KR20240020961A - Granule manufacturing system - Google Patents

Abstract

A granule manufacturing system is disclosed. The disclosed granule production system includes an extractor for producing a liquid extract by thermally extracting the granule material; A double-boiling concentrator equipped with an extract supply line connected to the extractor, receiving the liquid extract through the extract supply line and removing moisture through a double boiling method to produce a concentrate; A stirrer for preparing a mixture by stirring and mixing the concentrate and excipients to produce stirred granules; A granule molder that supplies the mixture mixed by the stirrer to a granule mold through a vibrating pipe and molds the mixture into granules through a granule mold hole formed in the granule mold to produce a granule molded product; A dryer that dries the granulated material to complete dried granules; A controller consisting of a control unit that controls the extractor, concentrator, stirrer, granulator, and dryer, and an operating panel that allows the control unit to control the extractor, concentrator, stirrer, granulator, and dryer according to user input. It is characterized by including.

Description

Granule manufacturing system {Granule manufacturing system}

The present invention relates to a granule manufacturing device, and more specifically, to each device that can collectively process the entire granulation process of extraction-concentration-stirring-granulation-drying of granule materials such as medicinal ingredients or health food ingredients. It relates to a granule manufacturing system that can intensively configure a single device to increase the process efficiency of granule manufacturing and to manufacture high-quality edible granules such as granular medicine and granular health food without deterioration of the material.

Generally, in order to manufacture granular health foods and medicines, health food ingredients and herbal medicines are boiled, the extract is concentrated, excipients are added, and an excipient is added and dried to prepare granular preparations.

The manufacturing of these edible granules has had a problem in that productivity is greatly reduced because each process is mostly performed manually. Accordingly, devices for manufacturing edible granules are being developed.

This edible granule manufacturing device is disclosed in Patent Registration No. 10-0848014, Publication Patent No. 10-2000-0073890, and Patent No. 10-1155527.

However, this conventional edible granule manufacturing device cannot proceed with the entire granulation process consisting of extraction-concentration-stirring-granulation-forming-drying in batches and consists of a device that can only perform some processes, so the efficiency of manufacturing granules is low. It was not at a satisfactory level, and it was difficult to consistently produce granules with uniform properties and medicinal efficacy.

In particular, when each process equipment is configured individually, the size of the overall equipment is bound to be large and must be installed within the manufacturing facility, so there are many limitations on the installation space of the manufacturing equipment, and the transportation of materials between each process is limited. It was difficult and time consuming, and the materials deteriorated during the transportation process, making it difficult to produce high-quality edible granules.

Registered Patent No. 10-0848014 Publication Patent No. 10-2000-0073890 Registered Patent No. 10-1155527

The present invention was created to solve the conventional problems as described above, and can handle the entire granulation process of extraction, concentration, stirring, granulation molding, and drying of granular materials such as medicinal ingredients or health food ingredients in one batch. The purpose is to increase the process efficiency of granule manufacturing and provide a granule manufacturing system that can produce high-quality edible granules such as granular medicine and granular health food without deterioration of the material.

In addition, the present invention consists of a packaging machine capable of packaging edible granules manufactured through a batch granulation process in stick form, so that not only the manufacturing of the granules but also the packaging can be carried out quickly and integrated to maximize the productivity of the edible granules. Another object is to provide a granule manufacturing system with improved morphology.

However, the purpose of the present invention is not limited to this, and of course, even if not explicitly mentioned, purposes or effects that can be understood from the means of solving the problem or the embodiment are also included.

The granule production system of the present invention for achieving the above object includes an extractor for producing a liquid extract by hydrothermal extraction of granule material; A double-boiling concentrator equipped with an extract supply line connected to the extractor, receiving the liquid extract through the extract supply line and removing moisture through a double boiling method to produce a concentrate; A stirrer for preparing a mixture by stirring and mixing the concentrate and excipients to produce stirred granules; A granule molder that supplies the mixture mixed by the stirrer to a granule mold through a vibrating pipe and molds the mixture into granules through a granule mold hole formed in the granule mold to produce a granule molded product; A dryer that dries the granulated material to complete dried granules; A controller consisting of a control unit that controls the extractor, concentrator, stirrer, granulator, and dryer, and an operating panel that allows the control unit to control the extractor, concentrator, stirrer, granulator, and dryer according to user input. It is characterized by including.

The extractor includes an extractor inner tube in which granular material is accommodated and a hot water inlet hole is formed on the bottom surface so that a liquid extract is generated by hot water flowing in through the hot water inlet hole; A lower plate fixed to the main body frame and having an extract discharge part on the bottom, a glass tube installed vertically around the lower plate into which the extractor inner tube is inserted and filled with water for hot water extraction, and an upper circumference of the glass tube an extractor outer cylinder including an upper plate installed on the extractor inner cylinder; An extractor heater installed on the lower side of the lower plate portion to heat the water contained in the extractor outer cylinder to generate hot water, and the generated hot water flows into the inner cylinder of the extractor through the hot water entrance hole by a convection phenomenon to generate a liquid extract; Included, the extractor heater is operated by the control unit when the temperature of the hot water reaches a set temperature of 91 to 93 ℃ for 100 to 120 minutes, and is stopped when the temperature is set to 99 to 101 ℃, and is controlled to generate a liquid extract. It is structured as possible.

The concentrator is installed on the main body frame, contains water for double boiling, and is heated by a concentrator heater installed on the bottom of the concentrator to heat the water to a predetermined temperature. It is configured to be seated at predetermined intervals inside the concentrator outer cylinder, and the liquid extract supplied from the extractor through the extract supply line is accommodated, and the liquid extract is boiled in heated water contained in the concentrator outer cylinder, thereby causing moisture. The inner tube of the concentrator from which this is removed to produce a concentrate; A concentrator door that opens and closes the open top of the concentrator inner cylinder and is provided with a viewing window to check the concentration state of the concentrate in the concentrator inner cylinder from the outside; A door driving unit installed on the main body frame in connection with the concentrator door and consisting of a swing cylinder to open and close the concentrator door by moving it up and down and rotating it left and right; An extract supply line connecting the concentrator door and the extract discharge unit to supply the liquid extract discharged through the extract discharge unit into the inner cylinder of the concentrator through the concentrator door, and an extract installed on the extract supply line to transfer the extract. Extract supply unit consisting of a transfer pump; A vapor discharge unit connected to the concentrator door and configured to include a vapor discharge line for discharging water vapor generated by heating the liquid extract contained in the inner cylinder of the concentrator by double boiling, wherein the concentrator heater is operated by a control unit for 100 minutes. The temperature of the water in the double boiler is controlled to maintain the set temperature of 68 to 72°C for 120 minutes, so that the active ingredient is concentrated without destruction by high temperature through low-temperature concentration.

The stirrer includes a stirring tank that provides a mixing space in which the concentrate is added and an excipient made of starch for mixing with the concentrate to form granules is added, and the concentrate and the excipient are mixed. A rotary mixing part consisting of a rotary mixing member that rotates within the stirring tank to mix the concentrate and the excipient to produce a mixture, and a rotary driving part connected to the rotary mixing member to rotate the rotary mixing member; It may be configured to include a lifting drive unit configured to raise and lower the rotary drive unit, thereby causing the rotary mixing member to move to the upper part of the stirring bin or to be introduced into the stirring bin.

The granulation machine includes a mixture supply unit consisting of a mixture hopper into which the mixture is introduced, and a vibrating feeder unit installed at the bottom of the mixture hopper to forwardly transport the mixture discharged from the mixture hopper; A granule molding frame through which the mixture is supplied and received by the vibrating feeder unit and a granule molding hole is formed through the outer circumferential surface of the lower end; A granule impeller configured to be rotated inside the granule mold by an electric method, and to push the mixture contained in the granule mold to the granule mold hole to form a granule mold as the mixture passes through the granule mold. ; The granule mold is seated and supported in the central portion, collects the granule molded material discharged through the granule mold, and guides the collected granule molded material to be discharged toward the dryer. It may be configured to include a granule collection and discharge guide box. there is.

The dryer includes a rotary dryer disposed at a lower portion of one side of the granule collection and discharge guide container to receive the granule molding and to be driven to rotate by an electric method; A drying lamp unit installed at the top of the rotary drying tank to irradiate light to the granule molded material to dry it; It may be configured to include a mixing means that is inserted into the rotary drying bucket and mixes the granular material contained in the rotary drying bucket as the rotary drying bucket rotates.

The dryer may be configured to further include a drying blower that blows air toward the rotary drying tank to blow dry the granular material contained in the rotary drying container.

It may be configured to further include a packaging machine for packaging the dried granules manufactured by the dryer into a stick type.

The packaging machine supplies a packaging film in the form of a sheet, rolls the packaging film in the width direction and overlaps both ends to manufacture a primary packaging material in the form of a packaging tube and a tube in which wings are formed by overlapping both ends, and heats the wings. Secondary packaging is manufactured by fusion bonding and bonding and cutting the lower ends of the primary packaging, and when the dry granules are added to the secondary packaging, the upper end of the secondary packaging containing the dry granules is bonded and cut. a packaging material manufacturing department that ensures that packaging is completed; A dry granule hopper into which the dry granules are input, a screw-type granule transfer unit that transfers the dry granules discharged from the dry granule hopper to the packaging material manufacturing unit, and the dry granules supplied from the screw-type granule transfer unit to the secondary It may be configured to include a granule input unit configured to include a funnel former that guides the granule to be discharged into the open upper part of the packaging material.

The packaging material manufacturing unit may be configured with a printer that prints pharmaceutical information including at least one of a hospital name, patient name, and manufacturing date on the packaging film.

According to the above, the present invention can handle the entire granule manufacturing process of extraction-concentration-stirring-granule forming-drying-packaging in one batch, thereby increasing the process efficiency of granule manufacturing and producing granular medicine and granules without deterioration of the material. It is effective in producing high-quality edible granules such as health food.

In addition, the granule production system of the present invention allows the extractor to control the temperature of the hot water and generate eddy currents due to the convection phenomenon of the hot water, causing the inner cylinder of the extractor to repeatedly move the hot water to raise and lower the hot water level compared to the outer cylinder of the extractor, thereby damaging the granule material. The extraction of active ingredients is improved, and the concentrator performs low-temperature concentration by maintaining the temperature of 68-72°C, which has the effect of producing high-quality granules by ensuring concentration without destruction of the active ingredients by heat.

In addition, the entire granule manufacturing system is automatic or semi-automatic, and by minimizing material movement between each component, granule manufacturing time can be significantly shortened and productivity improved. In addition, granular herbal medicine can be manufactured by receiving prescription information from oriental medicine clinics, etc. It can be used as a reference for manufacturing, and in particular, by printing pharmaceutical information such as hospital name, patient name, manufacturing date, etc. along with the manufacturing of stick-type packaging, granule packaging and printing are unified, creating a close cooperative relationship with oriental medicine clinics, etc., and expanding the granular herbal medicine manufacturing industry. It can help with development.

In addition, the various and beneficial advantages and effects of the present invention are not limited to the above-described content, and may be more easily understood in the process of explaining specific embodiments of the present invention.

1 is a front view showing the configuration of a granule manufacturing system according to an embodiment of the present invention,
Figure 2 is a plan view showing the configuration of a granule manufacturing system according to an embodiment of the present invention;
Figure 3 is a diagram showing the specific configuration of the extractor of the granule production system according to an embodiment of the present invention;
Figure 4 is a diagram showing the specific configuration of the double boiler concentrator of the granule production system according to an embodiment of the present invention;
Figure 5 is a diagram showing the specific configuration of the granule molding machine of the granule production system according to an embodiment of the present invention;
6 and 7 are side and top views showing the specific configuration of the dryer of the granule production system according to an embodiment of the present invention;
Figure 8 is a diagram showing the specific configuration of the dryer of the granule production system according to an embodiment of the present invention;
Figure 9 is a diagram showing a packaging machine additionally configured to the granule manufacturing system according to an embodiment of the present invention;
Figure 10 is a view showing the packaging material forming part of the packaging machine of the present invention,
Figure 11 is a diagram showing the packaging material transfer part of the packaging machine of the present invention,
Figure 12 is a view showing the side adhesive portion and adhesive cutting portion of the packaging machine of the present invention;
Figure 13 is a diagram showing the operating state of the side adhesive part of the packaging machine of the present invention;
Figure 14 is a diagram showing the operating state of the adhesive cutting part of the packaging machine of the present invention,
Figure 15 is a diagram showing the configuration of the granule input section of the packaging machine of the present invention.

The above objects, other objects, features and advantages of the present invention will be easily understood through the following preferred embodiments related to the attached drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed content will be thorough and complete and so that the spirit of the present invention can be sufficiently conveyed to those skilled in the art.

In this specification, when an element is referred to as being on another element, it means that it may be formed directly on the other element or that a third element may be interposed between them. Additionally, in the drawings, the thickness of components is exaggerated for effective explanation of technical content.

Embodiments described in this specification will be explained with reference to cross-sectional views and/or plan views, which are ideal illustrations of the present invention. In the drawings, the thicknesses of films and regions are exaggerated for effective explanation of technical content. Therefore, the shape of the illustration may be changed depending on manufacturing technology and/or tolerance. Accordingly, embodiments of the present invention are not limited to the specific form shown, but also include changes in form produced according to the manufacturing process. For example, an etch area shown at a right angle may be rounded or have a shape with a predetermined curvature. Accordingly, the regions illustrated in the drawings have properties, and the shapes of the regions illustrated in the drawings are intended to illustrate a specific shape of the region of the device and are not intended to limit the scope of the invention. In various embodiments of the present specification, terms such as first and second are used to describe various components, but these components should not be limited by these terms. These terms are merely used to distinguish one component from another. Embodiments described and illustrated herein also include complementary embodiments thereof.

The terms used in this specification are for describing embodiments and are not intended to limit the invention. As used herein, singular forms also include plural forms, unless specifically stated otherwise in the context. As used in the specification, 'comprises' and/or 'comprising' does not exclude the presence or addition of one or more other elements.

In describing specific embodiments below, various specific details have been written to explain the invention in more detail and to aid understanding. However, a reader skilled in the art to understand the present invention will recognize that it can be used without these specific details. In some cases, it is mentioned in advance that when describing the invention, parts that are commonly known but are not significantly related to the invention are not described in order to prevent confusion without any reason in explaining the invention.

Hereinafter, with reference to the drawings, a granule manufacturing system according to an embodiment of the present invention will be described.

Referring to Figures 1 to 8, the granule manufacturing system of the present invention includes an extractor 100, a double boiler concentrator 200, a stirrer 300, a granulator 400, a dryer 500, and a controller 600. It is configured to do so. In the present invention, the extractor 100, double boiler concentrator 200, stirrer 300, granulator 400, dryer 500, and controller 600 are configured to be installed on the main body frame 101, and this main body frame (101) can be configured to achieve organic arrangement and combination between each component.

The extractor 100 is configured to produce a liquid extract by hot water extraction of granule material, which is a raw material for producing granules such as herbal medicine, food raw materials, etc. In the present invention, the extractor 100 may be comprised of one unit, or may be comprised of two or more extractors for individual hot water extraction of various medicinal ingredients.

Referring to FIGS. 1, 2, and 3, the extractor 100 is configured to include an extractor outer cylinder 110, an extractor inner cylinder 120, and an extractor heater 130.

The extractor outer cylinder 110 is fixedly installed on the main body frame 101, has a lower plate 112 with an extract discharge portion 113 on the bottom, and is installed vertically upward around the lower plate 112 to extract the extractor. It is configured to include a glass tube 114 into which the inner tube 120 is inserted and filled with water for hot water extraction, and an upper plate 116 that is installed around the upper end of the glass tube 114 and holds the extractor inner tube 120. do. Here, a valve (v) may be configured on the extract discharge unit 113 to be controlled to open and close by the controller 600.

The extractor inner cylinder 120 has a cylindrical shape with an open top, and is configured to have a plurality of hot water access holes 122 formed on the lower surface, and is configured to be provided with a lid 124 that covers the open top.

The extractor heater 130 is installed below the extractor outer cylinder 110 and is configured to heat the extractor outer cylinder 110. This heater 130 is configured to be controlled by the controller 600.

Granular materials such as various medicinal herbs can be introduced and accommodated inside the extractor inner cylinder 120, and the interior of the extractor outer cylinder 110 is configured to be filled with water for hot water extraction of the granular materials. At this time, since the extractor inner cylinder 120 and the extractor outer cylinder 110 communicate through the hot water inlet hole 122, the water filled in the extractor outer cylinder 110 also fills the inner cylinder 120 at the same water level.

In this way, the granular material is put into the extractor inner cylinder 120, and the extractor outer cylinder 110 is filled with water for hot water extraction, so that the granular material is submerged in water in the extractor inner cylinder 120.

In this state, when the extractor heater 130 drives and generates heat to heat the bottom of the extractor outer cylinder 110, the water inside is heated to generate hot water, and this hot water flows into the extractor according to the convection phenomenon (eddy current due to convection). A liquid extract is generated by hot water extraction of the active ingredient from the granular material contained in the inner cylinder 120.

The extractor heater 130 is installed at the lower center of the extractor outer cylinder 110, so that the lower center of the extractor outer cylinder 110 is heated to a higher temperature than the peripheral portion. Accordingly, the water contained in the extractor outer cylinder 110 is transferred to the extractor. As the water in the inner center of the outer cylinder 110 was heated more than the water at the inner edge, the water in the inner center of the extractor outer cylinder 110 convected upward, causing the water level in the extractor inner cylinder 120 to become higher than the water level in the extractor outer cylinder 110. The operation of the temporary extractor heater 130 is stopped, the temperature of the water decreases, the convection phenomenon weakens, and the water level of the extractor outer cylinder 110 becomes equal to the water level of the extractor inner cylinder 120 again.

As the extractor heater 130 is turned on and the water is heated and the temperature rises, the water level in the extractor inner cylinder 120 becomes higher than the outer cylinder 110, and then the extractor heater 130 is stopped and as the temperature decreases, the extractor inner cylinder 120 ) The extraction rate of the active ingredient for the granular material can be improved by repeating the process of lowering the water level to become the same as that of the outer cylinder 120.

Although not shown, a temperature sensor is configured to detect the internal water temperature inside the extractor inner cylinder 120 or the extractor outer cylinder 110, and the controller 600 operates the heater 130 according to the hot water temperature detected by this temperature sensor. ) can be configured to control.

Specifically, the heater 130 is operated by the controller 600 for 100 to 120 minutes when the temperature of the hot water reaches a set temperature of 91 to 93 ° C, and stops when the temperature reaches a set temperature of 99 to 101 ° C. It is controlled to produce a liquid extract.

Referring to Figures 1, 2, and 4, the double boiling concentrator 200 is configured to receive the liquid extract from the extractor 100 and remove moisture by using a double boiling method to produce a concentrate.

The double boiler concentrator 200 is configured to include a concentrator outer cylinder 210, a concentrator inner cylinder 220, a concentrator door 225, a door driver 230, and an extract supply unit 240.

The concentrator outer cylinder 210 is installed on the main body frame 101 and contains water for double boiling (hereinafter referred to as “bain boiling water”), and a concentrator heater 215 is installed on the bottom to heat the double boiling water to a predetermined temperature. do.

The concentrator inner cylinder 220 accommodates and stores the liquid extract supplied from the extractor 110, and is heated by the double boiler water contained in the pesticide outer cylinder 210, thereby heating the liquid extract contained inside in a double boil method to remove moisture from the liquid extract. It is configured to evaporate away in the form of water vapor to produce a concentrate.

The concentrator door 225 is configured to open and close the open upper part of the concentrator inner cylinder 220, and a viewing window 226 is provided at the center to visually check the concentration state of the concentrate generated inside the concentrator inner cylinder.

The door driving unit 230 is installed on the main body frame 101 and is configured to be connected to the concentrator door 225, raising and lowering the concentrator door 225 and rotating it left and right to move the pesticide door 225 to the open state. Alternatively, it is configured to move the position to a closed state by covering and sealing the concentrator inner cylinder 220, and the door driving unit 230 is made of a swing cylinder to enable up and down movement and left and right rotation of the concentrator door 225.

The extract supply unit 240 is made of a hose, one side of which is connected in communication with the inside of the concentrator door 225, and the other side of which is connected to the extract discharge unit 113, an extract supply line, and an extract supply line on this extract supply line. It consists of an extract transfer pump (p) that is installed and transfers the liquid extract discharged from the extract discharge unit 113 to the concentrator inner cylinder 220 through the concentrator door 225.

In addition, the present invention is configured to be connected to the concentrator door 225 on one side, and includes a vapor discharge portion 245 consisting of a vapor discharge line hose that discharges water vapor evaporated from the concentrate contained in the concentrator inner cylinder 220. do.

At this time, the other side of the steam discharge line hose of the steam discharge unit 245 is connected to a cooling condenser (not shown), and is configured to cool and condense the discharged water vapor and collect it through the condensate provided in the cooling condenser to discharge the condensate. You can.

In addition, the steam discharge unit 245 may include a transfer blower configured on the steam discharge line hose to transfer water vapor to the cooling condenser.

In the present invention, the concentrator heater 215 is configured to be controlled by the controller 600, and although not shown, a double boiler water temperature detection sensor is installed on the concentrator outer cylinder 210 to detect the temperature of the double boiler water, and the controller ( 600) may be configured to control the concentrator heater 215 according to the temperature detected by the double boiler water temperature sensor.

Specifically, the concentrator heater 215 is controlled by the controller 600 to maintain the temperature of the double boiler water at a set temperature of 68 to 72°C for 100 to 120 minutes, so that the concentrate is concentrated at low temperature and the active ingredients are removed by high temperature. Can be concentrated without destruction.

The stirrer 300 is configured to prepare a mixture by stirring and mixing the concentrate with excipients to produce stirred granules.

Referring to FIGS. 1, 2, and 5, the stirrer 300 is configured to include a stirring container 310, a rotating mixing unit 320, and an elevating drive unit 330.

The stirring tank 310 is a main body frame to provide a mixing space where the concentrate produced in the concentrator 200 is added, an excipient made of starch is added to the concentrate, and the concentrate and excipient (starch) are mixed. It is installed at (101).

The rotary mixing unit 320 includes a rotary mixing member 324 that mixes the concentrate and excipients while rotating in the stirring tank to create a mixture, and is connected to the rotary mixing member 324 to rotate the rotary mixing member 324. It is configured to include a rotation drive unit 322. The rotation drive unit 322 is configured to include a drive motor 321 and an extension shaft 323 that is coupled to the rotation axis of the drive motor 321 and to which the rotation mixing member 324 is coupled to the bottom. This rotation drive unit 322 is controlled by the controller 600 to control the rotation speed and rotation time of the rotation mixing member 324.

The lifting drive unit 330 is made of a cylinder module such as a pneumatic cylinder or an electric cylinder, and is installed on the main body frame 101, and is configured so that the expansion rod 332 of the cylinder is coupled to the rotation drive unit 322, and the rotation drive unit ( 322) is configured to be controlled to raise and lower under the control of the controller 200. As the rotary drive unit 322 is raised and lowered, the rotating mixing member 324 moves away from the top of the stirring tank 310 in the standby state and is introduced into the stirring tank 310 when in use, thereby allowing mixing of the concentrate and excipients. .

Meanwhile, in the present invention, the stirrer 300 is configured to connect the stirring tank 310 and the concentrator inner cylinder 220, and the concentrate supply line supplies the concentrate concentrated in the pesticide inner cylinder 220 into the stirring tank 310. It may be configured to further include (not shown), and a concentrate transfer pump may be configured on this concentrate supply line (not shown), and may be configured to be driven and controlled by the controller 600.

In addition, although not shown, in the present invention, the stirrer 300 consists of an excipient storage unit in which excipients made of starch are stored, and a screw-type transferer for transferring and discharging the starch stored in the excipient storage unit to the stirring tank 310. An excipient supply means including an excipient transfer unit may be further configured, and in this case, the excipient transfer unit may be controlled by the controller 600.

The granule molder 400 is configured to mold the mixture of concentrate and excipients mixed by the stirrer 300 into granules and supply the molded granules (hereinafter referred to as “molded granules”) to the dryer 500. .

Referring to FIGS. 1, 2, 6, and 7, the granule molding machine 400 includes a granule molding frame 410, a mixture supply unit 420, a granule impeller 430, and a granule collection and discharge guide container 440. It is designed to include

The granule mold 410 accommodates the mixture of concentrate and excipients supplied by the mixture supply unit 420, and is configured to have a granule mold hole 412 formed on the outer peripheral surface of the lower end. This granule molding frame 410 is configured to be seated and installed in the central part of the granule collection and discharge guide container 440.

The mixture supply unit 420 consists of a mixture hopper 421 into which the mixture is introduced, and a vibration feeder unit 422 and 423 that moves the mixture discharged from the mixture hopper 421 forward and discharges it into the granulation mold 410. The vibration feeder units 422 and 423 are driven and controlled by the controller 600 and are connected to a feeder drive unit 422 that generates vibration, and the feeder drive unit 422 is connected to the mixture to vibrate by vibration generated from the feeder drive unit 422. It is configured to include a transfer chute 423 that transfers and discharges the mixture discharged from the hopper 421 to the granule mold 410.

The granule impeller 430 is configured to rotate in a motor-driven manner by the drive motor 432 installed on the main body frame 101, and is placed at the inner lower part of the granule mold 410 and rotates, thereby forming the granule. The mixture supplied into the mold 410 is pushed in close contact with the granule molding hole 412, so that the mixture is extruded into a granule molding product through the granule molding hole 412.

At this time, the drive shaft of the drive motor 432 is configured to protrude through the center of the granule collection and discharge guide tube 440 and protruding inside the lower part of the granule mold 410, and is combined with the granule impeller 430 to drive the drive motor ( The granule impeller 430 may be configured to rotate by the drive shaft of 432). The drive motor 432 is configured to control the rotation speed or rotation time under the control of the controller 600.

The granule collection and discharge guide box 440 is configured so that the granule mold 410 is seated and installed at the center and surrounds the lower circumference of the granule mold 410, and the granule mold 410 is installed in the granule mold 410. It is configured so that the granular molded material discharged through the molding falls and is collected, and a discharge guide portion 441 that guides the collected granular molded material to discharge toward the dryer 500 may be configured on one side.

The dryer 500 is configured to thermally dry the granulated material, and is additionally configured to add blow drying to complete the dried granules through drying.

Referring to FIGS. 1, 2, and 8, the dryer 500 is configured to include a rotary drying tank 510, a mixing means 530, and a drying lamp unit 535.

The rotary drying tank 510 is configured to be disposed on one side of the granule collection and discharge guide container 440, specifically at the lower part of the discharge guide part 441, and is configured to receive and accommodate the granule molded material discharged through the discharge guide part 441. It is configured so that the central part is coupled to the drive shaft of the drive motor 520 installed on the main body frame 101, and is configured to be rotated in an electric manner by the drive motor 520. This drive motor 520 is configured to have its rotation speed or rotation time controlled by the controller 600.

The mixing means 530 is configured to be fixedly supported on the support frame 540 connected to the main body frame 101, and is inserted into the rotary drying tank 510 and is rotated according to the rotation of the rotary drying tank 510. The granular material contained in (510) is mixed and dried efficiently. This mixing means 530 may be configured in the form of a fork as shown in the drawing, but its shape is not limited and of course can be configured in various forms.

The drying lamp unit 535 may be made of an optical lamp that generates heat, such as a halogen, and is fixed to the support frame 540. It is controlled by the controller 600 and irradiates light to the granular molded material to dry the granular molded material. It is configured to produce dry granules. This drying lamp unit 535 is controlled by the controller 600.

Meanwhile, although not shown, a drying blower may be further configured to be fixed to the support frame 540 and blow air toward the dried granule material contained in the rotary drying tank 510 to achieve blow drying.

In the present invention, the support frame 540 is configured to be height-adjustable with respect to the main body frame 101, and the separation distance between the granule molded material contained in the rotary drying tank 510, the drying lamp unit 535 and the drying blower, and the rotary drying tank 510. It is configured to adjust the depth of the mixing means 530 that penetrates the granular material contained in (510).

The support frame 540 includes a vertical bar 545 configured to be adjusted up and down in a sliding manner on the lifting guide 544 installed on the main body frame 101, and a rotary drying tank 510 from the top of the vertical bar 545. A first support bar 541 is installed at a right angle toward the upper space and the drying lamp unit 535 and a drying blower are coupled and installed downward, and is installed at a right angle downward from the first support bar 541 and mixing at the bottom. The means 530 penetrates the second support bar 542 and the lifting guide 544, which are detachably coupled, in a screw-fastened manner, and pressurizes the vertical bar 545 as it is tightened to secure the drying lamp unit 535. ), drying blower, and a fixing locking member 546 that fixes the adjusted height of the mixing means 530.

The controller 600 includes a control unit that controls the control configuration comprised of the extractor 100, concentrator 200, stirrer 300, granulator 400, and dryer 500, and an extractor operated by the control unit according to the user's operation input. It is configured to include an operation panel 610 to control the operation of the concentrator 200, the stirrer 300, the granulator 400, and the dryer 500.

The operating panel 610 may be configured to include a touch screen that outputs control status information of the extractor 100, concentrator 200, stirrer 300, granulator 400, and dryer 500 on the screen, Input by the user can be done through screen input on a touch screen, or it can be configured to operate by a separate button, switch jog, or dial-type control unit.

For example, the operation panel 610 may provide an interface screen for receiving user operation information through a touch screen. For example, the operation panel 610 provides extraction setting information such as extraction time and extraction temperature for the extractor 100, concentration setting information such as concentration time and concentration temperature for the concentrator 100, and stirring for the stirrer 300. Stirring setting information such as rotation time and stirring rotation speed, granule molding setting information such as the rotation speed of the granule impeller for the granule molding machine 400 and the conveying speed of the vibrating feeder unit, lamp operation time and blower operation time for the dryer 500. An interface screen can be provided to receive drying setting information such as the rotation speed of the rotary drying tank, and the controller 600 receives extraction setting information, concentration setting information, and stirring setting information input from the user through the operation panel 610. , can be configured to control each configuration according to granule molding setting information and drying setting information. In addition, the operation panel 610 may be provided with a manual operation unit that manually turns on/off the operations of the extractor 100, concentrator 200, stirrer 300, granulator 400, and dryer 500.

Meanwhile, the controller 600 of the present invention can be configured to receive and store herbal medicine prescriptions issued from oriental medicine clinics through wired or wireless communication and USB memory, output them on the screen of the operation panel 610, and manufacture granules according to the prescriptions. , Preferably, the controller 600 automatically controls the extractor 100, concentrator 200, stirrer 300, granulator 400, and dryer 500 according to the prescription included in the herbal medicine prescription to produce granules according to the prescription. It can be configured to manufacture a mold drug.

Hereinafter, referring to FIGS. 9 to 15, the granule production system of the present invention is configured to further include a packaging machine 700 for packaging the dried granules manufactured by the dryer 500 into a stick type.

The packaging machine 700 is configured to include a packaging material manufacturing unit 701 and a granule input unit 703 for injecting dry granules into the stick-type packaging material manufactured by the packaging material manufacturing unit 701.

The packaging material manufacturing unit 701 supplies a sheet-shaped packaging film (f), rolls the packaging film (f) in the width direction so that both ends overlap, and forms a tube-shaped primary packaging material with wings (pa) where both ends overlap. (p1) is manufactured, the wings (pa) of the primary packaging material (p1) are bonded by heat fusion, and the lower ends of the primary packaging material (p1) are bonded and cut to manufacture the secondary packaging material (p2), 2 The stick-type granule product (g) is completed by gluing and cutting the upper part of the secondary packaging material (p2) containing the dry granules while the dry granules are injected into the tea packaging material (p2).

The packaging material manufacturing unit 701 includes a packaging film supply unit 710, a packaging material forming unit 720, a packaging material transfer roller 725, a side adhesive unit 730, an end adhesive and cutting unit 740, and an adhesive driver unit 750. It is configured to do so.

The packaging film supply unit 710 includes a packaging roll 711 in which the packaging film f is wound in a roll shape, and a guide that guides the packaging film f unrolled from the packaging roll 711 to the packaging material forming unit 720. It consists of a roller 712.

Referring to FIGS. 9 and 10, the packaging material molding unit 720 guides the packaging film f supplied through the packaging film supply unit 710 so that the packaging film f is rolled in the width direction to form a tube shape as it passes. Both ends of the packaging film (f) are overlapped and guided to form wings (pa), allowing molding into the primary packaging material (p1).

The packaging material molding part 720 includes a circular guide hole 721a that guides the packaging film f to be rolled into a tube shape, and is formed to extend on one side of the circular guide hole 721a to form a wing portion pa. A first forming block 721 composed of a guiding wing-forming guide hole 721b, and both ends of the packaging film f installed at the top of the first forming block 721 and spaced apart from each other are inclined so as to be brought together. A packaging film (f) formed by an inclined guiding groove (722a), the upper end of which is connected to the lower end of the inclined guiding groove (722a), and the lower end of which is formed with the wing-forming guide hole (721b) and collected by the inclined guiding surface (722a). It is configured to include a second forming block 722 configured with a wing guide groove 722b that guides both ends of the wing forming guide hole 721b.

As the packaging film (f) passes through the circular guide hole (721a), it becomes a rolled tube shape, and both ends of the packaging film (f) are gathered by the inclined guide groove (722a) and wings are formed through the wing guide groove (722b). A wing portion (pa) may be formed while passing through the guide hole 721b.

Referring to Figures 9 and 11, the packaging material transport roller 725 rotates in opposite directions to extrude and transport the wing part (pa) downward, and is connected to the transport motor 726 and the power transmission gear part 727. It is connected by a motor drive method to transport the packaging material formed in a tube shape to the lower part.

Referring to FIGS. 9, 13, and 14, the side adhesive portion 730 is a hot plate adhesive method, and the side adhesive member 730 is configured to achieve thermal bonding by pressing the overlapping wings (pa) by heat. am.

The side adhesive portion 730 is installed on the main body frame 101 so as to be disposed between the upper part of the packaging material transport roller 725 and the lower part of the packaging material molding part 720, and is a pair of sides configured to enable the movement of being brought together or spread apart. It is configured to achieve thermal bonding by compressing the overlapping wing portions (pa) by the thermal bonding member 731. The pair of side thermal adhesive members 731 may be made of a hot plate.

The side adhesive portion 730 is configured to be rotatable on a pair of hinge axes 733 installed on the main body frame 101, and is configured so that a pair of side thermal adhesive members 731 are connected to the distal end to form a pair of side heat adhesive members. A pair of pivoting bars 732 are formed to enable the adhesive members 731 to come together and contact each other or to be spaced apart from each other.

This pair of rotating bars 732 is connected to the motor-driven adhesive driving unit 750, and a pair of side thermal adhesive members 731 are formed through a rotational movement in which they open or come together according to the driving of the adhesive driving unit 750. It is configured to perform an adhesion operation.

The wings (pa) of the first packaging material (p1), which is formed into a tube-shaped packaging material while passing through the packaging material forming unit 720, overlap each other, but are not glued, and this first packaging material (p1) is attached to the side adhesive portion (730). ), the wing parts (pa) are heat-compressed and bonded to each other, thereby creating a second packaging material (p2) to which the wing parts (pa) are bonded.

The end adhesion and cutting part 740 is installed on the main body frame 101 to be placed below the packaging material transfer roller 725, and attaches the end of the tube-shaped secondary packaging material (p2) to which the wing portion (pa) is glued. and configuration for cutting.

The end adhesion and cutting part 740 adheres and cuts the lower part of the secondary packaging material (p2), and the dry granules are released through the open upper part of the secondary packaging material (p2) whose lower end is sealed by the granule input part 703. When inserted, the upper end of the secondary packaging material (p2) containing the dry granules is glued and cut to complete a single packaged stick-type granule product (g).

The end adhesion and cutting portion 740 is configured to allow the front and rear sides of the secondary packaging material (p2) to be gathered together or spread apart, and is a first end thermal bonding member made of a heating plate that bonds the longitudinal ends of the secondary packaging material (p2). It is configured to include (741), a second end thermal bonding member (742), and a cutting blade (743) for cutting the secondary packaging material (p2) in the bonded state.

The end adhesion and cutting part 740 has a pair of forward and backward movement axes 744 configured to move forward and backward with respect to the main body frame 101 along the forward and backward transfer guides 744a installed on the main body frame 101, and move back and forth at both ends. The shaft 744 penetrates and is configured to slide along the forward and backward moving axis 744, and the first end thermal bonding member 741 is fixedly installed so that the first end thermal bonding member 741 moves forward and backward moving axis 744. A slider 745 that moves back and forth along, both ends of which are fixedly installed to connect the front ends of a pair of back and forth movement bars 744, and is fixedly installed to be connected to the second end thermal adhesive member 742 by a spring 747. The bar 746 is configured to further include a coupling bar 748 at both ends of which are coupled and fixed to the forward and backward movement axis 744.

The present invention consists of an adhesion drive unit 750 for driving the adhesion operation of the side adhesion unit 730 and the end adhesion and cutting unit 740.

The adhesive drive unit 750 includes a motor 751, a vertical drive shaft 752 configured to transmit power of the motor 751 and enable forward and reverse rotation according to the driving of the motor 751, and a vertical drive shaft 752 of the motor 751. A first power transmission unit 753 that transmits driving force to the vertical drive shaft 752, a second power transmission unit 754 that transmits rotation of the vertical drive shaft 752 to the side adhesive portion 730, and a first power transmission unit. It is configured to include a third power transmission unit 755 that transmits the power of the unit 753 to the end bonding and cutting unit 740.

The first power transmission unit 753 includes a cam member 753a coupled to the rotation shaft 751a of the motor 751, an angle rotation bar 753b coupled to the lower end of the vertical drive shaft 752, and a cam member 753a. ) is composed of a first link section (753c) configured to connect the eccentric axis of the angle rotation bar (753b) and one end of the angle rotation bar (753b), and rotates left and right with the angle rotation bar (753b) as the motor 751 is driven, thereby driving the vertical drive shaft. It is configured to rotate (752) in one direction at a predetermined angle and in the other direction at a predetermined angle.

The second power transmission unit 754 connects a power transmission disk 754a coupled to the top of the vertical drive shaft 752, both sides of the power transmission disk 754a, and a pair of rotating bars 732, respectively. It consists of a pair of second link segments 754b that transmit power to open or close a pair of pivot bars 732 according to forward and reverse rotation of the power transmission disk 754a. Accordingly, when the rotational force of the motor 751 is transmitted to the vertical drive shaft 752 through the first power transmission unit 753, the power transmission disk 754a rotates according to the rotation of the vertical drive shaft 752a, and the side adhesive portion 730 ) is configured to operate to open or retract a pair of rotating bars 732 so that an adhesion operation of a pair of side thermal bonding members 731 is performed.

The third power transmission unit 755 is configured to connect the other end of the angle rotation bar 753b and the slider 745, and pushes the slider 745 according to one-way rotation of the angle rotation bar 753b to heat the first end. The third link section 755a, which moves the adhesive member 741 forward or pulls the slider 745 according to rotation in the other direction to move the first end thermal adhesive member 741 backward, and the angle rotation bar 753b It is configured to connect one end and the coupling bar 748, and moves the forward and backward movement axis 744 coupled with the coupling bar 748 rearward according to the one-way rotation of the angle rotation bar 753b, thereby forming a thermal bonding member at the first end. (741) is moved backward to get closer to the second end thermal bonding member (742), or the forward and backward movement axis (744) coupled to the coupling bar (748) is moved forward according to the rotation of the angle rotation bar (753b) in the other direction. It is configured to include a fourth link section 755b that moves the first end thermal bonding member 741 forward and away from the second end thermal bonding member 742.

Referring to FIGS. 9 and 14, with the second packaging material (p2) positioned between the first end thermal adhesive member 741 and the second end thermal adhesive member 742, according to the driving of the adhesive driving unit 750. As the first end thermal adhesive member 741 and the second end thermal adhesive member 742 come closer to each other and come into close contact, adhesion and cutting to the end of the second packaging material (p2) can be performed.

A cutting groove 741a into which a cutting blade 743 is inserted is formed in the first end thermal bonding member 741, and a cutting blade 743 is drawn out and retracted from the opposite end of the second end thermal bonding member 742. A blade entry and exit groove 742a is formed.

When the first end thermal adhesive member 741 and the second end thermal adhesive member 742 move in a direction closer to each other as the adhesive driving unit 750 is driven, they are closely adhered to each other and form the second packaging material (p2). ) is in progress, and in this adhesion situation, the cutting blade 743 is in a state where the blade entry/exit groove 742a is retracted, and after adhesion of the second packaging material p2 is performed, the first end heats up additionally. When the adhesive member 741 and the second end thermal adhesive member 742 come into close contact with each other and pressurize each other, the spring 747 is compressed and the cutting blade 743 comes out of the blade entrance and exit groove 742a and enters the cutting groove 741a. As it is inserted, cutting is performed on the end of the second packaging material (p2).

Referring to Figures 10 and 15, the granule input unit 703 transfers the dry granule hopper 760 into which dry granules are input, and the dry granules discharged from the dry granule hopper 760 to the packaging material manufacturing unit 701. To include a screw-type granule transfer unit 762 and a funnel former 770 that guides the dry granules supplied from the screw-type granule transfer unit 762 to be discharged and introduced into the open upper part of the secondary packaging material (P2). It is composed.

The screw-type granule transfer unit 762 is connected to the dry granule hopper 760 and is connected to a transfer cylinder 763 that receives dry granules from the dry granule hopper 760, and a drive motor 764 to provide a drive motor 764. As the drive rotates within the transfer cylinder 763, the dry granules supplied to the transfer cylinder 763 advance and fall to the top of the funnel former 770, and are supplied to the funnel former 770 using a screw 765. It is composed.

The funnel former 770 is connected to the funnel 772, into which the dry granules discharged through the screw-type granule transfer unit 762 are introduced, and is formed in the form of a tube of the same predetermined length, and has a granule discharge hole at the bottom. It is configured to include a granule discharge pipe 774 that discharges dry granules to the second packaging material (p2) through (775).

As shown in FIG. 10, the granule discharge pipe 774 is configured to pass inside the circular guide hole 721a of the packaging material molding part 720, and the packaging film f is formed in a tube shape while passing through the circular guide hole 721a. 1 Molding into packaging material (p1) can be done more easily.

The granule discharge pipe 774 is manufactured from the packaging molding part 720 and is disposed to be inserted into the first packaging material (p1) and the second packaging material (p2), and the granule discharge hole 775 formed at the bottom of the granule discharge pipe 774. ) is configured to discharge and inject the dry granules into the part of the second packaging material (p2) extending to the lower part of the.

In the present invention, the controller 600 controls the operation of the screw-type granule transfer unit 762, the packaging material transfer roller 725, the side adhesive unit 730, the end adhesive and cutting unit 740, and the adhesive driver 750. You can.

In addition, in the present invention, the packaging material manufacturing unit 701 may include a printer 715 that prints at least one of the hospital name, patient name, and manufacturing date information on the packaging film.

The printer 715 is configured to be controlled by the controller 600, and the controller 600 can be configured to print, for example, the hospital name on the prescription, the patient's name, and the manufacturing date entered by the user on the packaging material. . Meanwhile, the operation panel 610 of the controller 600 provides an input screen for inputting pharmaceutical information such as hospital name, patient name, and manufacturing date from the user, and the controller 600 converts the pharmaceutical information entered by the user into a packaging film. The printer 715 can be controlled to print.

Although the present invention has been shown and described in connection with preferred embodiments for illustrating the principles of the present invention, the present invention is not limited to the configuration and operation as shown and described. Rather, those skilled in the art will be able to understand that many changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims. Accordingly, all such appropriate changes, modifications and equivalents shall be considered to fall within the scope of the present invention.

100...extractor
110...Extractor outer cylinder
112...lower plate
114...glass tube
116...top part
120...Extractor inner tube
130...Extractor heater
200...Concentrator
210...Concentrator external cylinder
215...Concentrator heater
220...Concentrator inner tube
225...Concentrator door
230...Door drive eastern part
240...Extract supply department
300...agitator
310...Stirring container
320...rotating mixing section
322..Rotary drive eastern part
324...rotating mixing member
330...Eastern part of the hatch
400...Granule molding machine
410...Granule molding mold
412...Granule molding hole
420...Mixture supply section
430...granular impeller
440... Granule collection and discharge guide box
500...dryer
510...rotary drying tank
530...mixing means
535...dry lamp unit
600...Controller
610...Operation panel
700...packer
701...Packaging Material Manufacturing Department
703...Granule input unit
710...packaging film supply department
720...Packaging material molding part
725...packaging material transfer roller
730...Side adhesive part
740...End adhesion and cutting part
750...Adhesive drive eastern part
760...Dry granule hopper
762...Screw type granule transfer unit
770...funnel former

Claims (9)

An extractor for producing a liquid extract by hot water extraction of granular material;
A double-boiling concentrator equipped with an extract supply line connected to the extractor, receiving the liquid extract through the extract supply line and removing moisture through a double boiling method to produce a concentrate;
A stirrer for preparing a mixture by stirring and mixing the concentrate and excipients to produce stirred granules;
A granule molder that supplies the mixture mixed by the stirrer to a granule mold through a vibrating pipe and molds the mixture into granules through a granule mold hole formed in the granule mold to produce a granule molded product;
A dryer that dries the granulated material to complete dried granules;
A controller consisting of a control unit that controls the extractor, concentrator, stirrer, granulator, and dryer, and an operating panel that allows the control unit to control the extractor, concentrator, stirrer, granulator, and dryer according to user input. A granule manufacturing system comprising:
According to claim 1,
The extractor,
An extractor inner cylinder in which granular materials are accommodated and a hot water inlet hole is formed on the bottom surface so that a liquid extract is produced by hot water flowing in through the hot water inlet hole;
A lower plate fixed to the main body frame and having an extract discharge part on the bottom, a glass tube installed vertically around the lower plate into which the extractor inner tube is inserted and filled with water for hot water extraction, and an upper circumference of the glass tube an extractor outer cylinder including an upper plate installed on the extractor inner cylinder;
An extractor heater installed on the lower side of the lower plate portion to heat the water contained in the extractor outer cylinder to generate hot water, and the generated hot water flows into the inner cylinder of the extractor through the hot water entrance hole by a convection phenomenon to generate a liquid extract; Includes,
The extractor heater is operated by the control unit when the temperature of the hot water reaches a set temperature of 91 to 93 ° C for 100 to 120 minutes, and is stopped when the temperature is set to 99 to 101 ° C. It is controlled to generate a liquid extract. granule manufacturing system.
According to claim 2,
The concentrator,
A concentrator outer cylinder that is installed on the main body frame, contains water for double boiling, and is heated by a concentrator heater installed on the bottom to heat the double boiling water to a predetermined temperature;
It is configured to be seated at predetermined intervals inside the concentrator outer cylinder, and the liquid extract supplied from the extractor through the extract supply line is accommodated, and the liquid extract is water-boiled by the heated water contained in the concentrator outer cylinder. The inner tube of the concentrator from which this is removed to produce a concentrate;
A concentrator door that opens and closes the open top of the concentrator inner cylinder and is provided with a viewing window to check the concentration state of the concentrate in the concentrator inner cylinder from the outside;
A door driving unit installed on the main body frame in connection with the concentrator door and consisting of a swing cylinder to open and close the concentrator door by moving it up and down and rotating it left and right;
An extract supply line connecting the concentrator door and the extract discharge unit to supply the liquid extract discharged through the extract discharge unit to the inner cylinder of the concentrator through the concentrator door, and an extract installed on the extract supply line to transfer the extract. Extract supply unit consisting of a transfer pump;
It includes a vapor discharge unit connected to the concentrator door and configured to include a vapor discharge line for discharging water vapor generated when the liquid extract contained in the inner cylinder of the concentrator is heated by double boiling,
The concentrator heater is controlled by the control unit to maintain the temperature of the double boiler water at a set temperature of 68 to 72°C for 100 to 120 minutes, and is controlled to concentrate without destroying the active ingredient due to high temperature through low-temperature concentration. granule manufacturing system.
According to claim 1,
The stirrer,
A stirring tank providing a mixing space in which the concentrate is added and an excipient made of starch for mixing with the concentrate to form granules is added, and the concentrate and the excipient are mixed.
A rotary mixing part consisting of a rotary mixing member that rotates within the stirring tank to mix the concentrate and the excipient to produce a mixture, and a rotary driving part connected to the rotary mixing member to rotate the rotary mixing member;
A granule manufacturing system comprising a; an elevating drive unit configured to raise and lower the rotary drive unit to cause the rotary mixing member to move to the upper part of the stirring container or to be introduced into the stirring container.
According to claim 1,
The granulation machine,
A mixture supply unit consisting of a mixture hopper into which the mixture is introduced, and a vibrating feeder unit installed at the bottom of the mixture hopper to forwardly transport the mixture discharged from the mixture hopper;
A granule molding frame through which the mixture is supplied and received by the vibrating feeder unit and a granule molding hole is formed through the outer circumferential surface of the lower end;
A granule impeller configured to be rotated inside the granule mold by an electric method, and to push the mixture contained in the granule mold to the granule mold hole to form a granule mold as the mixture passes through the granule mold. ;
The granule mold is seated and supported in the central portion, collects the granule molded material discharged through the granule mold, and guides the collected granule molded material to be discharged toward the dryer. Characterized in that it includes a granule collection and discharge guide box. granule manufacturing system.
According to claim 5,
The dryer,
a rotary drying container disposed at a lower portion of one side of the granule collection and discharge guide container to receive the granule molding material and to be driven to rotate by an electric method;
A drying lamp unit installed at the top of the rotary drying tank to irradiate light to the granule molded material to dry it;
A granule manufacturing system comprising a mixing means inserted into the rotary drying tank and mixing the granule molded material contained in the rotary drying container as the rotary drying container rotates.
According to claim 6,
The dryer
A granule manufacturing system further comprising a drying blower that blows air toward the rotary drying tank to blow dry the granular material contained in the rotary drying container.
According to claim 1,
A granule manufacturing system further comprising a packaging machine that packs the dried granules manufactured by the dryer into a stick type.
According to claim 8,
The packaging machine,
A packaging film in the form of a sheet is supplied, the packaging film is rolled in the width direction and both ends overlap to manufacture a packaging tube and a tube-shaped primary packaging material in which wings are formed by overlapping both ends, and the wings are bonded by heat fusion. Secondary packaging is manufactured by gluing and cutting the lower ends of the primary packaging material, and when the dry granules are added to the secondary packaging material, the packaging is completed by gluing and cutting the upper end of the secondary packaging material containing the dry granules. Packaging material manufacturing department that makes it possible;
A dry granule hopper into which the dry granules are input, a screw-type granule transfer unit that transfers the dry granules discharged from the dry granule hopper to the packaging material manufacturing unit, and the dry granules supplied from the screw-type granule transfer unit to the secondary It is configured to include a granule input unit configured to include a funnel former that guides the discharge to the open upper part of the packaging material,
The granule manufacturing system, wherein the packaging material manufacturing unit is configured with a printer that prints pharmaceutical information including at least one of a hospital name, patient name, and manufacturing date on the packaging film.

Images