JP2003170004A - Filling tank deaeration device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To generate no dispersion of a filling amount and to stabilize a flow of a liquid food at the time of filling. <P>SOLUTION: The filling tank deaeration device has a closed filling tank 61; a negative pressure formation part for forming a negative pressure in the filling tank 61; a feed part for feeding the liquid food to the filling tank 61; a discharge part for discharging the liquid food from the filling tank 61; and a measuring device for suctioning the liquid food in the filling tank 61 through the discharge part each by a set amount and feeding it to a measuring feed pipe. Since the negative pressure is formed in the filling tank 61, air intruding into the filling tank 61 is removed by the negative pressure. Accordingly, when the liquid food is filled in a carton, a dispersion is not generated in the filling amount and a flow of the liquid food can be stabilized at the time of filling. Thereby, the liquid food can be prevented from overflowing from the carton, from deteriorating the quality of the liquid food. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a deaerator for a filling tank.

[0002]

2. Description of the Related Art Conventionally, a filling machine for filling a carton of a packaging container with a liquid food is provided with a filling tank for containing the liquid food, and the liquid food in the filling tank is weighed by a predetermined amount to form a carton. I am trying to fill it.

FIG. 2 is a schematic view of a conventional filling machine.

In the figure, 11 is a filling tank for containing liquid food, 12 is a reciprocating type measuring pump for measuring the liquid food contained in the filling tank 11, and 13 is connected to the measuring pump 12. It is a metered supply pipe.

The liquid food is supplied from a liquid food supply source (not shown) to a supply pipe 50, a liquid food supply valve 52 and a supply pipe 5.
1 is conveyed in the direction of the arrow through 1 and is supplied to the filling tank 11 through the supply port 54. And the filling tank 1
The liquid food in 1 is discharged through an opening 18 formed in the bottom surface of the filling tank 11, is sent out by the metering pump 12 to the metering supply pipe 13 by a set amount, and the upper end is opened. The bottom carton 15 is filled.

In this case, the metering pump 12 is operated in the suction mode and the delivery mode, and in the suction mode, the liquid food is discharged from the filling tank 11, sucked by the metering pump 12, and the metering pump 12 is used. Stored in the weighing space 20 of. Further, in the delivery mode, the liquid food product stored in the weighing space 20 is discharged by the weighing pump 12, sent to the weighing supply pipe 13, and filled in the carton 15. In addition,
The figure shows the metering pump 12 operated in the delivery mode.

By the way, in the suction mode, the liquid food in the filling tank 11 is sucked by the metering pump 12 and stored in the metering space 20, and in the delivery mode is stored in the metering space 20 and discharged by the metering pump 12. A valve mechanism 16 is provided between the filling tank 11, the metering pump 12, and the metering pipe 13 in order to deliver the liquid food to the metering pipe 13.

The valve mechanism 16 comprises a valve housing 21, and a suction valve 41 and a delivery valve 42 arranged vertically adjacent to each other along the valve housing 21. The suction valve 41 includes a valve body 22 that is movably disposed with respect to the valve housing 21 and is biased by a spring 43 toward a first valve seat formed above the valve housing 21. . Then, in the suction mode, the valve body 22 is moved downward against the urging force of the spring 43 to separate from the first valve seat, and the suction valve 41
Is opened, and in the delivery mode, the valve body 22 is moved upward by the biasing force of the spring 43 to hit the first valve seat, and the suction valve 41 is closed.

The delivery valve 42 is a valve housing 2
The valve body 23 is provided so as to be movable with respect to 1, and is biased by a spring 44 toward a second valve seat formed below the valve housing 21. Then, in the delivery mode, the valve main body 23 moves the spring 4
4 is moved downward against the biasing force of No. 4 to separate from the second valve seat, the delivery valve 42 is opened, and the valve body 23 is moved upward by the biasing force of the spring 44 in the suction mode. Then, the delivery valve 42 is closed by hitting the second valve seat.

An elbow pipe 24 is connected to the side surface of the valve housing 21, and the valve main bodies 22 and 23 in the valve housing 21 are connected to the metering pump 12. The metering pump 12 includes a cylinder 35,
And a piston 36 which is slidable in the cylinder 35, and the cylinder 35 and the piston 36 form the measuring space 20. The piston 3
6 is connected to a measuring drive device (not shown) via a piston rod 38, and the piston 36 can be moved in the vertical direction by driving the drive device.

In the suction mode, when the piston 36 is moved downward, the suction valve 4
1 is opened, the liquid food in the filling tank 11 is discharged from the opening 18 and flows around the valve body 22,
It flows through the elbow pipe 24 and is supplied to the weighing space 20. At this time, the delivery valve 42 is closed.

Further, in the delivery mode, when the piston 36 is moved upward, the delivery valve 42 is opened, the liquid food in the metering space 20 is supplied to the valve housing 21, and the liquid food around the valve body 23 is supplied. Flow, then
It is sent to the metering pipe 13. At this time, the suction valve 41 is closed.

A pipe 53 is arranged so as to project through the upper wall of the filling tank 11, and the pipe 53 injects a cleaning liquid or sterilizing vapor toward the inner wall surface of the filling tank 11 as required. . Reference numeral 56 is a level sensor which is provided so as to penetrate the upper wall of the filling tank 11 and detects the position of the liquid surface of the liquid food in the filling tank 11.

[0014]

However, in the conventional filling machine described above, air is not mixed into the liquid food in the pretreatment process, but due to the design, air is not contained in the piping system and the filling tank system of the filling machine. If it has a structure that allows the air to enter, air may be mixed into the liquid food.

In that case, the liquid foodstuffs are filled in the carton 15 in the state where minute air bubbles are contained. As a result, the filling amount varies and the flow of the liquid foodstuffs at the time of filling becomes unstable. In addition to the liquid food overflowing from the carton 15, the quality of the liquid food deteriorates due to the bubbles contained therein.

In particular, when filling a liquid food containing a large amount of fibers, particles, etc., the content of bubbles increases.

The present invention solves the above-mentioned problems of the conventional filling machine so that the filling amount does not vary, the flow of the liquid food during the filling is stabilized, and the liquid food overflows from the carton. An object of the present invention is to provide a filling tank deaeration device that can prevent the above.

[0018]

Therefore, in the filling tank deaerating device of the present invention, a closed filling tank, a negative pressure forming portion for forming a negative pressure in the filling tank, and the filling tank are provided. A supply unit that supplies liquid food, a discharge unit that discharges the liquid food from the filling tank, and a metering device that sucks the liquid food in the filling tank by a set amount through the discharge unit and sends the liquid food to a metering supply pipe. Have.

In another filling tank degassing apparatus of the present invention, the supply unit further includes a diffuser for supplying the liquid food at a low speed.

In still another filling tank degassing device of the present invention, the supply unit causes liquid food to enter the filling tank in a tangential direction.

In still another filling tank degassing device of the present invention, a bubble collecting member for collecting bubbles in the liquid food product is further arranged at the discharge part.

In still another filling tank degassing device of the present invention, further, in the measuring device, the speed at which the liquid food is sucked is set in advance so that the bubbles are sufficiently adhered to the bubble collecting member. It

In still another filling tank degassing device of the present invention, the metering device further sucks a predetermined amount of the liquid food in the filling tank through the discharging part and stores it in a metering space. It is operated in a mode and in a delivery mode in which the liquid food stored in the weighing space is sent to a metering supply pipe and filled in a carton.

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a perspective view of a filling tank according to the embodiment of the present invention, and FIG. 3 is a schematic view of a filling machine according to the embodiment of the present invention.

In the figure, 61 is a filling tank for containing liquid food, and the filling tank 61 is a tank body 62.
And a lid body 63, which are sealed to form a negative pressure inside. Therefore, a pipe 64 is connected to the tank main body 62 by opening it in the vicinity of the upper end of the tank main body 62, and a vacuum pump (not shown) as a negative pressure source is connected to the inside of the filling tank 61 through the pipe 64. . In addition, the level sensor 56, which is arranged so as to penetrate the upper wall of the filling tank 11,
Thus, the position of the liquid surface of the liquid food in the filling tank 61 is set to be lower than the position where the pipe 64 is opened. A control valve (not shown) is provided at a predetermined position in the pipe 64, and a control unit (not shown) selectively opens and closes the control valve to selectively generate a negative pressure in the filling tank 61. Not only can it be adjusted, but it can also be adjusted.

As described above, since the negative pressure is formed in the filling tank 61, the air that has entered the filling tank 61 can be removed. The pipe 64, the vacuum pump,
A negative pressure forming section is constituted by the control valve and the like. In addition, in the present embodiment, the pressure in the filling tank 61 is set to −several tens to −several hundreds [mmHg].

The liquid food is supplied from a liquid food supply source (not shown) to a supply pipe 50, a liquid food supply valve 52 and a supply pipe 5.
1 is conveyed in the direction of the arrow through 1 and is supplied to the filling tank 61 through the supply port 54. As shown in FIG. 1, the supply pipe 51 extends in a tangential direction with respect to the filling tank 61, and the cross-sectional area inside the supply port 54 of the filling tank 61 increases as the distance from the supply port 54 increases. A diffuser 65 is formed integrally with the supply pipe 51. A supply unit is configured by the supply pipe 51 and the diffuser 65.

In this case, the liquid food supplied through the supply pipe 51 enters the filling tank 61 from the supply port 54 in the tangential direction, and immediately after entering, passes through the diffuser 65, and in the diffuser 65. , The liquid food laminar flow is formed, and the velocity is decreased as the cross-sectional area of the diffuser 65 increases. Therefore, the supply pipe 5
0, even if the air that has entered the supply pipe 50, the supply pipe 51, or the like while flowing through the liquid food supply valve 52 and the supply pipe 51 becomes bubbles and is contained in the liquid food, the supply port 54 and the diffuser 65 are The air bubbles are separated from the liquid food as the velocity of the liquid food flowing decreases. Further, since the liquid food enters the filling tank 61 tangentially from the supply port 54, the liquid food in the filling tank 61 is sufficiently stirred (stirred) to sufficiently separate air bubbles from the liquid food. You can The bubbles separated from the liquid food rise in the filling tank 61, are sucked by the negative pressure, and are discharged to the outside of the filling tank 61.

Further, 12 is a reciprocating metering pump as a metering device for metering the liquid food contained in the filling tank 61, and 13 is a metering pipe connected to the metering pump 12. . The metering pump 12 sucks the liquid food in the filling tank 61 by a set amount through an opening 18 formed in the bottom surface of the filling tank 61, sends it out to the metering supply pipe 13, and has the upper end opened. Fill the bottomed carton 15. The opening 18 constitutes a discharge part.

The opening 18 is provided with a bubble collecting member 67 made of a perforated plate, a mesh or the like having a plurality of orifices 68 formed therein, and the liquid food in the filling tank 61 is filled with the bubble collecting member. It is discharged via 67.

The metering pump 12 is operated in the suction mode and the delivery mode, and in the suction mode, the liquid food is discharged from the filling tank 61, sucked by the metering pump 12, and the metering space of the metering pump 12 is set. Stored in 20. Further, in the delivery mode, the liquid food product stored in the weighing space 20 is discharged by the weighing pump 12, sent to the weighing supply pipe 13, and filled in the carton 15. Note that FIG. 3 shows the state where the metering pump 12 is operated in the delivery mode.

By the way, in the suction mode, the liquid food in the filling tank 61 is sucked by the measuring pump 12 and stored in the measuring space 20, and in the delivery mode, stored in the measuring space 20 and discharged by the measuring pump 12. A valve mechanism 16 is arranged between the filling tank 61, the metering pump 12, and the metering pipe 13 in order to send the liquid food to the metering pipe 13.

The valve mechanism 16 comprises a valve housing 21, and a suction valve 41 and a delivery valve 42 which are vertically adjacent to each other along the valve housing 21. The suction valve 41 includes a valve body 22 that is movably disposed with respect to the valve housing 21 and is biased by a spring 43 toward a first valve seat formed above the valve housing 21. . Then, in the suction mode, the valve body 22 is moved downward against the urging force of the spring 43 to separate from the first valve seat, and the suction valve 41
Is opened, and in the delivery mode, the valve body 22 is moved upward by the biasing force of the spring 43 to hit the first valve seat, and the suction valve 41 is closed.

Further, the delivery valve 42 is the valve housing 2
The valve body 23 is provided so as to be movable with respect to 1, and is biased by a spring 44 toward a second valve seat formed below the valve housing 21. Then, in the delivery mode, the valve main body 23 moves the spring 4
4 is moved downward against the urging force of No. 4 to separate from the second valve seat, the delivery valve 42 is opened, and the valve body 23 is moved upward by the urging force of the spring 44 in the suction mode. Then, the delivery valve 42 is closed by hitting the second valve seat.

An elbow pipe 24 as a connecting pipe is connected to the side surface of the valve housing 21, and the valve main bodies 22 and 23 in the valve housing 21 are connected to the metering pump 12. The metering pump 12 is
The measuring space 20 is formed by the cylinder 35 and the piston 36 that is provided with a cylinder 36 and a piston 36 that is slidable inside the cylinder 35. The piston 36 is connected via a piston rod 38 to a driving device (not shown) for measurement, and the piston 36 can be moved in the vertical direction by driving the driving device.

In the suction mode, when the piston 36 is moved downward, the suction valve 4
1 is opened, the liquid food in the filling tank 61 is discharged from the opening 18 and flows around the valve body 22,
It flows through the elbow pipe 24 and is supplied to the weighing space 20. At this time, the delivery valve 42 is closed.

Further, in the delivery mode, when the piston 36 is moved upward, the delivery valve 42 is opened, the liquid food in the metering space 20 is supplied to the valve housing 21, and the liquid food in the periphery of the valve body 23 is supplied. Flow, then
It is sent to the metering pipe 13. At this time, the suction valve 41 is closed.

A pipe 53 is provided so as to project through the lid 63, and the pipe 53 injects a cleaning liquid or sterilizing vapor toward the inner wall surface of the filling tank 61 as required. The filling tank 61, the control valve, the vacuum pump, the pipe line 64, the supply pipe 51, the diffuser 65, and the opening 1
8 and the metering pump 12 constitute a filling tank deaerator.

By the way, among the bubbles contained in the liquid food, the bubbles having a diameter of about 0.8 mm are filled in the filling tank 61.
When the liquid food has a depth of a predetermined value or more, the liquid food naturally rises due to buoyancy even when the liquid food is stationary and separated from the liquid food. Therefore, the distance from the opening 18 to the liquid surface of the liquid food is L1.
[M] and the speed at which the liquid food passes through the bubble collecting member 67 is v1 [m / s], L1> v1. On the other hand, bubbles having a diameter of about 0.1 mm are difficult to separate from the liquid food when the liquid food is stationary, even if the filling tank 61 has a predetermined depth or more.

Therefore, the liquid food is passed through the bubble collecting member 67 at a predetermined low speed, and the bubbles are collected by adhering to the bubble collecting member 67 by the surface tension. In the present embodiment, the bubble collecting member 6
The speed of passing 7 is 0.6 [m / s] or less, preferably 0.1 to 0.3 [m / s]. Then, the bubbles attached to the bubble collecting member 67 are aggregated and rise in the filling tank 61 by buoyancy. Therefore, when a perforated plate is used as the bubble collecting member 67, the diameter of each orifice 68 is 0.20 to 0.30 [m
m], preferably about 0.25 [mm], and when a mesh is used as the bubble collecting member 67, the level of the mesh is set to about 100 mesh.

Further, since a negative pressure is formed in the filling tank 61, the bubbles expand and the diameter increases accordingly. Therefore, not only the expanded bubbles tend to rise naturally due to buoyancy, but also the expanded bubbles collect the expanded bubbles 67.
The bubbles can be easily aggregated because they adhere to the. As a result, it is possible to increase the number of bubbles separated from the liquid food.

The speed at which the liquid food passes through the bubble collecting member 67 corresponds to the speed at which the piston 36 is moved downward in the suction mode. Therefore, at the speed at which the piston 36 is moved downward, that is, at the speed at which the liquid food is sucked, the air bubbles are collected by the air bubble collecting member 6.
It is preset to adhere well to 7.

As described above, since the negative pressure can be formed in the filling tank 61, it is possible to prevent air from being mixed into the liquid food and to prevent air bubbles from being contained in the liquid food. You can Therefore, when the liquid food is filled into the carton 15, the filling amount does not vary, the flow of the liquid food at the time of filling can be stabilized, and the liquid food is prevented from overflowing from the carton 15. You can Further, it is possible to prevent the quality of the liquid food from being deteriorated.

Further, even if air is mixed in the liquid food and air bubbles are contained therein, it can be separated from the liquid food by the diffuser 65 and the air bubble collecting member 67. Therefore, when the liquid food is filled into the carton 15, the filling amount does not vary, the flow of the liquid food at the time of filling can be stabilized, and the liquid food is prevented from overflowing from the carton 15. You can Further, it is possible to prevent the quality of the liquid food from being deteriorated.

The present invention is not limited to the above-mentioned embodiments, but can be variously modified within the scope of the present invention, and they are not excluded from the scope of the present invention.

[0047]

As described in detail above, according to the present invention, in the filling tank deaerating device, a closed filling tank, and a negative pressure forming portion for forming a negative pressure in the filling tank, A supply unit that supplies the liquid food to the filling tank, a discharge unit that discharges the liquid food from the filling tank, and a set amount of liquid food in the filling tank is sucked by a set amount through the discharge unit, and then into a metering supply pipe. And a metering device for sending out.

In this case, since a negative pressure is formed in the filling tank, the air that has entered the filling tank is removed by the negative pressure. Therefore, when the liquid food is filled in the carton, the filling amount does not vary, the flow of the liquid food during the filling can be stabilized, and the liquid food can be prevented from overflowing. . Further, it is possible to prevent the quality of the liquid food from being deteriorated.

Further, since a negative pressure is formed in the filling tank, the bubbles contained in the liquid food product expand and the diameter increases accordingly. Therefore, the expanded bubbles tend to naturally rise due to the buoyancy, and the bubbles separated from the liquid food can be increased.

In another filled tank degassing apparatus of the present invention, the supply unit further includes a diffuser for supplying the liquid food at a low speed.

In this case, since the speed of the liquid food is reduced by the diffuser in the supply unit, even if the air that has entered the supply unit becomes bubbles and is contained in the liquid food, the speed of the liquid food flowing through the diffuser becomes low. Accordingly, the bubbles are separated from the liquid food product.

In still another filling tank degassing device of the present invention, the supply section causes liquid food to enter the filling tank in a tangential direction.

In this case, since the liquid food product is introduced tangentially to the filling tank, the liquid food product in the filling tank is sufficiently stirred and air bubbles can be sufficiently separated from the liquid food product.

In still another filling tank degassing device of the present invention, a bubble collecting member for collecting bubbles in the liquid food product is further arranged at the discharge part.

In this case, the air bubbles in the liquid food are collected by the air bubble collecting member, aggregated, and rise in the filling tank by buoyancy. Therefore, air bubbles can be sufficiently separated from the liquid food.

In still another filling tank deaerator of the present invention, in the metering device, the speed at which the liquid food is sucked is set in advance so that the bubbles are sufficiently attached to the bubble collecting member. It

In this case, in the measuring device, the speed at which the liquid food is sucked is set in advance so that the air bubbles are sufficiently adhered to the air bubble collecting member, so that the air bubbles can be sufficiently separated from the liquid food. it can.

[Brief description of drawings]

FIG. 1 is a perspective view of a filling tank according to an embodiment of the present invention.

FIG. 2 is a schematic view of a conventional filling machine.

FIG. 3 is a schematic diagram of a filling machine according to an embodiment of the present invention.

[Explanation of symbols]

12 Measuring pump 13 Measuring supply pipe 15 carton 18 openings 20 weighing space 51 supply pipe 61 filling tank 64 pipelines 65 diffuser 67 Bubble collecting member

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) // B65B 3/12 B65B 3/12 F term (reference) 3E118 AA04 AB14 BB16 CA03 DA05 DA08 EA03 4D011 AA02 AA04 AA08 AA16 AC01 AC04 AC06 AD03 AD06 4G068 AA02 AB30 AC16 AC17 AD24 AE06 AF01 AF31

Claims (6)

[Claims] 1. (a) a sealed filling tank; and (b)
A negative pressure forming part for forming a negative pressure in the filling tank, and (c)
A supply unit for supplying liquid food to the filling tank, (d)
A discharge part for discharging liquid food from the filling tank,
(E) A filling tank degassing device, comprising: a weighing device that sucks the liquid food in the filling tank by a set amount through the discharging portion and sends the suctioning liquid to a measuring supply pipe. 2. The filling tank deaerator according to claim 1, wherein the supply unit includes a diffuser for supplying the liquid food at a reduced speed. 3. The filling tank degassing device according to claim 1, wherein the supply unit causes liquid food to enter the filling tank in a tangential direction. 4. The filling tank degassing device according to claim 1, wherein a bubble collecting member that collects bubbles in the liquid food is arranged in the discharge part. 5. The filling tank deaerator according to claim 4, wherein in the metering device, the speed at which the liquid food is sucked is set in advance so that bubbles sufficiently adhere to the bubble collecting member. 6. The suction mode in which the weighing device sucks a predetermined amount of the liquid food in the filling tank through the discharge portion and stores it in a weighing space, and the liquid food which is stored in the weighing space is weighed. The filling tank deaerator according to claim 1, which is operated in a delivery mode for delivering to a supply pipe and filling a carton.