KR20130084450A - Oil strainer equipped revolution filter - Google Patents

Abstract

PURPOSE: An oil strainer with a rotational filter element is provided to reduce intake load of a fluid flow and to implement a high efficient filtering performance by the rotation of a rotational filter element according to the flow of a working fluid. CONSTITUTION: An oil strainer with a rotational filter element includes a cap (1), a rotational filter element (2), and a case (3). The cap has an entrance and an exit on the upper part, and a rotation support shaft (14) integrally in the center of the lower part. The rotational filter element is rotatably connected to the rotation support shaft. The case is combined with the cap while covering the rotational filter element. The rotational filter element has a plurality of holes on the circumferential surface, a hollow inside, and an opening on the upper part; and is integrally formed with a rotation guide unit (20) which generates rotatory power by using the flow of a fluid in the opening.

Description

Oil strainer equipped revolution filter

The present invention relates to an oil strainer installed on a hydraulic line to remove solid foreign matter contained in a fluid, and in particular, a filter medium functioning as a filter to filter solid foreign matter is rotatably mounted inside the apparatus. The present invention relates to an oil strainer having a rotary filter, which can significantly reduce the amount of foreign matter accumulated on the surface of the filter medium.

The working fluid (oil), which functions as a fluid for operating the hydraulic equipment in the hydraulic system, contains a large number of solid foreign objects. If these foreign materials are used without filtering, the flow path inside the pipe or equipment through which the working fluid flows may be blocked, and further operation or operation may be impossible. Therefore, a means for filtering out foreign matters is always required.

Filtration to foreign substances can be achieved through mechanical, chemical, biological methods, and the like. If the required degree of filtration is low, only simple mechanical filtration may be used. A representative example of such a mechanical filtration device is a strainer. This can be said to be a kind of strainer that filters out the foreign matter contained in the working fluid (oil) through a hole smaller than the minimum size of the foreign matter to be filtered.

Such a strainer is generally installed in the form of a bucket or a cone in the middle of the pipe. In this case, valves are installed at the front and rear ends of the strainer. Therefore, if the strainer needs to be repaired, the valves installed at the front and rear ends of the strainer are locked, and the flow of the working fluid is interrupted. The repair is carried out by replacing it.

The cleaning or replacement cycle of the strainer is closely related to the density indicating how densely arranged the holes formed in the filter medium serving as the filter are arranged. Density is an important factor that affects suction load. If the density is fine, it is possible to filter out fine foreign matters, but on the other hand, the suction load increases, which can lead to a decrease in performance. Although it decreases, there is a problem of not functioning properly as a filter medium.

Moreover, if exposed to the harsh environment where a lot of foreign material is introduced, the cleaning or replacement cycle of the strainer may be shorter. If the presenter is not cleaned or replaced, the performance and lifespan of the system is greatly reduced. However, if the cleaning or replacement cycle of the filter is shortened, there is a problem in that the maintenance and repair of the device is much more difficult and more expensive.

The technical problem to be solved by the present invention is to provide an oil strainer that has a high efficiency of filtration performance while reducing the suction load, the foreign matter accumulated on the surface of the filter medium is significantly reduced to increase the cleaning or replacement cycle.

The present invention as a means for solving the problem, the cap having an inlet and an outlet at the top and having a rotation support shaft integrally in the lower center; Rotating filter body rotatably coupled to the rotation support shaft of the cap; A case coupled to the cap while covering the rotary filter, wherein the rotary filter is a hollow cylinder having a myriad of holes in the circumferential surface and opened at an upper portion thereof, using a fluid flow in the opening. It provides an oil strainer having a rotary filter, characterized in that the rotary guide portion for generating a rotational force is formed integrally.

Here, the outlet is formed in the center of the cap, the inlet may be formed in the tangential direction in which the rotary filter is rotated on the cap side.

In addition, the case may be configured to be transparent to see the inside or to form a light-transmitting window in place so that the amount of solids filtered by the rotary filter can be directly identified with the naked eye.

In addition, in order to minimize resistance when the rotary filter rotates, holes formed in the circumferential surface of the rotary filter may be formed in an array forming a predetermined pattern in an oblique direction along the rotation direction of the rotary filter.

The rotation induction part may have a shaft hole coupled to the rotation support shaft at a center thereof, and the rotation blades may be arranged in an arc shape at a predetermined interval around the shaft hole.

According to the oil strainer according to the embodiment of the present invention, the filter medium serving as a filter is rapidly rotated in one direction by the flow of the working fluid by the suction pressure of the pump, so that the foreign matter to be filtered included in the working fluid It can be gathered to the bottom of the case outside without being stuck in the hole or caught in the hole. Accordingly, the flow resistance of the fluid passing through the filter medium is reduced and the suction load can be reduced.

In other words, due to the rotation of the rotary filter according to the working fluid flow, it is possible to expect a high efficiency of filtration performance while reducing the suction load on the fluid flow. In addition, when the suction load is reduced, the life and efficiency of the overall hydraulic system can be improved, and the amount of foreign matter accumulated on the surface of the filter medium is significantly reduced, and the cleaning or replacement cycle of the device can be greatly increased, thereby making it easy to maintain and repair. The effect of increase and cost reduction is manifested.

1 is an exploded perspective view of an oil strainer according to an embodiment of the present invention.
2 is a perspective view of the oil strainer according to FIG.
3 is a plan view of the oil strainer shown in FIG.
4 is a transverse cross-sectional view of the oil strainer shown in FIG. 2.
5 is a view showing an operating state of the oil strainer according to the embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the present invention, a detailed description of known configurations will be omitted, and a detailed description of configurations that may unnecessarily obscure the gist of the present invention will be omitted.

1 is an exploded perspective view of an oil strainer according to an embodiment of the present invention, Figure 2 is a combined perspective view of the oil strainer according to FIG. 3 is a plan view of the oil strainer shown in FIG. 2, and FIG. 4 is a cross-sectional view of the oil strainer shown in FIG. 2.

1 to 4, the oil strainer according to the present embodiment is largely a cap (1) having two conduits (10) 12 connected to the conduit through which the working fluid flows, and the cap (1). It consists of a hollow case (3) for coupling with the rotary filter (2) rotatably mounted in the case (3). At this time, one of the two conduits (10, 12) formed in the cap (1) is the inlet for introducing the working fluid and the other is the outlet through which the working fluid from which foreign matter is removed.

In the lower center of the cap (1), the rotary support shaft (14) to which the rotary filter (2) is rotatably coupled is formed integrally. In this case, the rotary support shaft 14 may be provided with a snap ring 140 so that the rotary filter 2 coupled thereto is not artificially separated and separated in the process of rotating by the fluid. ), Means for assisting the smooth rotation of the rotary filter 2, for example, a needle pin 144 may be provided.

The conduit 12, which forms the outlet of the two conduits 10, 12, is in communication with the central portion of the cap 1, the other forming an inlet such that the working fluid can be introduced into the strainer while forming a spiral flow. One conduit 10 may be in tangential direction in which the rotary filter 2 rotates on the side of the cap 1. In this case, a connector (not shown) for connection with the main pipe through which the working fluid flows may be connected to the end of each conduit 10, 12 by a tube fitting method.

The rotary filter 2 functions as a filter for filtering foreign matter contained in the working fluid. The rotary filter 2 is rotatably coupled to the rotation support shaft 14 of the cap 1 to filter foreign matter contained in the working fluid while rotating in one direction in the case 3. The rotary filter 2 is preferably a hollow cylinder having a myriad of holes in its circumferential surface and opened at an upper portion thereof, and may have a configuration in which a rotation induction part 20 for generating rotational force by using a fluid flow is formed in the opening. .

The hole formed in the circumferential surface of the rotary filter 2 can be formed with a diameter and density enough to allow the working fluid to pass smoothly and to filter out foreign matters. Although not shown, formed in an array forming a predetermined pattern in an oblique direction along the rotational direction of the rotary filter 2 to minimize the fluid resistance when the rotary filter 2 is rotated. Can be.

Rotation guide portion 20, as shown in the figure, is formed in the shaft hole 200 in the center so as to be smoothly rotated to be inserted into the rotation support shaft 14, over a predetermined interval around the shaft hole 200 The rotary blades 202 may be configured in a circular arc configuration, that is, one impeller structure. In this case, the space formed between each of the rotary blades 202 is a passage 204 through which the clean working fluid filtered out of the foreign matter passes, and the passage 204 communicates with the conduit 12 forming the outlet.

In addition to the above structure, the rotation induction part 20 is not shown, but a plurality of passages 204 can obtain a rotational force from the flow of the working fluid even when the spiral structure from the bottom to the center around the hole 200. Therefore, the rotation induction part 20 is not limited to the illustrated example, and it turns out that any applicable structure can be applied as long as the rotational force can be generated through the flow in the forced flow of the working fluid at the suction pressure of the pump.

On the other hand, the case 3 is coupled to the cap (1) while covering the rotary filter 2, thereby forming a space in which the working fluid before filtration between the rotary filter (2) can stay. That is, the working fluid filled in the space formed between the case 3 and the rotary filter 2 by the case 3 is coupled to the working fluid including foreign matter introduced through the conduits 10 and 12 forming the inlet. The working fluid present in the space inside the rotary filter 2 is a clean working fluid in which foreign substances are filtered while passing through the rotary filter 2.

When the rotary filter 2 rotates due to the flow of the working fluid, foreign substances filtered out by the influence of the centrifugal force accumulate on the surface of the rotary filter 2 and accumulate on the bottom side of the outer case 3 without being caught in the hole. . Therefore, the case 3 is transparent so that the amount of solid foreign matter precipitated by the rotary filter 2 can be directly checked by the naked eye and the cleaning timing can be determined. It can be a configuration.

The foreign matter filtration process performed by the oil strainer according to the present invention having the above configuration will be briefly described in connection with the operation and effect of the present invention.

5 is a view showing an operating state of the oil strainer according to an embodiment of the present invention.

Referring to FIG. 5, the working fluid including solid foreign matter is introduced into the space between the case 3 and the rotary filter 2 through the conduits 10 and 12 forming the inlet. The suction pressure of the pump acts from the side of the conduit 12 which forms the outlet, and the conduit 12 which forms the outlet communicates with the inner space of the rotary filter 2. The working fluid introduced into the space between the case 3 and the rotary filter 2 thus exits the device through the outlet via the hole and the inner space of the rotary filter 2.

The rotary induction part 20 formed on the upper opening side of the rotary filter 2 obtains a rotational force from the flow of the working fluid as described above, and thus the rotary filter 2 rotates quickly in one direction. The rapid rotation of the rotary filter (2) causes the working fluid to generate centrifugal flow along the direction of rotation, so that the solid foreign matter that has not passed through the holes of the rotary filter (2) is filtered out and the surface of the rotary filter (2). It is piled up by moving spirally to the bottom side of the case 3 without being stuck in or stuck in a hole.

If the solid foreign matter that is the filtration object is not accumulated in the surface of the rotary filter 2 or stuck in the hole as described above, the working fluid can pass while maintaining a constant pressure and speed in passing through the filter medium. In other words, compared with the conventional general strainer configuration in which foreign matter is continuously accumulated in the filter medium, the flow resistance and the suction load of the fluid are reduced, so that the overall driving efficiency of the hydraulic system can be improved.

In the foregoing detailed description of the present invention, only specific embodiments thereof have been described. It is to be understood, however, that the invention is not to be limited to the specific forms thereof, which are to be considered as being limited to the specific embodiments, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

1: cap 2: rotary filter
3: Case
10: conduit (entrance) 12: conduit (outlet)
14: rotation support shaft 20: rotation guide portion
200: shaft ball 202: rotary wing
204: passage

Claims (5)

A cap having an inlet and an outlet at the top and having a rotation support shaft integrally at the bottom center thereof;
Rotating filter body rotatably coupled to the rotation support shaft of the cap;
And a case coupled to the cap while covering the rotary filter body.
The rotary filter is,
An oil strainer having a rotary filter, characterized in that the hollow cylinder having a myriad of holes in the circumferential surface and the upper portion thereof is opened, and the rotation guide portion is formed integrally with the opening to generate rotational force by using a fluid flow.
The method of claim 1,
And the outlet is formed at the center of the cap, and the inlet is formed in a tangential direction in which the rotary filter is rotated on the cap side.
The method of claim 1,
The case is transparent, the oil strainer having a rotary filter, characterized in that the internal view or a transparent window formed in place.
The method of claim 1,
The hole formed in the circumferential surface of the rotary filter body is an oil strainer having a rotary filter, characterized in that formed in an array forming a predetermined pattern in an oblique direction along the rotation direction of the rotary filter.
The method of claim 1,
The rotation guide portion has a shaft hole coupled to the rotating support shaft in the center, the oil strainer having a rotary filter characterized in that the rotary blades are arranged in an arc shape at a predetermined interval around the shaft hole.

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