain line 40 are not rotated when the drum body 10 rotates even though the discharge port 41 of the drive unit 40 is formed in the drive unit 20, The spray angle of the cooling water injected through the pipe 31 of the drum 30 and the nozzle 32 can be kept constant and the cooling water can be stably supplied and drained to the drum body 10.

When the speed sensing device 26 is attached to the driving device 20 and the speed sensing device 26 is connected to the control part 50 for controlling the capsule molding machine, The rotational speed of the drum body 10 of the casting drum 2 can be automatically controlled.

At this time, the speed sensing device 26 is mounted with the rotation plate 26a so as to rotate together with the drum main body 10 or the driven gear 22, and a sensor 26b for sensing the rotation speed of the rotation plate 26a So that the speed can be measured.

The speed measuring method using the rotating plate 26a and the sensor 26b is a method of measuring the rotational speed of the teeth by using the sensor 26b as a proximity sensor while forming a plurality of teeth along the circumference of the rotating plate 26a, Alternatively, the rotation speed of the rotary plate 26a may be sensed by a magnetic method.

When the rotational speed of the drum body 10 is earlier or later than the set speed, the control unit 50 detects the measured speed, The speed of the motor 23 is adjusted so that the driving is performed at the set speed.

1: Gelatin feeding device 2: Casting drum
3: guide roller 4: molding device
5: chemical liquid supply device
10: drum body 11: hollow part
12: Looking Glass
20: driving device 21: connecting rod
22: driven gear 23: drive motor
24: Driving gear 25: Rotation union valve
26: Speed sensing device
30: supply line 31: pipe
31a: flow path 32: nozzle
40: drainage line 41: outlet
42: Temperature sensor
50:

Claims (7)

A driving device (20) for rotating the drum body (10) in which a hollow part (11) for injecting cooling water is formed and a gelatin sheet is installed is formed in a cylindrical shape
A driven gear 22 rotatably coupled with the connecting rod 21 and a driving motor 23 for driving the driven gear 22 and a drive motor 23 for driving the driven gear 22, And a rotation union valve (25) for preventing rotation of the gear (24), the supply line (30) and the drain line (40)
A supply line 30 for supplying cooling water to the hollow portion 11 of the drum body 10 is inserted into the hollow portion 11 of the drum body 10 with a pipe 31 having a flow path 31a formed therein, A plurality of nozzles 32 are set in an upward direction in which the gelatin sheet is brought into contact with the drum body so that the temperature of the cooling water is directly supplied to the pipe 31 on the surface of the drum body to which the gelatin sheet is supplied,
The drainage line 40 for discharging the cooling water contained in the hollow portion 11 of the drum body 10 to the outside causes the cooling water supplied to the drum body 10 to be desiccated at the lower portion of the drum body 10, A discharge port 41 is formed coaxially with the rotating shaft of the drum body so as to induce secondary cooling and sequentially discharge the overflow from the coolant water heated to a high temperature,
The pipe 31 of the supply line 30 is mounted at the center of the discharge port 41 of the discharge line 40 so as to be discharged by the cooling water overflowed to the drum body 10, Wherein the casting drum of the gelatin capsule molding machine has a double pipe structure and the flow path is separated to supply and drain cooling water. delete delete delete delete The method according to claim 1,
The driving device 20 further includes a speed sensing device 26. The speed sensing device 26 includes a rotation plate 26a and a sensor 26b for sensing the rotation speed of the rotation plate 26a, The control unit 50 forwards the velocity value measured by the sensing device 26 to the control unit 50 so that the rotation speed of the casting drum can be adjusted through the control of the drive motor 21 in accordance with the set velocity And the casting drum of the gelatin capsule molding machine. The method according to claim 1,
The temperature sensor 42 is mounted on the drain line 40 to measure the temperature of the discharged gas and the temperature is forwarded to the control unit 50. The control unit controls the temperature of the temperature sensor 42, The temperature of the casting drum is controlled by controlling the amount of the cooling water flowing into the drum body 10 through the nozzle 32 of the pipe 31 by controlling the valve 33 of the casting drum 30 Casting drum of gelatin capsule molding machine.

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