BRPI0809102A2 - FILTERING DEVICE - Google Patents

Description

Report of the Invention Patent for "FILTERING DEVICE".

FIELD OF TECHNIQUE

The present invention relates to a filtering device which is adapted to be mounted on the suction part of a fuel pump.

BACKGROUND ART

Fuel in an automobile-mounted fuel tank or the like is delivered to the engine enclosure by a fuel pump and the fuel pump has a suction portion provided with a filtering device to filter the fuel in the fuel tank.

The filtering device is known to include a filtering means which is underside formed with a resin frame (Patent Document 1). However, it is very laborious to produce such conventional filters as the frame needs to be consolidated with the filter medium or formed in the insert molding filter medium.

Although a technique for consolidating multiple blades of point consolidation filtering or self-denominated dot consolidation filtering (Patent Document 2) is known, the entire filtering medium or the filtering medium in its innermost layer could be deformed. in a part corresponding to the suction part of a fuel pump by a suction force caused by the fuel pump provided that the point consolidated part has a small area. If such a problem occurs, a load is placed on the suction force generated by the fuel pump, which could have an adverse effect on fuel pump durability.

Patent Document 1: DE 3609905 A1 Patent Document 2: JP-A-2000-246026 DESCRIPTION OF THE INVENTION

OBJECTIVE TO BE ACHIEVED BY THE INVENTION

In consideration of the aforementioned problem, an object of the present invention is to provide a filtering device which is useful for increasing pump durability compared to conventional filtering devices.

MEANS OF ACHIEVING OBJECTIVE 5 According to a first aspect of the present invention, it is

provided a filtering device which is adapted to be mounted in a pump suction facility to suck a fluid to filter the fluid by using a filtering medium made of resin fibers; including a filter body including the bag-shaped filtering means and configured such that the fluid is flowable into an interior space; a suction part is formed in the filter body such that it is adapted to communicate with the interior space and the suction port; and a melt-solidified portion opposite the suction portion and formed of a molten portion of the filter means.

As long as the suction force by the pump has the highest value

In a position opposite the suction part in communication with the suction part of the pump, the filtering means bends towards the suction part in that position, and is attached to the suction part in some cases. From this point of view, the melt solidified part, which is formed of a molten part of the filter means, is disposed opposite the suction part of the filter medium in the first aspect of the present invention.

As long as the fluid is prevented from passing through the melt solidified part, the fluid is prevented from having a substantially straight flow directed from the position opposite the suction part to the suction port of the pump and the fluid flowing inwards. from the pump suction port, passing around the suction part.

Thus, the suction force by the pump is reduced in the opposite position to the suction part, which prevents the filtering medium from becoming deformed in that position. In this way, the filtering medium is prevented from being trapped against the suction part, which is useful for reducing pressure loss through the filtering medium and improving pump durability.

According to a second aspect of the present invention, the filtering medium is formed of several resin fiber blades, which are point-consolidated and the melt-solidified portion has an area greater than one point-consolidated portion in the filtering device.

In the second aspect of the present invention, various resin fiber blades are formed as the filtering means are point-consolidated to unify the resin fiber blades. Thus, a resin fiber blade, which is located on an inner side of the filter medium, is prevented from bending into the interior space. Additionally, the melt-solidified portion has an area greater than a consolidated portion per point.

When the areas of the point-consolidated parts and the melt-solidified part are increased, consequently, the filtering area of the filtering device is decreased. Since the point-consolidated parts are formed for the purpose of uniting the resin fiber blades, it is necessary that the area of each point-consolidated part is as small as possible with regard to the filtering area. On the other hand, once the melt solidified part is formed for the purpose of altering fluid flow or other purpose, it is necessary for the melt solidified part to have a certain level of area. From this point of view, the melt solidified part has an area larger than a consolidated part per point.

When the filter medium is formed of several resin fiber blades, it is possible to effectively remove impurities contained in the fluid according to the impurity diameters. When the filtering device is modified to have a different material combination, fiber diameter or the like, of the respective resin fiber blades according to the fluid to be treated, the filtering device may have a wide range of applications. .

According to a third aspect of the present invention, the melt-solidified portion extends radially around the said portion opposite the suction portion in the filter device.

In a third aspect of the present invention, since the melt-solidified portion has several linear portions mutually connected by extending the linear portions radially around the opposite portion to the suction portion, the filtering means has a greater resistance to stop being deformed compared to the first aspect of the present invention.

According to a fourth aspect of the present invention, the filtering device includes an edge around the suction part to thereby protect the interior space of the filter medium and at least a part of the melt solidified part overlaps an upper edge of the edge.

In the fourth aspect of the present invention, since an edge is disposed around the suction part to thereby protect the inner space of the filter medium and since at least a part of the melt solidified part overlaps an upper edge of the edge, The filtering device has a greater resistance against deformation as compared to a case where the melt solidified portion does not overlap the upper edge of the edge.

According to a fifth aspect of the present invention, the melt solidified portion is formed in a linear shape, a dot shape and an annular shape or a combination of at least two of these shapes in the filter device.

When the area of the melt solidified part is increased, the filtering area is consequently decreased. In a fifth aspect of the present invention, it is possible to provide the melt solidified portion with an effective shape to decrease pressure loss through the filtering medium to prevent the filtering medium from being deformed once the solidified portion by fusion is formed with a linear shape, a dotting shape and an annular shape or in a combination of at least two of these shapes.

EFFECTS OF THE INVENTION

According to the present invention constructed as described above, it is possible to increase the durability of a pump compared to the prior art.

BRIEF DESCRIPTION OF DRAWINGS

Figure 1 is a cross-sectional view of the entire structure of a fuel tank including the filtering device according to an embodiment of the present invention;

Figure 2 is a perspective view of the filtering device according to the embodiment;

Figures 3A and 3B are cross-sectional views of the filtering medium before melt solidification and the filtering medium after melt solidification, wherein the filtering medium forms the filtering device according to the embodiment;

Figures 4A and 4B are an enlarged plan view and an enlarged cross-sectional view showing the essential parts of the filtering device according to embodiment;

Figure 5 is a cross-sectional view showing the parts

elements of a filtering medium forming the filtering device according to the embodiment;

Fig. 6 is a cross-sectional view showing a comparison example for explaining the operation of a filtering device according to the embodiment;

Figures 7A and 7B are an enlarged plan view and an enlarged cross-sectional view showing a first modification of the filtering device according to the embodiment;

Figures 8A and 8B are an enlarged plan view and an enlarged cross-sectional view showing a second modification of the filtering device according to the embodiment; and

Figures 9A to D are plan views showing further modifications of the filtering device according to the present invention. BEST MODE FOR CARRYING OUT THE INVENTION Next, the filtering device according to one embodiment

of the present invention will be described.

As shown in Figure 1, a fuel tank 10 that is mounted on a vehicle includes a fuel pump 12 and the fuel pump 12 sucks a fuel into the fuel tank 10 to deliver the fuel to an engine compartment (not shown). The fuel pump 12 has a filtering device 14 disposed on a suction side therein to filter the fuel in the fuel tank 10.

As shown in Figure 2, the filtering device 14 is formed of a filtering means 16 and a resin frame 18 disposed on the filtering means 16, the filtering medium having a substantially rectangular shape as seen in a plan view and having melt-consolidated outer edges in a two-fold state such that it is formed into a pouch shape. The filtering means 16 may have different shapes depending on the shape of the fuel tank 10, the location where the fuel pump 12 is arranged or another factor.

As shown in figure 3A, filter means 16 is formed

16A, 16B, 16C and 16D resin fiber blades (four layers of structure in this embodiment) and each of the 16A, 16B and 16C resin fiber blades are made of a thermosetting resin nonwoven fabric . Resin fiber blades 16A, 16B and 16C have different fiber diameters, resulting in impurities contained in the fuel being effectively removed according to their diameters by their respective 16A, 16B and 16C resin fiber blades.

The 16D resin fiberboard, which is disposed on the outermost side, has a larger contour line than the 16A, 16B and 16C resin fiberboard so that opposite sides of the 16D resin fiberboard in a state Two-ply castings are certainly melt-consolidated by the fact that they are made from a highly thermofused resin such as polypropylene.

As shown in Figure 2 and Figure 4B, the frame 18 is formed of a substantially flat plate and is enclosed in the filtering medium.

The filtering means 16 has a hole 20 for receiving a tubular suction fitting 22 (described later) as a suction portion which may be formed in the frame 18.

The frame 18 has a plurality of openings 24 formed therein so that the fuel filtered through filter media 16 passes therethrough. The frame 18 has the suction fitting 22 formed therein to pass through it so that it communicates with a hole pump suction nozzle 12 (see figure 1). The fuel filtered by the filter medium 16 is drawn into the fuel pump 12 through the suction fitting 22.

Suction fitting 22 has a connecting member 28 coupled thereto so that it communicates with the fuel pump suction port 12. Suction fitting 22 has an annular fixing member formed on a base thereof so that has a larger diameter than the main body of the suction fitting 22. The connecting member 28 is formed of a fastening member 32 and a suction fitting 34, which have substantially the same diameters as the fastening member 30 and the fitting. of suction 22 respectively. When suction fitting 22 and suction fitting 34 are joined by, for example, melt consolidation, suction fitting 22 and suction fitting 34 communicate with each other so that fuel can flow through the suction fitting 22 and suction fitting 34.

Although suction fitting 22 and suction fitting 34 are joined by, for example, melt consolidation in the hole 20 formed in filter means 16, suction fitting 22 and suction fitting 34 are joined such that they have a Between the fixing member 30 and 25, the fixing member 32, and the fixing member 30 and the fixing member 32 hold a peripheral part of the hole in the filtering means 16, compressing the peripheral part of the hole.

The locking member 30 has an annular rib 36 formed on an inner side thereof (next to the locking member 32) so that it protrudes therefrom. When the securing member 30 and the securing member 32 engage the filtering means 16, the rib 36 cuts into the filtering means 16 to prevent the filtering means 16 from moving between the rib and the securing member 32.

Thus, the connecting member 28, the frame 18 and the filtering means 16 are unified such that they connect to the suction fitting 34 of the connecting member 28 for suction port of the fuel pump 12 as shown in figure 1. , performing the filtering device function 14.

It should be noted that the locking member 30 has a plurality (three in the embodiment shown) of arcuate ribs 38 formed at 120 degree intervals along a simple imaginary circle on an outer side thereof (spaced from the locking member 32). so that it projects from it as shown in figures 4A and 4B. Arched ribs 38 are preferably formed on a part of the fastener 30 near an outer edge of the fastener 30 as serving as a flow resistance for the fuel flow within the fittings.

suction shafts 22 and 34.

The frame 18 includes beams 40, each having a reinforcement rib 42 formed therein so that they project along it in the same direction as the arcuate ribs 38 and have substantially the same projection length as the arcuate ribs 38. Reinforcing ribs 42 are formed into longer beams 40, beam crossings 40 and other positions reinforcing frame 18 and employing reinforcing ribs 42 and arcuate ribs 38 to ensure an interior space 44 in filter means 16 so that fuel flows into the interior space 44.

In this way the filter medium 16 is formed of several blades

16A, 16B, 16C and 16D resin fibers as shown in FIG. 3A, the filtering medium has melt-consolidated portions 46 formed at certain intervals therein (see FIG. 3B) so as to unify the resin fiber blades 16A, 16B, 16C and 16D. Thus, the resin fiber blade 16A 30 and another blade, which is located on an inner side of the filter medium, are prevented from bending towards the inner side of the interior space 44. On the other hand, as shown in figure 4A , the filtering medium

16 includes a Y-shaped fusion solidified portion 48 opposite the suction fitting 22 so that it extends the geometrical axis of the suction fitting 22 outwardly to unify resin fiber blades 5 16A, 16B, 16C and 16D Thus, the resin fiber blade 16A and another blade, which is located on an inner side of the filter means 16, are prevented from bending towards the inner side of the interior space 44. fusion solidified 48 has respective outwardly extending portions overlapping the upper ends of the respective arched ribs 38 so that they extend between the three arched ribs 38 in the form of a bridge.

The point-consolidated portions 46 and the melt-solidified portion 48 are formed before the filter medium 16 which has a substantially rectangular shape folds into a two-fold state. The filter medium 16 may be melt-consolidated by, for example, an ultrasonic welder (not shown).

Point-consolidated portions 46 and melt-solidified portion 48 may be formed by heat sealing using a heater rather than ultrasonic welding. The melt solidified portion 48 may be formed by placing a hot plate (not shown) in contact with the filter medium 16, the hot plate receives conductive heating from the heater. The hot plate includes a Y-shaped projection to form the melt solidified part 48.

As other measures, the melt solidified portion 48 and the like 25 may be formed by heat sealing using a laser. In this case, the laser includes a laser head (not shown) arranged so that it is movable in parallel with the filter means 16 or a pattern for placing the filter means 16 arranged thereon so that it is horizontally movable from a such that the laser beam is applied to the portions of the filtering medium where the dot-consolidated portions 46 and the melt-solidified portion 48 are formed. The filter medium 16 may be melt-induced, hot air or the like to heat the desired portions of the filter medium 16.

Now, explanation will be made about the function of the filtering device according to the embodiment of the present invention.

As shown in FIGS. 4A and B of this embodiment, the Y-shaped fusion solidified part 5 is formed opposite the suction fitting 22 in communication with the suction port of the fuel pump 12 (see FIG. 1). extending between the three arched ribs 38 in the form of a bridge, the arcuate ribs protrude from the securing member 30.

The suction force by fuel pump 12 has the value

as opposed to the suction portion of the fuel pump 12 in the filter media 16. As a result, the filter media 16 flexes toward the suction fitting 22, in some cases, unless some action is taken it may become attached to the suction fitting 22 as shown in figure 6.

In this embodiment, as long as melt solidified part 48 is formed opposite the suction fitting 22 to prevent fuel from passing through melt solidified part 48, the fuel is prevented from having a substantially straight flow (see figure 6). from the opposite position 20 of the suction fitting 22 to the suction portion of the fuel pump 12 and the fuel flows into the suction port of the fuel pump 12 passing along the suction fitting 22 (see figure 4B).

Thus, the filter means 16 is prevented from being deformed from the position opposite the suction fitting 22. Accordingly, the filtering means is prevented from being trapped against the suction fitting 22, which is useful for reducing pressure loss through the filter media 16 and increase the life of the fuel pump 12.

The melt solidified part 48 is formed in a Y-shape and extends radially around a part thereof opposite the suction fitting 22 to connect various linear parts together, increasing the strength of the melt solidified part in the medium. filtration 16. The melt-solidified portion 48 has respective outwardly extending portions overlapping the upper ends of the respective arcuate ribs 38 protruding from the clamping member 30 and extending between the arcuate ribs 38 in the form of a bridge. , which further increases the strength of the melt-solidified portion of filter means 16 to prevent filter means 16 from being deformed.

Instead of the Y-shaped melt-solidified portion, a dot-shaped melt-solidified portion 66, which has a wider diameter than the point-consolidated portion 46, may be formed at a position of the filter medium, which is opposite to the suction fitting 10 22 as shown in figures 7A and B. It is possible to increase the strength of the filter medium 16 compared to a case where no melt solidified part 66 is formed.

As long as the suction force by the fuel pump 12 has a very high value in a position opposite the suction fitting 22 15 in communication with the suction part of the fuel pump 12, the melt solidified part supply 66 in this position can preventing the filter medium 16 from being deformed compared to a case where no melt solidified part 66 is formed.

If the areas of point-consolidated portions 46 and the melt-solidified portion 66 are increased, the filtering area of the filtering device 14 is consequently decreased. Taking into account the filtering area, the point-consolidated portion area 46 is preferably the smallest possible because it is formed for the purpose of unifying the resin fiber blades 16A, 16B, 16C and 16D. On the other hand, it is necessary for the melt solidified part 66 to have a certain level of area because it is formed for the purpose of changing the flow of a fluid or the like. In this view, it is preferable that the melt solidified part 66 has an area larger than a consolidated point 46 part.

As shown in FIGS. 8A and B, linear fusion-soluble portions 68 may be formed radially in the filtering means such that they mount at the upper ends of the three arcuate ribs 38 of the securing member 30, respectively. By forming the melt-solidified portions 68 such that they mount at the upper ends of the arcuate ribs 38, it is possible to increase the strength of the portions of the filtering means 16 which are located at the upper ends of the arcuate ribs 38 and their vicinity. Thus, it is possible that the filter medium 16 is deformed compared to a case where no melt solidified portions 68 are formed.

The present invention is not limited to having the melt solidified part 48 or linear melt solidified parts 68. As shown in Figure 9A, the filter means may have an annular melt solidified part 70 formed therein. In such a case, the annular fusion solidified portion is configured to overlap the upper ends of the respective arcuate ribs 38.

As shown in Fig. 9B, the filtering means may have a melt solidified portion 75 formed therein so that it is formed of two inner ring annular portions 72 and an outer ring 74. Although the arcuate ribs 38 are disposed between the ring 72 and the outer ring 74 in this figure, one between the inner ring 72 and the outer ring 74 may be arranged to overlap the upper ends of the arcuate ribs 38, or both rings between the inner ring 72 and the outer ring 74 20 may be formed so as to overlap the upper ends of the arcuate ribs 38.

The melt solidified portion may be arranged so that it is formed of several crossed linear portions. In the case where the melt solidified part is formed from a melt solidified part 76 is formed into a transverse shape as shown in Fig. 9C, if the intersection of two linear parts of the melt solidified part 76 agrees with the geometric axis of the socket suction 22, only one of the arcuate ribs 38 has a linear portion mounted thereon.

For this reason, the crossing position of the linear portions may be modified such that the respective linear portions are mounted on the upper ends of the arcuate ribs 38, respectively, or the arcuate ribs 38 may be arranged at 90 degree intervals such that respective linear parts are mounted on the arcuate ribs 38 respectively. When the respective linear parts are mounted on their respective arcuate ribs 38, more effectively preventing the filtering means 16 from deforming.

5 Instead of the fusion solidified part including linear parts

or a continuous ring, the filter means may have a plurality of melt-soluble parts 78 in a dotting format as shown in Figure 9D. Although the fusion solidified part is formed with a linear shape, a punctuation shape and an annular shape 10 in these figures, the fusion solidified part can be formed into a combination of at least two such shapes. Thus, the melt solidified portion is configured such that it reduces pressure loss along the filtering means 16 to effectively prevent the filtering means 16 from being deformed.

Although the explanation of this modality was made around

In one case where the filter device 14 filters a fuel, the fluid to be filtered is not limited to a fuel. Resin fibers 16A, 16B, 16C and 16D forming a filter medium 16 may have different materials and different fiber diameters according to the type of fluid to be filtered.

Although the rectangular shaped filter media 16 is folded into a double-fold state and is formed into a fusion-consolidation pouch at the outer edge in this embodiment, it is not necessary that the filter medium be always folded in a folded state. 25 double. An upper filter media panel and a lower filter media panel, which are prepared respectively, are combined into a pocket shape by overlapping the outer edges of both panels and by melt consolidation of the outer edges.

The entire description of Japanese Patent Application No. 2007-076831 filed March 23, 2007 which includes a descriptive report, claims, drawings and summary is incorporated herein by reference.

Claims (5)

1. Filtration device adapted to be mounted in a suction port of a pump to suck a fluid for the purpose of filtering the fluid using a filter media (16) made from resin fiber (16A, 16B, 16C, 16D), characterized in that it comprises: a filter body including a filter medium (16) in a pocket shape and configured such that the fluid is flowable into an interior space (44) ; a suction portion formed in the filter body to be adapted to communicate with the interior space and the suction port; and a melt-solidified portion opposite the suction port and formed of a molten portion of the filter medium (16). Filtering device according to Claim 1, characterized in that the filtering medium (16) is formed by several resin fiber blades (16A, 16B, 16C, 16D) which are connected to each other. The melt-solidified portion has a larger area than the bonded portion (46). Filtering device according to Claim 1 or 2, characterized in that the melt-solidified portion extends radially around a portion thereof opposite the suction portion. Filtering device according to any one of claims 1 to 3, characterized in that it further comprises an edge around the suction portion to ensure the interior space (44) in the filtering medium (16). ), and at least a portion of the melt solidified portion overlaps an upper edge of the edge. Filtration device according to any one of claims 1 to 4, characterized in that the melt-solidified portion is formed of one of linear shape (68), dot shape and an annular shape (70) or by a combination of at least two of these formats.