JPH0137730Y2 - - Google Patents

Description

[Detailed description of the invention] (Field of industrial application) This invention is capable of continuously pumping high-viscosity liquids filled in containers such as pails or drums with high precision and quantitative performance. This invention relates to a fixed-quantity dispensing device.

(Prior art and its problems) In general, a single-shaft eccentric screw pump type or an air-driven piston pump is used as a device to transfer high viscosity liquid filled in a container such as a pail or drum can. It is used.

The former uniaxial eccentric screw pump is suitable for transferring a large flow rate of liquid, but is not suitable as a precision metering dispensing device because it does not have quantitative performance and discharge pressure is insufficient. In addition, the latter type of air-driven piston pump has a high discharge pressure, but because the liquid is discharged intermittently, the discharge volume pulsates, and the discharge volume also fluctuates as the discharge pressure changes. Therefore, it cannot be used when quantitative performance is required for liquid transfer.

Therefore, when transferring high-viscosity liquids filled in containers such as pails or drums continuously with high precision and quantitative performance, an air-driven pump is used to remove the liquid from the can. Attempts have been made to store the liquid in a service tank and continuously transfer it using a metering pump, or to transfer the liquid by connecting the suction port of the metering pump to the discharge port of an air-driven pump. However, even with this method, in the former case, air bubbles generated in the service tank are transferred together with the liquid, and if the liquid is highly viscous, the liquid is not delivered to the suction port of the metering pump, resulting in insufficient suction. Unable to exhale. Also, in the latter case, the high discharge pressure of the air-driven pump acts directly on the suction port of the metering pump, which impairs the metering performance of the metering pump itself, and excessive pressure also acts on the seal, causing leakage. occurs. Furthermore, there are problems such as the installation of a service tank increases the size of the entire device.

(Purpose) The purpose of the present invention is to provide a device that can reliably, easily, and quantitatively discharge high-viscosity liquids filled into containers such as pails or drums. That's true.

(Means for Solving the Problems) In order to achieve the above-mentioned object, the liquid metering dispensing device of the present invention includes a rotary positive displacement pump 6 mounted on the lifting table 1, and below the pump 6: A guiding member 11 is attached to cover the suction port, and the outer peripheral portion of the guiding member 11 is shaped to abut against the inner wall of the liquid container.

(Example) An example of the configuration of the liquid metering discharge device of the present invention will be described based on the drawings.

Reference numeral 1 designates a lifting platform formed by a cylinder 3 installed perpendicularly to a base plate 2 and a bracket 4 attached to a piston rod of the cylinder 3. In place of the cylinder 3, an elevating mechanism comprising a constant torque motor, a rack and pinion, etc. may be used. Furthermore, if a heating device (not shown) is installed on the base plate 2 to heat the wall or bottom of a pail or drum can, even ultra-high viscosity liquid can be reliably discharged. A drive motor 5 is mounted on the bracket 4, and is a variable speed motor, a motor with a continuously variable transmission, or the like. 6 is a rotary displacement pump such as a gear pump attached to the pump block. The pump block 7 is attached to the bracket 4 by a connecting rod 10. In addition, the output shaft of the drive motor 5 and the drive shaft of the rotary displacement pump 6 are
They are integrally connected by a shaft 8 and a coupling ring 9. A guiding member 11 is integrally attached to the lower surface of the pump block 7 mentioned above. The guiding member 1
1, a flexible plate 13 in the form of a hollow disc made of synthetic rubber or synthetic resin is integrated into a dielectric 12 that has a bowl-like shape and has a liquid inlet at the top, as shown in FIG. or,
These are formed in one piece. Then, the liquid in the can is pressed so as to cover it from above and guided to the liquid inlet, and the flexible plate 13 comes into contact with the inner wall of the can filled with liquid to scrape off the liquid adhering to the wall surface. 14 is a perforated plate, and metal rope 1 for the filter
5 is attached to the lower part of the dielectric 12. Instead of the wire 15, a pump block 23 as shown in FIG. 4 or a filter 24 formed of sintered metal is attached to the suction part of the rotary displacement pump 6 using a restraint 25 or the like. You can also do that. 16 is an air vent attached to the upper part of the induction body 12, and 17 is a liquid feeding pipe connected to the discharge port of the pump block 7. Reference numeral 18 denotes an air vent installed in a position close to the connection portion of the liquid sending pipe 17 with the pump block 7. Also,
It is also possible to connect a flow meter (not shown) to the liquid sending pipe 17 and control the discharge amount in conjunction with the drive motor 5.

When the above-mentioned inductor 12 is pressed with a predetermined surface pressure against the liquid level in the can by the cylinder 3, and the drive motor 5 is activated to rotate the rotary displacement pump 6, the liquid flows through the metal wire 15 and the perforated plate. 14, and
The liquid is sucked into the rotary displacement pump 6 through the pump block 7 and discharged from the liquid feed pipe 17.

When discharging liquid from a pail using the above-described device, first, pressurized air is supplied to the cylinder 3 to cause the piston rod to protrude, and the inductor 12 to be raised together with the bracket 4 to a predetermined position. Next, when the pail can A is placed on the base plate 2, the pressurized air supply circuit to the cylinder 3 is switched and the piston rod is retracted, and the inductor 1 is removed together with the bracket 4.
2 and insert it into the pail can A. When the guide 12 reaches the liquid level in the pail A, it stops at that position and presses the liquid A with a predetermined image pressure. In this state, the air vents 16 and 18 are opened, and the drive motor 5 is operated to rotate the rotary displacement pump 6. Then, pail can A
Impurities are removed from the liquid a by the metal wire 15 and the perforated plate 14, and the liquid a is transferred from the derivative 12 to the pump brake 7.
The liquid is sucked into the rotary displacement pump 6 through the liquid supply pipe 17 and discharged from the liquid supply pipe 17. At this time, the air that has entered the induction body 12 is discharged from the air vent 16, and the air that has been present inside the rotary displacement pump 6 and pump block 7 is discharged from the air vent 18. After the air has been released, the air vents 16 and 18 are closed. Then,
Liquid a in the pail can A is discharged from the liquid feeding pipe 17. Then, when the liquid level in pail A falls,
The guide 12, which is being pressed downward by the cylinder 3, also descends at the same time. When the guide 12 descends, the flexible plate 13 scrapes off the liquid a adhering to the can wall surface. When the liquid a in the can is sent out and the metal rope 15 attached to the inductor 12 reaches the bottom of the pail can A, the drive motor 5 is stopped and the pressurized air supply circuit to the cylinder 3 is switched. The piston rod is projected to raise the induction body 11 together with the bracket 4, and the pail can A is taken out and replaced with the pail A prepared next.

In the above-described liquid discharging operation, when discharging the liquid is temporarily stopped, the drive motor 5 is stopped.

Although the present invention can be implemented as described above, the apparatus for discharging liquid from a large can such as a drum is as shown in FIG. A plurality of cylinders 2 are installed so that the liquid can be sufficiently pressurized.
9 is integrally attached, and the intermediate bracket 18
The pump block 7 and the induction body 21 are integrally attached to each other by a connecting pipe 10. Also, derivative 2
1 and the liquid sending pipe 17 are connected to the return pipe 22 by a three-way valve (not shown) to form a return pipe, it is possible to circulate the liquid in the can and to prevent the liquid from stagnation in the liquid sending pipe 17. You can also prevent it from happening.

(Effects of the invention) The liquid fixed-quantity dispensing device of the invention includes a rotary displacement pump 6 mounted on the lifting platform 1, and the pump 6
A guiding member 11 is placed below the suction port so as to cover the suction port.
is attached, and the outer peripheral part of the guiding member 11 is configured to be in contact with the inner wall of the liquid container, so that when the liquid is pressed by the guiding member, the pail can, Alternatively, the high viscosity liquid in the drum can be discharged continuously or intermittently with highly accurate quantitative properties. Further, since the guide member is in contact with the inner wall of the tube, the liquid adhering to the can wall can be scraped off and completely discharged.

[Brief explanation of the drawing]

FIG. 1 is a schematic diagram showing one embodiment of the liquid metering discharge device of the present invention. Figure 2 shows 1 of the liquid guide section.
It is a schematic enlarged view showing an example. FIG. 3 is a schematic diagram showing an embodiment of another liquid metering discharge device. FIG. 4 is a schematic cross-sectional view showing one embodiment of the filter mounting section. DESCRIPTION OF SYMBOLS 1... Lifting platform, 2... Base board, 3... Cylinder, 4... Bracket, 5... Drive motor, 6...
...Rotary displacement pump, 7,23...Pump block, 8...Shaft, 9...Coupling, 10,20
...Connecting rod, 11...Guiding member, 12, 21...
Derivative, 13... Flexible plate, 14... Perforated plate, 15
...Kanetsu, 16, 18...Air bleed, 17...
Liquid sending pipe, 19... intermediate bracket, 22... return pipe, 24... filter, 25... suppressor.

Claims (1)

[Scope of utility model registration request] A rotary positive displacement pump 6 is mounted on the lifting platform 1, and a guide member 11 is mounted below the pump 6 so as to cover its suction port, and the outer circumference of the guide member 11 is brought into contact with the inner wall of the liquid container. A liquid metering dispensing device characterized by having a shape.