JPH038402A - Device for removing gas in liquid - Google Patents

Abstract

PURPOSE:To supply a liq. having a low content of gas by connecting the opening at the tip of a gas removing pipe provided almost at the center axis part of a vortex chamber to a suction device operated by the liq. itself being fed. CONSTITUTION:The vortex chamber 1 is set in a feed pipe 3 on the suction side of a liq. feed pump 4. The gas removing pipe 6 is provided almost at the center axis part of the vortex chamber 1, and the opening 7 at the tip of the gas removing pipe 6 is coupled or connected to the suction device 8 operated by the liq. itself being fed. As a result, the bubbles suspended in the liq. and the gas dissolved in the liq. are simultaneously removed, and a liq. having a low content of gas can be supplied.

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Application Field) The present invention relates to a device for removing gas from a liquid, which removes gas floating or dissolved in a liquid and supplies a liquid with a low gas content.

In particular, this device can be extremely effectively used in industrial machinery that uses devices in which gases floating or dissolved in a liquid are a problem. In other words, various machines that require lubricating oil,
For example, it can be used in automobile engines, industrial engines, internal combustion engines such as gas turbines, external combustion engines, and various hydraulically operated devices.

In addition, when transporting liquid raw materials, liquid semi-finished products, or liquid products, if the inclusion of gases such as air becomes a problem, for example, paper sizing liquid containing surfactants or air sizing agents floating in the body may become a problem. Technology that can simultaneously remove gases dissolved in coating liquids containing monomers and polymers, as well as bubbles in them, can be used in the desired flow mechanism.
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(Prior art) Conventionally, methods for removing gas contained in a liquid include simply utilizing the buoyancy of the gas, and
3. Japanese Patent No. 1371889, Japanese Unexamined Patent Publication No. 1-104315
There is a method of applying rotational motion to a liquid containing air bubbles and utilizing the difference in centrifugal force acting on the gas and liquid to collect the air bubbles at the center of the rotation and unite them, making them easier to remove. there were.

(Problems to be Solved by the Invention) In all of these methods, after the liquid containing gas is pumped, the flow velocity is used to apply rotational motion to the liquid containing gas to remove air bubbles floating in the liquid. However, it cannot be an effective method at all for gases dissolved in liquids. Consisting of a pump and a swirling flow chamber installed in a flow pipe on the suction side of the pump,
A gas removal tube is provided approximately at the center of the swirling flow chamber at the shaft portion, and the tip opening of the gas removal tube is coupled or connected to a suction device operated by the flowing liquid itself. This is a device for removing gas from a liquid.

As the suction device, a gear pump, trochoid pump, vane pump, or centrifugal pump is used.

The device for removing gas in a liquid according to the present invention is characterized in that the diameter of the cross-sectional circle of the swirling flow chamber provided in the flow pipe becomes smaller from the upstream side to the downstream side of the swirling flow chamber. In some cases.

Furthermore, in the device for removing gas in a liquid according to the present invention, a liquid suction cloth for filtering the liquid is provided near the bottom of the swirling flow chamber so as to cover the bottom and the swirling flow inlet. The gas can be easily removed through the gas removal tube, and the gas can be easily removed through the gas removal tube.
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(Function) In the device for removing gas in a liquid configured as described above, the air bubbles floating in the liquid expand and coalesce due to the depressurizing action caused by suction on the suction side of the flow pump. The gas is easy to separate from liquids with different densities while swirling in the swirling flow chamber, and the combined gas with low density tends to gather at the central axis of the swirling flow chamber due to the difference in centrifugal force between the gas and the liquid.

In addition, gas dissolved in the liquid is likely to precipitate out of the liquid as a gas due to the decompression effect mentioned above, and the precipitated gas is likely to expand and coalesce, and the difference in centrifugal force with the liquid causes the swirling flow chamber to They tend to gather around the central axis.

On the other hand, a gas removal tube is provided in the central axis of the swirling flow chamber, and the gas removal tube is coupled or connected to a suction device operated by the flowing liquid itself. The opening is in a reduced pressure state (Example) Examples based on the present invention will be described below, but the present invention is not limited to the following Examples.

First Implementation Figure 1 shows an example in which the present invention is applied to the removal of gas from engine oil.

The bottom of the swirling flow chamber 1 is cylindrical, and two swirling flow introduction pipes 2 are provided at symmetrical positions with respect to the central axis of the swirling flow chamber 1 in the tangential direction of the cylindrical portion. .

The cross-sectional diameter of the swirling flow chamber 1 becomes smaller toward the downstream, and the upper part of the swirling flow chamber 1 is connected to the flow pipe 3. The flow pipe 3 is connected to an oil pump 4.

On the other hand, a gas removal tube 6 having a large number of small holes 5 is provided at the central axis of the swirling flow chamber 1, and an upper opening 7 of the gas removal tube 6 is installed in the middle of the flow tube 3. It is connected to a conduit 9 that connects to a gear pump 8. A gear pump box 10 is installed in the middle of the flow pipe, and an impeller 12 that shares an axle 11 with one gear of the gear pump 8 is installed in the box so that a part of the impeller 12 comes out into the flow pipe 3. It is provided.

Further, an oil screen 13 is provided at the lower part of the swirling flow chamber 1 so as to cover the swirling flow introduction pipe 2 .

When sucked by the oil pump 4, the gas-containing engine oil passes through the oil screen 13, after which coarse particles are filtered out, and then enters the swirling flow introduction pipe 2. Swirling flow introduction pipe 2
The engine oil containing gas exiting in the tangential direction flows upward through the swirling flow chamber 1 while generating a strong swirling flow. While the swirling flow is occurring, the gas in the engine oil collects around the gas removal pipe 6, and the engine oil from which the gas has been removed collects around the outer periphery of the swirling flow chamber 1, causing the impeller 12 to move. Without rotating, the oil flows through the flow pipe 3 in the direction of the oil pump 4.

When the impeller 12 rotates, the gear pump 8 is operated by the gear that shares the impeller 12 and the axle 11.
The inside of the gas removal tube 6 is suctioned through the conduit 9 connected to the gas removal tube 6, and the gas that has gathered around the gas removal tube 6 is suctioned. The sucked gas passes through the gear pump 8 and is discharged to the outside through the gear pump discharge port 14 and the check valve 34.

Second Embodiment The second embodiment was produced as a prototype for liquids that generally contain gas, and will be explained with reference to FIG. 2(a).

In the lower cylindrical portion of the swirling flow chamber 15, - number of swirling flow introduction pipes 16 are provided in the tangential direction.

The cross-sectional diameter of the swirling flow chamber 15 becomes smaller toward the downstream, the upper part of the swirling flow chamber 15 is closed, and a large number of through holes 18 are provided in the side wall 17 of the swirling flow chamber 15. . A trochoid pump 19 is built into a pump case 20 at the bottom of the central axis of the swirling flow chamber 15 , and a hollow axle 2 of a gear 21 inside the trochoid pump 19 is installed.
2 is connected to an impeller axle 24 of an impeller 23 provided on the outer periphery of the pump case 20 in the swirling flow chamber 15 .

Inside the hollow axle 22, a hollow shaft 2 of the pump case 20 is provided.
A Karman vortex generator 26 is attached to the upper part of the hollow shaft 25, and a large number of small holes 2 are provided.
A gas removal tube 28 with 7 is installed.

A trumpet-shaped outer case 2 is provided outside the swirling flow chamber 15.
The upper part of the outer case 29 is connected to a flow pipe 30, and the flow pipe 30 is connected to a suction pump 31.

By being sucked by the suction pump 31, the gas-containing liquid passes through the swirling flow introduction pipe 16 and rises to the upper part of the swirling flow chamber 15 while rotating the impeller 23 while generating a swirling flow. While the swirling flow is occurring, the gas in the liquid gathers in the direction of the central axis. The gas removal pipe 28 provided at the center shaft is connected to the suction port 32 of the trochoid pump 19 which is rotated by the impeller 23, and is strongly sucked in, so that the gas collected at the center shaft of the swirling flow chamber 15 is removed. is discharged through the small hole 27, through the gas removal pipe 28 and the trochoid pump 19, and from the discharge port 33 of the trochoid pump 19 through the check valve 34.

The liquid from which gas has been removed passes through the through hole 18 provided in the side wall 17 of the swirling flow chamber 15 and flows into the flow pipe 30.

Note that FIG. 2(b) is a sectional view taken along the xy plane of FIG. 2(a).

(Effects of the Invention) Since the present invention is configured as described above, it produces effects as described below.

A suction device consisting of a liquid flow pump and a swirling flow chamber installed in a flow pipe on the suction side of the pump, a gas removal pipe provided in the swirling flow chamber, and operated by the liquid itself to be flowed. By connecting this gas removal tube to the liquid, it is possible to simultaneously remove not only air bubbles floating in the liquid but also gas dissolved in the liquid, making it possible to supply liquid with extremely low gas content. Become.

Furthermore, since a suction device is used that is operated by the liquid itself, the gas removal device can be made extremely compact. Therefore, by incorporating the gas removal device according to the present invention into machines that require lubricating oil, such as automobile engines, industrial engines, internal combustion engines such as gas turbines, external combustion engines, and various hydraulically operated devices, it is possible to On the lubricating surface of machines, it is possible to prevent the gas contained in the lubricating oil from breaking the oil film and form a sufficient oil film, thereby preventing wear and tear on the machine.

In addition, various industrial machines that incorporate hydraulically operated mechanisms, such as various construction machinery and machine tools, incorporate many hydraulically operated mechanisms for directional control, position control, and pressure control. The operating efficiency and operating accuracy of these hydraulic operating mechanisms deteriorate when gas is contained in the hydraulic fluid, but by incorporating the gas removal device according to the present invention, these operating efficiency and operating accuracy can be greatly improved. It has the effect of improving.

In addition, recent passenger car engines sometimes incorporate operating mechanisms that use hydraulic pressure, such as hydraulic tappets and variable valve mechanisms, and the power source for these hydraulic operating mechanisms is an engine pressurized by an oil pump. Oil is used as a working medium, and if gas is contained in the engine oil, the operating efficiency and operating accuracy of these hydraulic operating mechanisms will deteriorate, but the gas removal device according to the present invention can be compactly installed inside the engine. By incorporating these, the operating efficiency and
This has the effect of greatly improving operating accuracy.

In addition, industrial fields that may cause technical defects in products due to the presence of gases in liquids, such as industrial fields that handle paper sizing liquids or coating liquids containing silicate or polymers, etc. By incorporating the gas removal device according to the present invention into the flow process of these liquids,
This has the effect of eliminating technical defects that may occur in the final product due to gas, and making it possible to produce a final product of uniform quality.

[Brief explanation of drawings]

FIG. 1 shows a first embodiment of the present invention, and FIG.
) is a sectional view of a device for removing gas in a liquid according to a second embodiment of the present invention. FIG. 2(b) is a sectional view taken along the X-Y plane of FIG. 2(a). Swirling flow chamber Swirling flow inlet pipe Side wall through hole Trochoid pump Pump case inner gear Hollow axle Impeller Impeller axle 25° 26° 27° 28° 29° 30° 31° 32° 33° 34° Hollow shaft Karman vortex generation Equipment Small hole Gas removal tube Outer case Flow tube Suction pump Suction port Discharge port Check valve

Claims (1)

[Claims] 1. Consists of a liquid flow pump and a swirling flow chamber installed in a flow pipe on the suction side of the pump, and a gas removal pipe is provided approximately at the central axis of the swirling flow chamber. . A device for removing gas in a liquid, characterized in that the opening at the tip of the gas removal tube is coupled or connected to a suction device operated by the liquid itself being fed. 2. The device for removing gas in a liquid according to claim 1, wherein the diameter of the circle in the cross section of the swirling flow chamber becomes smaller from the upstream side to the downstream side of the swirling flow chamber. 3. Claim 1 or 2, characterized in that a liquid screen for filtering liquid is provided near the bottom of the swirling flow chamber so as to cover the bottom and the swirling flow inlet. Equipment for removing gases from liquids. 4. The device for removing gas from a liquid according to claim 1, 2 or 3, wherein a check valve is provided in the discharge pipe of the suction device.