JP2003033614A - Method for decreasing or increasing concentration of solid particle in solid-liquid mixed phase fluid incorporating solid particle and method for separating solid particle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for lowering the concentration of solid particle in solid-liquid mixed phase fluid with a simple constitution, and a constitution of the method of separating the solid particle with a filter on the basis of the method. SOLUTION: In this method, the solid-liquid mixed phase fluid is distributed to a pipe which is plurally branched in an intermediate part, with respect to the solid-liquid mixed phase fluid in a specified branched pipe, the flow rate is set smaller than the average value of flow rate of the total solid-liquid mixed phase fluid before the distributing and, thereby, the concentration of solid particle in the solid-liquid mixed phase fluid is decreased or the flow rate is set larger than the average value and, thereby, the concentration of solid particle in the solid-liquid mixed phase fluid is increased. Further in this method, the solid particle in the solid-liquid mixed phase fluid distributed from the pipe which is decreased in concentration of the solid particle is separated by the filter on the basis of a method decreasing the concentration of solid particle among the respective methods, at the same time, the other distributed solid-liquid mixed phase fluid which does not separate the solid particle is circulated again to the pipe side before the distributing, based thereon, the solid particle is separated from solid-liquid mixed phase fluid and, thereby, the frequency of exchange of filter and the quantity of disposal of the filter can be decreased.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a case where solid particles are mixed in a liquid, as an example, in a solid-liquid multiphase fluid such as lubricating oil mixed with solid particles such as metal powder produced by cutting. A method of reducing or increasing the concentration of solid particles,
And a method for separating solid particles from the solid-liquid mixed phase fluid based on the method.

[0002]

2. Description of the Related Art A fluid in which fine solid particles are mixed in a liquid is called a solid-liquid mixed phase fluid, and the solid particle concentration of the solid-liquid mixed phase fluid (hereinafter abbreviated as "particle concentration"). May be required to be reduced or increased.

For example, when metal powder produced by cutting is mixed in the lubricating oil, the particle concentration is required to be lower than a specific value in order to produce a smooth lubricating effect.

However, while the conventional solid particles are made to flow,
There is no particular way to reduce that particle concentration,
After all, the method of increasing the relative amount of the liquid fluid itself in the solid-liquid mixed phase fluid had to be taken.

However, increasing the relative amount of the liquid fluid is obviously complicated in operation, and
It is uneconomical.

On the other hand, there are various methods for separating solid particles in a solid-liquid mixed phase fluid in which fine solid particles are mixed, but the method of filtering solid particles by a filter is the most typical. That's the method.

However, in this method, when a large number of fine solid particles are mixed, the working efficiency is deteriorated due to the high frequency of filter replacement, and the number of filters to be discarded increases. There was a problem that it was not environmentally and economically preferable.

On the other hand, there is a method of performing a centrifugal separation for performing the above-mentioned separation, but this method is not suitable when the solid particles are fine, and it is necessary to provide a huge rotary centrifuge. Therefore, it is extremely uneconomical.

Furthermore, there is also a method of sequentially precipitating solid particles by gravity, but in the case of fine solid particles, it takes a long time for precipitation, which is unsuitable for work efficiency.

There are other methods for separating solid particles from a solid-liquid mixed phase fluid, but various technical problems cannot be avoided.

[0011]

SUMMARY OF THE INVENTION The present invention focuses on the problems of the prior art as described above, and has a simple structure,
An object of the present invention is to provide a method for reducing the particle concentration of solid particles in a solid-liquid mixed phase fluid, and a configuration related to a method for separating solid particles from the solid-liquid mixed phase fluid based on the method.

[0012]

In order to solve the above problems, the structure of the present invention is (1). The solid-liquid mixed-phase fluid is divided into a plurality of pipes branched in the middle part, and the flow velocity of the solid-liquid mixed-phase fluid in a specific branched pipe is higher than the average value of the flow velocity of all the solid-liquid mixed-phase fluids before dividing. A method of decreasing the concentration of solid particles in a solid-liquid mixed phase fluid by setting it small, or increasing the flow velocity above the average value to increase the concentration of solid particles in a solid-liquid mixed phase fluid, (2) ． Solid-liquid mixed phase fluid,
Divide into a pipe branched into multiple parts in the middle part,
By setting the flow velocity of the solid-liquid mixed phase fluid in the specific branched pipe to be smaller than the average value of the flow velocity of all the solid-liquid mixed phase fluid before the diversion, the solid particle concentration in the specific pipe is reduced. The solid particles are separated from the liquid mixed phase fluid by the filter, and the separated solid-liquid mixed phase fluid which is not separated solid particles is circulated to the pipe side before branching again. A method of separating solid particles.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION As shown in FIG. 1, when a plurality of branched pipes 12 are provided at an intermediate portion of a pipe 11 through which a solid-liquid mixed phase fluid flows, the state of each branched pipe 12 is By adopting different designs, the flow rates of the solid-liquid mixed phase fluid in the pipes 12 can be made different.

Such a difference in the flow velocity is caused by, for example, a difference in the opening degree of the valve 5 provided in each branched pipe 12, a difference in the cross-sectional area of each branched pipe 12, and the branched pipe 1.
It can be realized by the presence or absence of unevenness on the inner wall of No. 2 or a difference based on the degree of unevenness, the difference in angle with the pipe 11 before branching, or a combination of some or all of these.

As described above, in the solid-liquid mixed phase fluid flowing through the branched pipes 12, the particle concentration also decreases as the flow velocity decreases, and conversely, the particle concentration increases as the flow velocity increases. There is a fact.

The grounds for supporting such a fact are not necessarily fixed.

In such a case, if the force applied to the solid particles by the flow of the liquid portion in the fluid is simply proportional to the fluid velocity, the solid particles are Any branched pipe 12
In this case, the degree to which the solid particles are sucked by the liquid portion that branches and flows in each branched pipe 12 is proportional to the fluid velocity in each pipe.

In such a case, the higher the flow velocity,
The number of solid particles sucked in will also increase proportionally, and the difference in particle concentration between the branched pipes 12 is
It cannot happen.

However, in reality, the force that the solid particles receive from the liquid portion in the solid-liquid mixed phase fluid is not in proportion to the velocity of the fluid.

For example, in a stationary fluid in hydrodynamics, when a sphere having a radius a moves at a velocity U, the force F received by the sphere in the flow direction is ρa ² when the fluid density is ρ. It has been found to be proportional to U ² .

On the contrary, the relationship is such that the fluid having the density ρ is
It means that when moving at a velocity U, the force received when a sphere of radius a is stationary is also proportional to ρa ² U ² .

In an actual solid-liquid mixed-phase fluid, the force that solid particles receive is not a simple relationship such as mere square as in the preceding paragraph, but in any case the solid particles receive the liquid portion in the fluid. The force is not a simple proportional relation of the velocity of the fluid to the 1st power, but to the kth power of the velocity U (where k>
When the factor proportional to 1) is included, the higher the velocity of the solid-liquid mixed phase fluid, the more the solid particles are sucked into the branched pipe 12 having the higher velocity.

As a result, when the flow velocity in the branched pipe 12 is higher, the flow rate of solid particles flowing in per unit area becomes relatively large, which may increase the particle concentration.

On the contrary, when the flow velocity of the branched pipe 12 is smaller, the number of solid particles flowing in per unit area becomes relatively small, and the particle concentration also becomes smaller.
It will be smaller.

As described above, the particle concentration is influenced by the magnitude relation of the flow velocity in the branched pipe 12,
It is presumed that this is because the velocity of the solid-liquid mixed-phase fluid and the force received by the solid particles are not simply proportional, but there is an element that is proportional to the k-th power of the relative velocity (where k> 1). , At this point, the exact basis is not always clear.
However, in any case, it has not hitherto been paid attention to decrease the particle concentration due to the magnitude relation of the flow rate as described above.

In the above (1), as shown in FIG. 1, a plurality of pipes 11 are branched at a midway portion, and a design is made so that a difference in flow velocity is generated. , The particle concentration is reduced by the branched pipe 12 having a flow rate lower than the average flow rate per unit area of the all solid-liquid mixed phase fluid, but the number of the branched pipes 12 is plural. However, the number is not particularly limited to two (in FIG. 1, the portion where the pipe 11 branches and changes to the pipe 12 is shown in a particularly enlarged state). However, when three or more branched pipes 12 are set, at least the solid-liquid mixed phase fluid flowing out at the outlet pipe from the pipe having the smallest flow velocity is stored, The particle concentration can be reduced.

In the case of a pipe other than the above pipes,
After comparing with the average flow velocity of the all solid-liquid mixed phase fluid before branching as described above, if it is smaller than that flow velocity, the reduction of the particle concentration is realized, but the degree is It is inferior to the case of the branched pipe with the lowest flow velocity.

The method (2) above is based on the method (1) above, and in the branched pipe 12 in the state where the particle concentration is lowered, as shown in FIG. Although a method of filtering is adopted, the frequency of replacing the filter 4 can be reduced at the stage of using the filter 4 because the particle concentration is lowered (note that the pipe 11 is also used in FIG. 2). The part that changes from the branch to the pipe 12 is shown in a particularly enlarged state.

In the method (2), as shown in FIG. 2, the solid-liquid mixed phase fluid flowing in the other branched pipe 12 which is not the object of filtration by the filter 4 does not undergo the filtration step by the filter 4. The pipe 11 before branching
Will be cycled to.

The particle concentration of the solid-liquid mixed phase fluid which is simply circulated without being filtered by the filter 4 is determined by the pipe 1 before branching.
Since the particle concentration in 1 is high, when the solid particles are separated by the method of (2) above, the particle concentration of the entire solid-liquid mixed phase fluid still remaining without filtration is , But it is not without fear that it will increase gradually.

However, the solid-liquid mixed phase flow returning from the valve 51 and the solid-liquid mixed phase flow coming from 6 do not mix well in the tank 6 immediately.

Further, if the solid-liquid mixed-phase flow supplied from 6 is brought close to the outlet to the tank 2 and the inlet of the branch pipe, most of it is allowed to flow into the branch pipe. Further, the solid-liquid mixed-phase flow returned to the tank 2 via the valve 51 can be reduced in flow rate by increasing the cross-sectional area of the tank 2.

For this reason, the amount of particles precipitated in the solid-liquid mixed phase fluid per unit time in the tank 2 can be increased. Therefore, the above concerns can be virtually eliminated. If it is possible to dramatically reduce the concentration of particles supplied to the filter 4 by increasing the amount of sedimentation in the tank 2 without using a branch pipe, this should solve all the problems of this case. is there.

Hereinafter, description will be given according to the embodiment.

[0035]

Embodiment 1 In Embodiment 1, as shown in FIG.
The structure of (2) including the structure of (1) in the case of branching into two pipes, that is, the case where a so-called Y joint (Y junction) is adopted is shown.

Such a Y-joint is simple in structure and design, and is extremely excellent in that the flow velocities of the branched pipes 12 can be simply designed. In addition, in FIG. 3, both of the branched pipes 12 are designed to form an angle of 180 degrees, but the branched shape of the Y joint is not limited to such a case. That is, for example, in the branched pipe 12, the pipe on the side where the flow rate per unit area is small is closer to the side of the pipe 11 before branching than in the case of the angle of 180 degrees as described above. Angled designs are of course also possible.

[0037]

[Embodiment 2] In Embodiment 2, as shown in FIG.
In the configuration of (2), the storage tank 2 is provided in the middle of the circulation.

In the storage tank 2, the flow of the solid-liquid mixed phase fluid is extremely slow, so that solid particles are precipitated and the concentration of particles flowing into the pipe 11 before branching is determined by the storage tank 2.
Can be reduced than before flowing into.

[0039]

As is clear from the above description, in the present invention, the particle concentration can be reduced while the structure is extremely simple, and the frequency of filter replacement is reduced based on the reduction. Separation of solid particles can be achieved.

By reducing the frequency of filter replacement as described above, it is possible to increase the working efficiency of the entire process and reduce the operating cost.

Moreover, the apparatus corresponding to the method of the present invention is
The installation of the device is simple and inexpensive because it is simply required to branch the pipe portion, and no special control device and power device are required, so that there is almost no failure.

Furthermore, since the amount of the filter to be discarded is reduced, the cost of disposal can be reduced and it can also contribute to the prevention of environmental pollution.

As described above, the present invention can exert multifaceted effects and its value is enormous.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing the basic principle of the invention (1).

FIG. 2 is a schematic diagram showing a basic principle of the configuration of (2).

FIG. 3 is a block diagram showing a configuration aspect of an embodiment.

[Explanation of symbols]

1: Pipe 11: Pipe before branch 12: branched pipe 2: Tank 3: Pump 4: Filter 51, 52, 53: valve 6: Device in which solid particles are mixed in the filtered liquid

   ─────────────────────────────────────────────────── ─── Continued front page    F term (reference) 3J071 AA15 BB02 BB15 CC01 DD24                       EE01                 4D066 AB06 AB10 BB01

Claims (6)

[Claims] 1. A solid-liquid mixed-phase fluid is branched into a plurality of pipes branched at a midway portion, and the flow velocity of the solid-liquid mixed-phase fluid in a specific branched pipe is the flow velocity of all the solid-liquid mixed-phase fluids before dividing. A method of lowering the concentration of solid particles in a solid-liquid mixed-phase fluid by setting the value smaller than the average value of. 2. A solid-liquid mixed phase fluid is divided into a plurality of pipes branched at a midway portion, and the flow velocity of the solid-liquid mixed phase fluid in a specific branched pipe is the flow velocity of all the solid-liquid mixed phase fluid before the division. A method of increasing the concentration of solid particles in a solid-liquid mixed-phase fluid by setting it to be larger than the average value of. 3. A solid-liquid mixed phase fluid is divided into a plurality of branched pipes at a midway portion, and the flow velocity of the solid-liquid mixed phase fluid in a specific branched pipe is the flow velocity of all the solid-liquid mixed phase fluid before dividing. By separating the solid particles from the solid-liquid mixed phase fluid in which the concentration of the solid particles is reduced in the specific pipe by a filter, the solid particles are separated by a filter, and other separated solid liquids in which the solid particles are not separated are separated. A method for separating solid particles from a solid-liquid mixed phase fluid, wherein the mixed phase fluid is circulated to the pipe side before branching again. 4. A Y-joint is adopted as a plurality of branched pipes.
And each method according to claim 3. 5. The magnitude relation of the flow velocities of the branched pipes, the opening degree of a valve provided in each branched pipe, the cross-sectional area of each branched pipe, the presence or absence of uneven shapes on the wall surface of each branched pipe, or the unevenness Or the difference in the angle of each branched pipe with respect to the direction of the pipe before branching, or a combination of some or all of them. And claim 3
Each method described. 6. The method according to claim 3, wherein the solid-liquid mixed phase fluid undergoes the step of being stored in a tank before being circulated through the pipe before branching.