JP2566456B2 - Quantitative filling device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial field of application) The present invention fills a container with a fluid such as a beverage, a drug, an alcoholic beverage, a gelled product, a high-concentration liquid, a high-viscosity liquid, a solid-containing liquid, and a gas-containing liquid. The present invention relates to a metering filling device used to do this.

(Prior Art) Conventionally, quantitative filling of a fluid in a fluid filling machine has been an important factor in yield control, and a fluid measuring cylinder is attached to the filling nozzle and a fixed amount is transferred from the filling nozzle to the container via the measuring cylinder. A method of filling a fluid was practiced.

However, the metering and filling device by cylinder metering is not suitable as a device that responds to high demand for quality such as sterilization because the filling mechanism is increased by the number of cylinders, and recently, using a flow meter as a measuring method. What you do has been adopted.

In the case of using a flow meter, the filling amount tends to fluctuate depending on the performance of the filling valve in the filling nozzle.To improve this, fill at a large flow rate at the initial filling and change the valve to a small flow rate when approaching the specified amount. Japanese Patent Application Laid-Open No. 56-151695 proposes a method for the purpose of constant amount filling. Further, a uniaxial eccentric pump has been used for the purpose of making the filling portion of the filling machine compact to improve the metering property and preventing the variation of the filling amount.

The uniaxial eccentric pump is a pump in which an externally threaded rotor having a perfect circular cross section is rotated at an eccentric center in an internally threaded stator having an oval cross section and made of an elastic material. What measures the filling amount using the filling pump as described above is disclosed in JP-A-56-69518 and JP-A-62-1.
No. 68806 and JP-A No. 62-269771.

The one disclosed in Japanese Patent Laid-Open No. Sho 56-69518 controls the filling valve by detecting the rotational speed of the pump.
Japanese Patent Laid-Open No. 62-269771 uses a variable speed motor as a driving device for the filling pump, while the filling valve on the discharge side of the filling pump is eliminated.

(Problems to be solved by the invention) In the case of using the above-mentioned flowmeter, there is a change in the filling amount due to the flow of the flow rate even during the opening / closing operation of the valve, and therefore, the valve performance is important, the property of the fluid Since the change of the fluid flow rate due to the change of the flow rate and the change of the flow rate due to the change of the internal pressure of the filling tank are unavoidable, the stepwise closing control of the nozzle can be performed as in JP-A-56-151695. Those that operate under constant conditions cannot cope with changes in fluid over time or changes in fluid.

In particular, when the fluid is a solid-containing fluid, the solid content is crushed or broken, or the valve is clogged.

Further, in the case of a bubble-containing fluid, the volume of the fluid fluctuates as the pressure applied to the fluid changes, and quantitative filling cannot be performed by a simple measuring method.

In addition to this, high-viscosity fluid or the like causes poor liquid drainage at the nozzle port, resulting in liquid dripping, which pollutes the container and causes poor sealing or destabilization of the volume.

On the other hand, in the uniaxial eccentric pump, the filling part of the filling machine can be made compact to improve the metering property, and further, the deterioration of the properties of various fluids can be minimized. As can be seen, there has been no realization of quantitative control that responds to changes in the volume of fluid and prevention of dripping at the filling port.

Therefore, it is an object of the present invention to solve the above problems and to provide a quantitative filling device capable of quantitative filling even in a fluid whose volume changes with time and which has a high viscosity and is liable to drip. To do.

(Means for Solving the Problems) The present invention provides the following quantitative filling device in order to achieve the above objects.

The first means is a quantitative filling device for quantitative filling using a quantitative transfer pump, in which a pressure measuring device for detecting the pressure of the fluid is arranged at the fluid inlet or the liquid supply chamber of the quantitative transfer pump, and based on the measurement result. It is a fixed quantity filling device provided with a control device for controlling the rotation speed of a fixed amount transfer pump.

By using the device as described above, it is possible to perform a fixed amount filling corresponding to the change in the volume of the fluid, and in the fixed amount filling device in the first means, the fixed amount transfer pump is a pump capable of forward and reverse rotation, and the pump is also When the fluid is filled, a constant quantity filling device, which is a pump configured to reversely rotate through a control device so as to suck a fluid amount corresponding to the liquid drip into the pump, has a high viscosity and causes liquid drip. It is possible to quantitatively fill even an easy fluid. In the case of a fluid containing bubbles, some bubbles may be destroyed when a negative pressure is reached.Also, even if the content of bubbles changes, a constant amount is always filled at the inlet of the metering transfer pump. A third means is to provide a device for pressurizing and transporting the fluid before the inlet of the fluid so that the pressure of the fluid does not fall below atmospheric pressure.

A pulse motor or a servomotor is used as the driving device for the quantitative transfer pump as described above. Furthermore, by using a uniaxial eccentric pump for the quantitative transfer pump, even a fluid containing bubbles or solid matter can be transferred. Aseptic filling is made possible by making the outer peripheral wall of the stator part, which houses the rotor, double, and supplying or closing the space with a sterilizing agent or steam.

Further, by disposing a valve or a mesh body in the filling opening portion after the discharge port of the uniaxial eccentric pump, it is possible to provide a constant quantity filling device capable of preventing dripping even in a low viscosity fluid.

(Operation) According to the present invention, the pressure of the fluid is detected by the pressure measuring device provided in the liquid supply chamber of the constant-quantity transfer pump or the fluid inlet, and the rotation speed of the pump is controlled to change the volume of the fluid. However, it is possible to fill a fixed amount. Further, after the fixed amount is discharged, the pump is rotated in the reverse direction to suck the fluid into the pump to prevent the dripping and further enable the fixed amount filling.

Furthermore, by pressurizing the fluid transfer pressure in the pump so as not to be lower than the atmospheric pressure, it is possible to prevent the bubbles of the bubble-containing fluid from breaking and to perform the quantitative filling.

The rotation control of the pump as described above can be performed in the forward and reverse directions by using a pulse motor or a servomotor.By using a uniaxial eccentric pump as a fixed-quantity transfer pump, even the solid-containing fluid crushes or destroys the solid content. It is possible to perform quantitative filling without performing the above-mentioned operation, and the stator portion that houses the rotor of the uniaxial eccentric pump has a double structure, and by assembling the sterilizing agent or supplying steam, aseptic filling can be performed together with the quantitative filling.

Further, in the uniaxial eccentric pump, a valve or a mesh body is attached to the filling port to prevent dripping in the case of a low-viscosity fluid, and it is possible to perform a fixed amount filling.

(Example) Hereinafter, the Example shown in drawing is described.

FIG. 1 is a flow sheet showing a filling mechanism, FIG. 2 is a filling mechanism diagram in which a uniaxial eccentric pump (monopump) is used as a metering transfer pump, FIG. 3 is an operation diagram of the filling pump, and FIG. 4 is a uniaxial eccentric pump. Sectional views are respectively shown.

The fluid is filled into the container (1) from the filling tank (10) through the fluid inlet (8), the liquid supply chamber (11) and the pump (2) through the filling nozzle (9).

A uniaxial eccentric pump (2) is used as a fixed-quantity transfer pump, and a pressure measuring device (4) is provided at a fluid inlet (8), and this signal is converted by a pressure converter (5), and a controller (6) In (), a signal is output from the measured value to the controller (7) that controls the rotation of the pulse motor (3).

As shown in FIG. 4, the uniaxial eccentric pump (2) pumps by rotating an externally threaded rotor (12) having a perfect circular cross section at an eccentric center with an internally threaded stator (13) having an oval cross section and made of an elastic material. Causes the rotor (1
2) is driven from the motor (3) via the connecting part (15). The liquid supply chamber (11) refers to a portion having the connecting portion (15), and the pressure measuring device (4) may be installed also in this portion.

The present invention is characterized in that the rotation speed of the pump is controlled by the fluid pressure as described above.For example, in a filling machine for filling whipped cream, air bubbles are contained in the overrun whipped cream. The volume of the bubbles changes due to the pressure of the fluid being sent out, and the filling amount changes.

Therefore, in order to make the filling amount in the container after filling constant,
It is necessary to change the rotational speed of the pump according to the constantly changing fluid pressure to cope with the change in volume that changes with the pressure.

The bubble-containing fluid having a pressure P is sent by a metering pump that delivers a fluid having a volume q per revolution, and the volume when it is discharged from the nozzle into the atmosphere at a pressure P ₀ is V, and the gas volume contained in this is A ₀ , liquid volume L, porosity ρ ₀ = A ₀ / (A ₀ + L) approximately It is represented by.

The filling amount (volume) Q of the container once becomes Q = VN when the total number of rotations of the pump is N, and P is actually measured to keep Q constant. The total pump speed may be controlled so that Also P
If V fluctuates during filling, V is integrated over time and Q
The pump may be stopped immediately before reaching Q or after reaching Q.

As described above, the rotation speed of the pump is controlled by detecting the pressure of the fluid. In the present invention, by measuring the pressure at the fluid inlet, (1) the rapid pressure of the fluid due to the forward rotation and the reverse rotation of the filling machine. It is possible to adjust the volume variation due to the variation of the pressure loss due to the variation and the change of the physical property of the fluid.

(2) When the fluid contains bubbles, the contained air volume fluctuates due to the pressure fluctuation of (1), and the total volume of the fluid fluctuates. Therefore, it is possible to adjust the quantity by controlling the rotation speed.

In the present invention, in the constant amount filling device as described above, after the constant amount discharge, the pump is rotated in the reverse direction to suck the fluid into the pump to prevent the liquid from dripping, and it is possible to prevent the variation of the amount and the adhesion of the fluid to the head wall of the filling container. Sealing failure can be prevented. FIG. 3 shows the operating state, and the dotted line shows the case where the pressure becomes high.

A pulse motor or servomotor is used to control the rotation of the pump, and a uniaxial eccentric pump is used as the fixed-quantity transfer pump, which can be applied to fluids such as highly concentrated liquids, highly viscous liquids, solid-containing liquids, and gas-containing liquids. As a result, a quantitative filling device with a wide range of use can be obtained.

Therefore, aseptic filling can be performed together with quantitative filling by making the outer peripheral wall of the stator (13) of the uniaxial eccentric pump shown in FIG. 4 double and supplying or closing the space (14) with a sterilizing agent or steam. Moreover, the filling nozzle (9) and the pump discharge port can be connected without using a filling valve, and the contaminated portion can be reduced especially when aseptically filling.

In the case of aseptic filling, steam is not used as a sterilization method for those accompanied by heat denaturation.

Further, in a uniaxial eccentric pump, there is a gap between the rotor (12) and the stator (13), and even if the rotor (12) is stopped, the fluid leaks through the space volume of the rotor, causing liquid dripping. Particularly in the case of a bottom viscous fluid, a valve or a mesh body can be arranged at the filling opening to prevent fluid leakage.

(Effects of the Invention) According to the present invention, it is possible to perform quantitative filling even by sequentially measuring and controlling a liquid that changes in volume with time and has a high viscosity and is likely to drip.

Therefore, according to the first aspect of the present invention, even when the pressure of the fluid containing gas fluctuates, the fluctuation of the volume is detected by the pressure detection, and the rotation of the filling pump is automatically controlled.

According to the invention of claim 2, the fluid is sucked into the filling pump in order to prevent the liquid from dripping, so that the contamination due to the external factor of the fluid, the valve or the like which easily causes the contamination can be eliminated, and the container is prevented from dripping. It is possible to do quantitative filling without causing stains and poor sealing.

According to the third aspect of the present invention, it is possible to prevent the bubbles of the bubble-containing fluid from being destroyed and to perform the quantitative filling.

By using a pulse motor or a servomotor as a driving device for the constant-quantity transfer pump, it is possible to perform fine disassembly control of the capacity and rotation speed control, and it is easy to adjust the filling speed against pressure fluctuations.

In addition, by using a uniaxial eccentric pump as a fixed-quantity transfer pump, when filling a fluid containing a solid substance, the solid substance is not destroyed, and a low-viscosity fluid to a high-viscosity fluid,
Also, it is possible to obtain a quantitative filling device which has a wide range of applications including solid-containing fluids.

Thus, the stator part can be used as an aseptic filling machine with a double structure capable of blocking the sterilizing agent or supplying steam, and in the case of low viscosity fluid, a valve or a mesh can be attached to the filling port to prevent dripping. .

[Brief description of drawings]

FIG. 1 is a flow sheet showing a filling mechanism, FIG. 2 is a filling mechanism diagram in which a uniaxial eccentric pump is used as a metering transfer pump, FIG. 3 is an operation diagram of the filling pump, and FIG. 4 is a sectional view of the uniaxial eccentric pump. Is. (1) …… Filling container (2) …… Uniaxial eccentric pump (3) …… Servo or pulse motor (4) …… Pressure measuring device (5) …… Pressure converter (6) …… Control device (7) ...... Motor controller (8) …… Fluid inlet (9) …… Filling nozzle (10) …… Filling tank (11) …… Liquid supply chamber (12) …… Rotor (13) …… Stator

Claims (7)

(57) [Claims] 1. A quantitative filling device for quantitative filling using a quantitative transfer pump, wherein a pressure measuring device for detecting the pressure of the fluid is arranged at a fluid inlet of the quantitative transfer pump or a liquid supply chamber,
A quantitative filling device, characterized in that a control device for controlling the number of rotations of the quantitative transfer pump based on the measurement result is provided. 2. The constant quantity filling device according to claim 1, wherein the constant quantity transfer pump is a pump capable of rotating in the forward and reverse directions, and the pump is rotated in the reverse direction through a control device at the time of filling the fluid, and a fluid amount corresponding to the liquid drop is obtained. A metering and filling device which is a pump configured to be able to suck into the pump. 3. The quantitative filling device according to claim 1, wherein
A quantitative filling device comprising a device for pressurizing and transporting a fluid before the fluid inlet so that the pressure of the fluid at the inflow port of the quantitative transfer pump does not fall below atmospheric pressure. 4. The quantitative filling device according to claim 1, wherein the driving device of the quantitative transfer pump is a pulse motor or a servomotor. 5. The constant quantity filling device according to claim 1, 2, 3, 4, wherein the constant quantity transfer pump is a uniaxial eccentric pump. 6. An aseptic filling capable of supplying or closing a sterilizing agent or steam by forming a double structure on an outer peripheral wall of a stator part in which a rotor of a uniaxial eccentric pump is installed The quantitative filling device according to claim 5. 7. The quantitative filling device according to claim 5, wherein a valve or a mesh body is arranged in the filling opening portion after the discharge port of the uniaxial eccentric pump.