JPH0662121B2 - Equipment for filling substances in containers - Google Patents

Description

TECHNICAL FIELD The present invention relates to a device for automatically filling a container with a flowable powdery substance.

Conventional technology and its problems As a device for automatically filling a fluid powdery substance into a container, a typical one is manufactured by Perry Industries Incorporated of Hicksville, NY and registered trademark Perry Acofils ( PERRY ACCF
Known as ILS) and of its kind series 0, 1
And 2, there are models CMR124 and CMR2.
This is a high speed automatic powder filling device, rotary type,
A plurality of measuring chambers are formed in the rotating wheel, which is housed in the casing and rotates continuously around a horizontal axis. Furthermore, the hopper is arranged above the rotating wheel, and the funnel is arranged below the rotating wheel, and when a specific measuring chamber reaches the upper end position as the rotating wheel rotates, it communicates with the hopper, and its measurement is performed. A vacuum suction action occurs in the chamber and the hopper powder is sucked into the measurement chamber. The measuring chamber is then covered by the casing as the rotating wheel rotates. Then, when the measuring chamber reaches the lower end position, it communicates with the funnel, pressurized air is forced into the measuring chamber, and the powdery substance is jetted into the funnel, pushed into the container and filled.

However, this device has a problem in that it requires a plurality of measuring chambers formed on a rotating wheel and rotates them accurately, which complicates the construction. Furthermore, when the powdery substance is sucked into the measuring chamber and then the casing covers the measuring chamber as the rotary wheel rotates, the powdery substance undergoes shearing action between the hopper and the rotary wheel, which causes There is also a problem that the particles of the powdery substance are crushed and the size of the particles is reduced. There is also a problem that particles of the powdery substance enter between the rotating wheel and the casing, causing friction between the rotating wheel and the casing. There is also a problem that wear occurs on the rotating wheel and the casing, and particles thereof are mixed into the powdery substance. This problem is particularly important when the powdered material is a drug.

OBJECTS OF THE INVENTION Therefore, the present invention, when automatically filling a fluid powdery substance into a container, by a device of a simple configuration,
The purpose of the present invention is to accurately fill the powdery substance and solve the above-mentioned conventional problems.

According to the present invention, according to the present invention, there is provided an apparatus for movably filling a container (12) with a fluid powder substance, (a) a hopper (28) for storing a substance to be distributed, and (b) A measurement chamber (30) into which a fixed amount of substance is fed from the hopper (28), (c) a discharge valve (36) arranged between the measurement chamber (30) and the container (12), (d) The measuring chamber (3
(0) is disposed at one end of the measurement chamber (30) and partially forms a wall surface of the measurement chamber (30), which is a porous gas permeable boundary element (94), and (e) the boundary element (94) and the discharge valve. An inlet port formed in the side wall of the measurement chamber (30) at a position between (36), the inlet port is in constant communication with the hopper (28), (f) the boundary element (94) Through the measuring chamber
A vacuum which, when connected to (30) and when the discharge valve (36) is closed, sucks the substance from the hopper (28) through the inlet port into the measuring chamber (30) quickly and uniformly. A source (96), and (g) the measuring chamber via the boundary element (94).
When connected to (30) and the discharge valve (36) is opened,
Pressurized air is sent into the measurement chamber (30), and the packed substance is pushed together from the measurement chamber (30) into the container (12), and then the discharge valve (36).
When the measuring chamber (3) is closed, pressurized air is blown into the measuring chamber (30) and the hopper (28).
An apparatus is provided, which comprises an air pressure source (98) for returning and purging the residual substances in (0) into the hopper (28).

Description of Embodiments Hereinafter, embodiments of the present invention will be described.

In FIG. 1, this is an apparatus (10) for automatically filling a container (12) with a flowable powdery substance, and a container (12) such as a glass bottle has a conveyor belt (14) and a guide rail (15). ) To the lead screw (16) and the container (12) is
Stop below 8). Discharge nozzle (18) is on bracket (22)
Part of the dispensing head (20) mounted on the dispensing head (20), the dispensing head (20) has a pair of units (21a), (21b) of the same structure, and the discharge nozzle (18) is provided at the lower end thereof. There is. Therefore, when the powdery substance is filled, the dispensing head (20) is moved vertically to move the discharge nozzle (18) into the open neck region of the container (12) as shown in FIGS. 10a and 10b. Can be inserted into. In addition, the device has a control panel cabinet (24) and a push button station (26).

Further, as shown in FIG. 3, the dispensing head (20) is attached to the hopper (2
8) is provided, the hopper (28) is for storing the powdery substance (62), and is covered with a cover (40) having a pneumatic relief valve (70). In addition, each unit (21a),
The measurement chamber (30) is provided in (21b), and the discharge valve (36)
Is located between the measuring chamber (30) and the discharge nozzle (18) and is located opposite the discharge valve (36).
(34) is located at one end of the measurement chamber (30). The measuring chamber (30) has an elongated cavity (44) and the position adjusting head (34) is piston-like and has a boundary element consisting of a filter (66), which is housed in the measuring chamber (30). There is. The filter (66) partially forms the wall surface of the measurement chamber (30), is porous, and is permeable to gas. Furthermore, the adjusting screw (17) is connected to the position adjusting head (34), the adjusting screw cap (35) is arranged outside the measuring chamber (30), and is fixed to one end of the adjusting screw (17). Filter (66) in measuring chamber (30) by means of screw cap (35)
Can be adjusted to control the volume of the measurement chamber (30). Further, an outlet port (42) is formed in the bottom of the hopper (28), an inlet port is formed in the side wall of the measurement chamber (30) between the filter (66) and the discharge valve (36),
An inlet valve (32) is located between the outlet port (42) and the inlet port.

In this device, as shown in FIGS. 2, 4, and 5, the introduction valve (32) and the discharge valve (36) are operated by the air cylinder (38). The inlet valve (32) has an inlet hole (4
8) consists of a vertical slide plate (46) and the discharge valve (36) consists of a horizontal slide plate (50) with a discharge hole (52). Regarding the introduction hole (48) and the discharge hole (52),
As shown in FIGS. a to 9c, the positions are appropriately selected, and when one hole is opened, the other hole is closed, and after one hole is closed, the other hole is opened. be opened.
Therefore, the introduction valve (32) and the discharge valve (36) are alternately opened and closed. In addition, the introduction valve (32) and the discharge valve (36) should have O-rings (54), (56) and washers.
(58) and (60) are provided. O-rings (54) and (56) prevent leakage of substances, and washers (58) and (60) are O-rings (5
4) Reduce the friction of (56).

Further, the position adjusting head (34) is formed with a radial hole (67b) and an axial hole (67a), and the units (21a) and (21b) are provided with a hose connecting part (67c). (67c)
Communicates with the radial hole (67b) and the axial hole (67a), and communicates with the measurement chamber (30) through the filter (66). Hopper (28) is a jet (64) attached to a clamp (68)
Have.

In this device, as shown in FIG. 6, first, the introduction valve (32) is opened by the air cylinder (38), and the discharge valve (3) is opened.
6) is closed. Further, the pressurized air passes through the jet (64) and is fed into the hopper (28), and the powdery substance (62) passes through the introduction valve (32) and is pushed out into the measurement chamber (30).
At the same time, the hose connection (67c), the radial hole (67b), the axial hole (67a) and the measurement chamber (30) are evacuated by a vacuum source such as a vacuum pump to remove the powdery substance (62). It is sucked into the measuring chamber (30). Next, the introduction valve (32) is closed by the air cylinder (38) and the discharge valve (32) is
(36) is opened and pressurized air passes through the hose connection (67c), radial hole (67b), axial hole (67a) and filter (66),
It is fed into the measuring chamber (30). Therefore, the powdery substance (62) is pushed out of the measurement chamber (30), pushed through the discharge valve (36) and pushed into the container (12) to be filled.

This device can be filled not only with the powdery substance (62) but also with a liquid. In this case, as shown in FIG. 7, the position adjustment head (34) is provided with a ball check valve (69). Then, the liquid is stored in the hopper (28), and as shown in FIG. 8, the introduction valve (32) is opened and the discharge valve (36) is closed by the air cylinder (38). Therefore, when the liquid is introduced through the introduction valve (32) into the measurement chamber (30) and its liquid level reaches the ball (72) of the check valve (69), the ball (72) causes the valve orifice (74) Is closed. The inlet valve (32) is then closed, the outlet valve (36) is opened, and pressurized air is passed through the ball check valve (6).
Liquid is forced out of the measurement chamber (30) through the measurement chamber (30) through the discharge valve (36) and is filled in the container (12).

The device of FIG. 3 has some of the features of the present invention, but not all of them. According to the present invention, the inlet port of the measurement chamber (30) is in constant communication with the hopper (28). In the apparatus of FIG. 3 as well, the inlet port is formed on the side wall of the measurement chamber (30) between the filter (66) and the discharge valve (36), but the introduction valve (32) is provided at the inlet port and the hopper (28). As described above, the introduction valve (32) is opened and closed by the air cylinder (38) disposed therebetween, and the inlet port does not always communicate with the hopper (28). Therefore, the device of FIG. 3 is not an embodiment of the present invention.
Further, in the apparatus of FIG. 3, it is necessary to open and close the introduction valve (32) in addition to the discharge valve (36), and it cannot be said that the configuration is necessarily simple. There is also a problem that when the introduction valve (32) is closed, the powder substance is subjected to a shearing action, which causes the particles of the powder substance to be crushed.
The present invention is an improvement of the apparatus of FIG. 3 and solves the problem.

FIG. 11 shows an embodiment of the present invention. Device of FIG. 11 (8
Also in 0), as in the device (10) of FIG. 3, the dispensing head (20) is provided with the hopper (28), and the substance to be dispensed is stored in the hopper (28). The substance to be distributed is a powder substance, salt,
It may be pepper, sugar or wheat flour, talc, pharmaceutical powders and salts, spices, ground coffee, freeze-dried coffee, dry parsley and onion flakes or crumbs. The hopper (28) is supported by the bracket (82). Then, a fixed amount of substance is fed into the measurement chamber (30).

In addition, the discharge valve (36) has a measuring chamber (30) and a container (12).
A discharge nozzle (18) is provided between the discharge valve (36) and the discharge nozzle (18). The measurement chamber (30) has an elongated cavity (44) that extends vertically above the container (12) and is mounted axially moveable integrally with the discharge valve (36) and discharge nozzle (18). ing. Thus, like the device (10) of FIG. 3, the discharge nozzle (18) can be inserted into the open neck region of the container (12).

The discharge valve (36) is a pinch valve and has a flexible elastic tubular sleeve (108) and its operating member, the sleeve (108) being attached to the measuring chamber (30).
The operating member comprises a pin (112) penetrating the radial hole (110) of the block (109) and faces a wall portion of the sleeve (108). Therefore, push the pin (112) forward by a cam, lever, solenoid or air cylinder (114) and press it against the wall of the sleeve (108) so that the wall of the sleeve (108) crosses the measurement chamber (30). Energize, which allows the discharge valve (36) to close.

Furthermore, a boundary element is arranged at one end of the measuring chamber (30), opposite the discharge valve (36). Boundary element is a filter mounted on the alignment head (34)
The position adjusting head (34) is a piston-like member, which is housed in the measuring chamber (30) and sealed by an O-ring (86). The filter (94) spans the cavity (92) of the position adjusting head (34) and partially forms the wall of the measuring chamber (30), is porous and gas permeable. Furthermore, the adjusting screw (17) is screwed into the screw hole (88) of the cap (90), and the adjusting screw cap (35) is arranged outside the measuring chamber (30) and fixed to one end of the adjusting screw (17). ing. Accordingly, the position of the filter (94) in the measurement chamber (30) can be adjusted by the adjusting screw cap (35) to control the volume of the measurement chamber (30).

Further, as in the device (10) of FIG. 3, an outlet port (42) is formed in the bottom of the hopper (28) to allow the filter (94) and discharge valve
In the position between (36) the inlet port is the measuring chamber (30)
Is formed on the side wall. However, the device of FIG.
Unlike (10), the inlet port is in constant communication with the hopper (28) and there is no introduction valve (32) in FIG. In this embodiment, the hopper (28) is mounted and fixed to the device proximate to the measurement chamber (30), and the elongated flexible communication conduit (84) connects the hopper (28) and the measurement chamber (30). ing.

In addition, a vacuum source (96) and an air pressure source (98) are connected to the conduit (100),
(102), connected to the three-way valve (106) and the conduit (104), the position adjusting head (34) has a radial hole (67b) and an axial hole (67a), and the conduit (104) is a cap. It is attached to (90) and communicates with the radial hole (67b) and the axial hole (67a). The axial hole (67a) communicates with the measurement chamber (30) via the filter (94). Therefore, the vacuum source (96)
And the air pressure source (98) is connected to the three-way valve (106) and the film (9
It is connected to the measurement chamber (30) via 4).

In addition, a stirrer (83) is installed in the hopper (28). The agitator (83) does not make direct contact with the hopper (28) itself, but agitates the powdery substance and maintains it in a fluid state. In addition, the discharge nozzle (18) has a space (1) formed in the vertical block (109).
16) and the cavity (116) is connected to a conduit (118) and a vacuum source. Therefore, the negative pressure is discharged from the nozzle (1
It can be kept around the tip of 8) and impurities can be sucked into the cavity (116).

In this device, when the discharge valve (36) is closed, the three-way valve (106) is rotated to the position shown in FIG. Therefore, the vacuum source (96) evacuates the conduits (100), (104), the radial hole (67b), the axial hole (67a), and the measurement chamber (30), and the powdery substance is hopper (28). Drawn from
It is sucked into the measurement chamber (30) through the flexible communication conduit (84) and the inlet port. The vacuum source (96) produces a vacuum pressure of approximately 24 in of mercury and causes the measurement chamber (3
0) is rapidly evacuated. Therefore, when the powdery substance is sucked into the measurement chamber (30), it can be sucked in quickly. For example, in the case of a measurement chamber (30) of 1 to 10 cc, the powdery substance is sucked in at a speed of 1/10 second or less. As a result, the powdery substance is uniformly packed in the measurement chamber (30).

After that, the three-way valve (106) is rotated to the position shown in FIG. Thus, pressurized air is supplied by the air pressure source (98) which leads to the conduits (102), (104) and the radial bore (67b).
, Into the axial hole (67a) and the measurement chamber (30). At the same time, the discharge valve (36) is opened. Therefore, the packed substance is pushed out of the measurement chamber (30), passed through the discharge valve (36) and pushed into the container (12) to be filled. The pressurized air has a high pressure of 2-10 psig, which acts rapidly on the powder and when pushed into the container (12) the powder is pushed together. Therefore, even without the introduction valve (32) of FIG.
The substance in the measurement chamber (30) is not pushed back to the flexible communication conduit (84) and the hopper (28), and the powder substance can be accurately pushed and filled.

Regarding the discharge valve (36) of the measurement chamber (30),
After the lapse of a set time from the filling of the substance into the measurement chamber (30), the discharge valve (36) is operated and opened. During the set time, the wall portion of the flexible elastic tubular sleeve (108) supports the material from below. Then, during the set time, the discharge valve (36) is kept in the valve closed position, keeping the measurement chamber (30) substantially shielded from the outside atmosphere and preventing contamination of the substance.

Further, the discharge valve (36) is closed after filling the container (12). Then, the three-way valve (106) is rotated to the position shown in FIG. 14, pressurized air is supplied by the air pressure source (98), and the pressurized air is supplied to the measurement chamber (for a very short time of 1/10 second). 30), the flexible communication conduit (84) and the hopper (28). Therefore, the measurement chamber
Residual material in (30) returns to the hopper (28) and is purged. At the same time, the powdery substance is agitated by the pressurized air at the bottom of the hopper (28).

EFFECTS OF THE INVENTION As described above, according to the present invention, the discharge valve (3
6) is arranged between the measuring chamber (30) and the container (12), the boundary element (94) is arranged at one end of the measuring chamber (30) on the opposite side of the discharge valve (36), Partly form the wall surface of. The boundary element (94) is porous and gas permeable. In addition, an inlet port is formed in the side wall of the measurement chamber (30) at a position between the boundary element (94) and the exhaust valve (36). The entrance port is a hopper (2
Always communicate with 8). Then, the vacuum source (96) and the air pressure source (98) are connected via the boundary element (94) to the measurement chamber (30).
Connected to the vacuum source and the discharge valve (36) is closed.
(96) the measurement chamber (30) is evacuated, the powdery substance is drawn out from the hopper (28), passes through the inlet port,
It is sucked and packed in the measurement chamber (30). The powdery substance is quickly sucked in and uniformly packed. The exhaust valve (36) is then opened and pressurized air is supplied by the air pressure source (98), which is pumped into the measurement chamber (30). Thus, the stuffed substance is pushed out of the measuring chamber (30), through the discharge valve (36) and into the container (1
2) It is pushed into and filled. When pushed into the container (12), the powdery substances are pushed together. Then, the discharge valve (36) is closed, pressurized air is blown into the measuring chamber (30), the flexible communication conduit (84) and the hopper (28), and the residual substance in the measuring chamber (30) is hoppered.
It returns to the inside of (28) and is purged. As a result, when the fluid powdery substance is filled in the container (12), the powdery substance can be filled accurately with a simple configuration, and the initial purpose can be achieved.

[Brief description of drawings]

FIG. 1 is a side view of an apparatus for automatically filling a fluid powder substance in a container, FIG. 2 is an enlarged side view of a partial cross section of the apparatus of FIG. 1, and FIG. 3 is an enlarged sectional view of line 3, FIG. 4 is an enlarged sectional view of line 4-4 of FIG. 2, FIG. 5 is a bottom view of the apparatus of FIG. 2, and FIG. 6 is a powdery substance filling process of the apparatus of FIG. 7 is an enlarged cross-sectional view of the position adjusting head used for filling the liquid, FIG. 8 is a flowchart of the liquid filling process of the apparatus shown in FIG. 1, and FIGS. 9a, 9b and 9c are shown in FIG. 1 is an explanatory view showing the positional relationship between the introduction valve and the discharge valve of the apparatus of FIG. 1, FIG. 10a is a side view showing the positional relationship between the discharge nozzle and the container of the apparatus of FIG. 1, and FIG. 10b is the discharge nozzle of FIG. 10a. FIG. 11 is a side view showing a state in which is inserted into the opening neck region of the container, FIG. 11 is an enlarged sectional view showing an embodiment of the present invention, 12 is an enlarged sectional view showing the powdery substance filling step of the apparatus of FIG. 11, FIG. 13 is an enlarged sectional view showing the next step of the apparatus of FIG. 12, and FIG. 14 is a sectional view of the apparatus of FIG. It is an expanded sectional view showing a process of. (12) …… Container (28) …… Hopper (30) …… Measuring chamber (36) …… Exhaust valve (94) …… Filter (96) …… Vacuum source (98) …… Air pressure source

Claims (9)

[Claims] 1. An apparatus for automatically filling a fluid powder substance into a container (12), comprising: (a) a hopper (28) for storing a substance to be distributed; and (b) a fixed amount of substance. A measurement chamber (30) fed from the hopper (28), (c) a discharge valve (36) disposed between the measurement chamber (30) and the container (12), (d) the discharge valve (36) ) Opposite the measurement chamber (3
(0) is disposed at one end of the measurement chamber (30) and partially forms a wall surface of the measurement chamber (30), which is a porous gas permeable boundary element (94), and (e) the boundary element (94) and the discharge valve. An inlet port formed in the side wall of the measurement chamber (30) at a position between (36), the inlet port is in constant communication with the hopper (28), (f) the boundary element (94) Through the measuring chamber
A vacuum which, when connected to (30) and when the discharge valve (36) is closed, sucks the substance from the hopper (28) through the inlet port into the measuring chamber (30) quickly and uniformly. A source (96), and (g) the measuring chamber via the boundary element (94).
When connected to (30) and the discharge valve (36) is opened,
Pressurized air is sent into the measurement chamber (30), and the packed substance is pushed together from the measurement chamber (30) into the container (12), and then the discharge valve (36).
When the measuring chamber (3) is closed, pressurized air is blown into the measuring chamber (30) and the hopper (28).
A device provided with an air pressure source (98) for returning and purging the residual substance in (0) into the hopper (28). 2. Device according to claim 1, characterized in that the measuring chamber (30) extends vertically above the container (12). 3. A discharge nozzle (18) provided below the discharge valve (36), wherein the measuring chamber (30) is integrally formed with the discharge valve (36) and the discharge nozzle (18). A movably mounted in a direction such that the discharge nozzle (18) can be inserted into the open neck region of the container (12). Equipment. 4. The hopper (28) is mounted and secured to the device in proximity to the measurement chamber (30), and an elongated flexible communication conduit (84) is provided for the hopper (28) and the measurement chamber (30). The device according to claim (1), characterized in that: 5. Further comprising adjusting means for adjusting the position of said boundary element (94) within said measuring chamber (30) and controlling its volume, said adjusting means comprising said measuring chamber (30).
Device according to any one of claims (1) to (4), characterized in that it has an adjusting screw cap (35) arranged on the outside of the device. 6. The discharge valve (36) is connected to the measurement chamber (3).
(0) is operated after a lapse of a set time from the filling of the substance, and is kept in the valve closed position for the set time to keep the measurement chamber (30) substantially shielded from the outside atmosphere. The device according to any one of claims (1) to (5), characterized in that contamination of the substance is prevented. 7. The discharge valve (36) is connected to the measuring chamber (3).
Flexible elastic tubular sleeve (10
8) and an operating member (112) for urging the wall portion of the sleeve (108) across the measurement chamber (30) in the valve closed position, the measurement chamber (30) When filling, the wall portion is configured to support the substance from below under the set time, The claim (1)-(6) according to any one of claims 1 to 6. Equipment. 8. The discharge nozzle (18) is arranged in a cavity (116) connected to a vacuum source, and a negative pressure is applied to the discharge nozzle.
Maintained around the tip of (18), impurities are
6) The device according to any one of claims (1) to (7), characterized in that the device is sucked into. 9. A stirrer (83) which is mounted within said hopper (28) but which does not come into direct contact with the hopper (28) itself but stirs said substance and keeps it in a fluidized state. The device according to any one of claims (1) to (8), characterized by comprising: