JPH07115236B2 - Powder compression molding method - Google Patents

Abstract

A method for molding powder under compression by use of a compression molding machine including a horizontally supported turntable provided with bores vertically extending therethrough, and upper pressure rods and lower pressure rods respectively positioned above and below the respective bores, the upper end portion of each lower pressure rod being fitted in the corresponding bore. The method includes subjecting powder contained in each bore to preliminary compression by dropping the corresponding upper pressure rod into the bore by gravity before the compression molding operation. <IMAGE>

Description

Description: TECHNICAL FIELD The present invention relates to a method for compression-molding powder, which is carried out to produce a powder-molded article such as a tablet.

(Prior Art) When compressing powdered medicines, foods, bath agents and the like into tablets, a rotary powder compression molding machine is usually used. This powder compression machine, also called a tablet machine or a tablet machine, has a rotating horizontal disk-shaped turntable. The turntable is provided with a large number of die holes penetrating in the vertical direction at equal intervals in the rotation direction. Above and below each die hole of the rotary disc, a pair of upper and lower punches, which move up and down while moving together with the rotary disc, are provided corresponding to the respective die holes.

The production of tablets by such a rotary powder compression molding machine is performed as follows. A lower punch is fitted into each die hole from below, and the lower end portion of each die hole is always closed by the lower punch portion. Then, the lower punches descend in the die holes following the rotation of the turntable, and the die holes are successively filled with powder. When the die hole is filled with the powder, the lower punch and the upper punch are pressed by the preload roller and the main pressure roller, respectively, in order to compression-mold the powder. As a result, the powder is compression molded into tablets in the die hole. Then, the tablet formed in the die hole is lifted up by the lower punch and pushed out of the die hole by the lower punch to be taken out. In this way, the tablets are sequentially manufactured in each die hole while the turntable rotates once.

(Problems to be Solved by the Invention) In the production of tablets using such a rotary powder compression molding machine, the air contained in the powder is discharged to the outside of the powder by the compression by the preload roller. Therefore, when the powder is compressed by the main pressure roller, the occurrence of capping and lamination is suppressed, and further, the ejection of powder from the gap between the upper punch and the lower punch and the die hole is also suppressed. In particular, when compressing a powder with good flowability into tablets,
Such problems rarely occur.

However, when tableting a powder containing a large amount of a waxy substance such as vitamin E or a liquid substance, the temperature inside the mortar changes with time due to frictional heat between the upper and lower pestle and the mortar. When the tableting continues for a long time, the wax-like substance in the powder filled in the mortar is softened by the temperature rise in the mortar. In this way, when the wax-like substance is softened, the gap between the upper punch and the lower punch and the die hole is closed by the softened wax-like substance, the powder is not sufficiently deaerated, and the produced tablets are capped or capped. Lamination may occur. Further, since the air in the powder is suddenly ejected from the narrow gap between the upper punch and the lower punch and the die hole, a large amount of the powder leaks from the die hole together with the ejected air, and Weight fluctuations occur. Also, a large amount of powder leakage occurs from the unblocked mortar. The powder leaked from the die hole may enter into the details of the compression molding machine and cause abnormal wear of the details.

Such a phenomenon that occurs when the temperature in the die hole rises slows down the operation speed of the compression molding machine to suppress the generation of frictional heat between the upper and lower punches and the die hole, or To some extent, it is suppressed by reducing the speed so that degassing can follow. However, by reducing the operating speed of the compression molding machine, the production efficiency is significantly reduced.

The present invention is to solve the above-mentioned conventional problems, and an object thereof is to reliably deaerate a powder having poor deaerating property at high speed by compression molding, thus preventing occurrence of capping, lamination and the like. The object of the present invention is to provide a powder compression molding method.

(Means for Solving the Problems) The powder compression molding method of the present invention is, in a rotating plate that rotates in a horizontal state, in a die hole provided penetrating in the vertical direction,
The powder is filled in a state where the lower punch part of the lower punch is fitted from below, and the upper punch part of the upper punch is fitted into the die hole from above, and the powder is pressed by pressing the lower punch and the upper punch. A powder compression molding method of compression molding, characterized in that the upper punch part of the upper punch adjusted to a predetermined weight is dropped into a die hole filled with powder and precompressed by its own weight. Therefore, the above object is achieved.

(Example) Hereinafter, the present invention will be described with reference to Examples.

FIG. 1 shows a rotary powder compression molding machine used for carrying out the powder compression molding method of the present invention, and the powder compression molding machine includes a rotating disk 10 which is in a horizontal state. The turntable
A large number of through-holes 11 penetrating in the vertical direction are provided in the rotary disk 10 at equal intervals in the rotary direction.

A cylindrical mortar 60 is installed in each through hole 11. Each mortar 60 has a mortar hole 61 penetrating vertically.
The inner diameter of each die hole 61 is constant in the vertical direction.

A pair of lower punches 31 and upper punches 32 are provided corresponding to the lower and upper sides of the die holes 61 of each die 60 installed on the turntable 10 corresponding to the die holes 61. Each lower pestle 31 is a columnar lower pestle body 31a in a vertical state.
And a cylindrical lower punch part 31b projecting upward from the lower punch body part 31a in a concentric state, and by lowering each lower punch 31 as a whole, the lower punch part 31b of the die 60 is formed. It is fitted into the die hole 61. The outer diameter of each lower punch 31b is substantially equal to the inner diameter of the die hole 61. A guide roller 31c is attached to the lower part of each lower punch main body 31a with its axial direction in the horizontal state.

Each upper punch 32 has a columnar upper punch main body 32a in a vertical state.
And an upper punch part 32b concentrically projecting downward from the upper punch body part 32a, and the entire upper punch 32 is lowered, so that the upper punch part 32b is made into a die hole 61 of the die 60. Fit inside. The outer diameter of the upper punch part 32b is substantially equal to the inner diameter of the die hole 61. At the top of each upper punch body 32a, a guide roller 32c
However, it is attached with the axial direction being horizontal. Further, a guide roller 32d is similarly attached to a central portion in the up-down direction on the half body side of the upper punch main body portion 32a on which the guide roller 32c is attached.

Each lower pestle 31 and each upper pestle 32 are configured to move in an orbit together with the turntable 10, and each lower pestle 31 has a lower pestle body portion 31.
a The guide rollers 32d provided at the lower end surface and in the center of each upper punch 32 move with the lower punch guide 2
The guide surface 21 of 0 and the guide surface 41 of the upper punch guide 40 are guided respectively.

A hopper (not shown) for filling powder into the die holes 61 of each die 60 of the rotary disc 10 is provided above the predetermined position on the rotary disc 10 from the position where the hopper is provided. A feed shoe 70 for scraping off the filled powder is fixedly provided in contact with the upper surface of the rotary disc 10 on the downstream side of the rotary disc 10 in the rotation direction.

A pressurizing device is provided at a position distant from the position where the feed shoe 70 is provided to the downstream side in the rotation direction of the rotating disk 10 by an appropriate distance.
50 are provided. The pressurizing device 50 includes preload rollers 51 and 52, which are respectively provided on the lower side and the upper side with the rotary disc 10 sandwiched therebetween, on the upstream side in the rotation direction of the rotary disc 10, and the preload rollers 51 and 52, respectively. Lower and upper main pressure rollers 53 and 54 are provided at an appropriate distance on the downstream side of the board 10 in the rotation direction.

The lower preload roller 52 comes into contact with the lower end surface of the lower punch main body 31a of the lower punch 31 that has moved around and presses the entire lower punch 31 upward. Further, the upper preload roller 51 abuts on the upper end of the upper punch 32 that has moved circularly and presses the entire upper punch 32 downward. Similarly, the lower pressure roller 54 is
The lower punch main body 31a of the lower punch 31 comes into contact with the lower end surface of the lower punch 31 and presses the entire lower punch 31 upward. In addition, the upper main pressure roller 53
Contacts the upper end of the upper punch 32 and presses the entire upper punch 32 downward.

Between the upper pressure roller 51 and the main pressure roller 53, a pair of pressing guides 56 and 57, which are substantially horizontal, are provided. The pressing guides 56 and 57 are in contact with the guide rollers 32c and 32d in the upper punch 32 in a state of being pressed downward by the preload roller 51, and the upper punches
Guide so that the pressure of 32 is maintained.

Between the lower preload roller 52 and the main pressure roller 54, there is also provided a pair of pressing guides 55 in a substantially horizontal state, and the lower punches moved upward by the lower preload roller 52. The lower punch 3 by contacting the guide roller 31c of 31
Guide so that the pressurized condition of 1 is maintained.

The guide surface 21 of the lower punch guide 20 has a filling area facing the powder hopper in a substantially horizontal state, and an upstream side portion in the rotating direction of the turntable 10 in the filling area is gradually lowered as it goes to the upstream side. It has an inclined rising surface. Therefore, the lower punch 31 is guided by the ascending surface and ascends along with its orbital movement, and in the filling area where the hopper faces, the lower punch part 31b, which is the upper end of the lower punch 31, is the die hole of the die 60. A predetermined amount is inserted into 61. The guide surface 21 of the lower punch guide 20 is in a horizontal state from this filling region to a region where the lower preload roller 52 is arranged on the upstream side in the rotation direction of the turntable 10 in the horizontal state. Lower punches guide 20
Thereby, the lower punch 31 holds a constant height.

The lower punch guides 20 do not come into contact with the guide rollers 31c of the lower punches 31 while the lower punches 31 pass through the area where the pressure device 50 is disposed. Further, from the position where the lower main pressure roller 54 is disposed in the pressure device 50 to the downstream side, the rising surface is inclined upward in sequence. This makes the mortar
The lower punch part 31a of the lower punch 31 in the state of being fitted in the 61 further rises to a position almost equal to the upper surface of the turntable 10. Then, after that, the guide surface 21 of the lower punch guide 20
Is an inclined surface that is inclined downward as it goes to the upstream side, and the inclined surface is connected to the rising surface that is continuous with the above-described filling area.

On the other hand, the guide surface 41 of the upper punch guide 40 is in a substantially horizontal state except for the region where the pressure device 50 is disposed and the upstream region and the downstream region thereof. The upper punch 32 guided by the guide surface 41 in the horizontal state is the upper punch 32 of the lower end.
b is not fitted in the die hole 61. And
The downstream side area of the horizontal guide surface of the upper punch guide 40, that is, the area facing the upstream continuous part of the filling area of the guide surface 21 of the lower punch guide 20 is the upstream side. The first that gradually inclines downward as it becomes
It is an inclined surface 41a, and further, the upstream side portion is
A second inclined surface 41b having a larger inclination angle than the first inclined surface 41a.
It has become. The inclination angle of the first inclined surface 41a is larger than the inclination angle of the guide surface of the upper punch guide in the conventional compression molding machine. Therefore, the length of the first inclined surface 41a and the second inclined surface 41b is sufficiently smaller than the length of the inclined surface of the upper punch guide in the conventional compression molding machine.

The guide roller 32d of the upper punch 32 is guided by the first inclined surface 41a and the second inclined surface 41b and sequentially descends,
The entire upper punch 32 is sequentially lowered. Then, the second inclined surface 41b
In the middle of the process, the upper punch part 32b of the lower end part of the upper punch 32 is fitted into the die hole 61. On the second inclined surface 41b, the upper punch part 3 of the upper punch 32 is
The horizontal surface supporting the guide roller 32d is continuous with the 2b completely fitted in the die hole 61 by its own weight.

The powder compression molding method of the present invention is carried out as follows using the rotary powder compression molding machine having such a configuration.

When the turntable 10 in the rotary powder compression molding machine is rotated, the lower punch 31 and the upper punch 32 located above and below each die hole 61 together with the turntable 10 are the same in the same direction as the turntable 10. Move around at speed. The lower pestle 31 has a lower pestle portion 31b at the upper end thereof which is always fitted in the die hole 61. This allows
The lower part of each die hole 61 is closed by the lower punch part 31b. The lower punch portion 31b of the lower punch 31 closes the lower end portion and reaches the powder filling position.
A predetermined amount is set by the feed shoe 70.

When the die hole 61 filled with the powder passes through the position where the feed shoe 70 is provided, the upper punch 32 located above the die hole 61.
Is guided and lowered by the first inclined surface 41a of the upper punch guide 40, and then guided and lowered by the second inclined surface 41b. When the upper punch 32 is lowered along the second inclined surface 41b, the upper punch portion 32b of the lower end portion is dropped into the die hole 61 by its own weight. As a result, the powder in the die hole 61 is
The air contained in the powder, which is pre-compressed by its own weight,
Through the gap between the outer peripheral surface of the lower punch part 31b and the inner peripheral surface of the die hole 61, and the gap between the outer peripheral surface of the upper punch part 32b and the inner peripheral surface of the die hole 61, the die hole 6
1 Discharged to the outside. The total weight of the upper punch 32 is about twice as much as the weight of the upper punch used in the conventional molding machine so that the powder in the die hole 61 is surely pre-compressed.

Following such pre-compression, the lower punch 31 and the upper punch 32
Is pressurized by the preload rollers 51 and 52,
The powder in the die hole 61 is compression molded, and the main pressure roller 53
The powder in the die hole 61 is finished into a tablet product by compression molding with and 54. In such a powder compression molding method of the present invention, the powder in the die hole 61 is pre-compressed by the weight of the upper punch 32 before being compression-molded by the preloading rollers 51 and 52. The compression load in the pre-compression is determined by the weight of the upper punch 32, and the weight of the upper punch 32 is set so that the powder in the die hole 61 is sufficiently deaerated. Further, the second inclined surface 41b of the upper punch guide 40 causes the entire upper punch 32 to rapidly descend, and the powder in the die hole 61 is compressed by the weight of the punch for a relatively long time, so that the powder is released from the die. The qi effect is great.

When the powder contains a wax-like substance, the lower punch 31 and the upper punch 32 and the die hole 61 are rubbed with each other by frictional heat, so that
The temperature inside 61 rises and the waxy material softens.

However, in the method of the present invention, since the pre-compression is performed by the weight of the upper punch 32, even when the turntable 10 rotates at a high speed, the temperature rise in the die hole 61 is suppressed and the wax-like substance is softened. Is suppressed. Even if softening occurs due to temperature rise, in the method of the present invention, since a sufficient degassing effect is obtained, there is no risk of capping or lamination occurring in the manufactured tablet, and the air in the filled powder is almost Since it has been deaerated, there is almost no air to be ejected at the time of pre-compression which is high-speed compression and the subsequent compression molding, and therefore, there is no possibility that the powder will be ejected from the die hole 61.

When a tablet containing wax-like vitamin E (d-α tocopherol succinate) in a high unit (50 mg / 240 mg) is produced by a conventional method, when the rotation speed of the rotating disc is 40 rpm (1200 tablets / minute) In (2), a large amount of capping and lamination occurred in the produced tablet from the time 2 hours after the start of tablet production, and a large amount of powder was ejected from the die hole. Therefore, when the rotation speed of the turntable was reduced to 30 rpm, capping and lamination did not occur in the tablets produced until 4 hours after the start of tableting, but after that, capping, A large amount of lamination occurred. The weight of the upper punch was about 400 g. On the other hand, in the powder compression molding method of the present invention, even when the rotation speed of the rotary disk is 40 rpm, the produced tablets have no capping or lamination regardless of the tableting time, and There was also little squirting of powder through the holes. The weight of the upper punch was about 800 g.

(Effects of the Invention) As described above, the powder compression molding method of the present invention is performed by pressing the powder filled in the die holes of the rotary disk to a predetermined weight before performing the compression molding by pressing the powder. The powder in the die is surely degassed because it is pre-compressed with a punch, and there is no risk of capping or lamination occurring in the tablets produced during compression molding following pre-compression. There is also no danger of powder ejection. Moreover, since this pre-compression is performed by the weight of the upper punch, the time for pre-compression can be secured for a relatively long time even in the case of compression molding at a high speed. There is no possibility that the deaeration effect will be lowered, there will be no possibility that capping or lamination will occur in the manufactured tablets with time, and there will be no possibility that powder will be ejected from the die hole with time.

[Brief description of drawings]

FIG. 1 is a schematic view showing a main structure of a rotary powder compression molding machine used for carrying out the method of the present invention. 10 …… Rotary disk, 20 …… Lower punch guide, 31 …… Lower punch, 31a…
… Lower punch body part, 31b …… Lower punch part, 32 …… Upper punch, 32a …… Upper punch body part, 32b …… Upper punch part, 40 …… Upper punch guide, 41 ……
Guide surface, 41a ... first inclined surface, 41b ... second inclined surface, 50
...... Pressure device, 51, 52 …… Preload roller, 53, 54 …… Main pressure roller, 60 …… mortar, 61 …… mortar hole.

Claims (1)

[Claims] 1. A powder is filled in a mortar hole, which penetrates in the up-down direction, in a rotating disk that rotates in a horizontal state, with the lower pestle of the lower pestle being fitted from below, and the mortar hole is formed. A powder compression molding method in which the upper punch part of the upper punch is fitted into the inside of the upper punch and the lower punch and the upper punch are pressed to compress the powder. A powder compression molding method, characterized in that the upper punch part of which the weight is adjusted is dropped and precompressed by its own weight.