KR101407448B1 - Filter assembly - Google Patents

Abstract

The present invention discloses a filter assembly capable of reducing the thickness of the filter housing and the weight of the filter assembly. A filter assembly according to the present invention includes: a filter housing having a hollow formed therein and having a fusion rib formed along one side edge; A filter member disposed inside the filter housing to filter water flowing into the filter housing; And a housing cap having a fused groove formed to be fitted into the fused rib of the filter housing, wherein one end of the housing cap is inserted into the filter housing while one outer peripheral surface of the filter housing is in contact with the fused rib, A guide portion can be formed.

Description

Filter assembly {FILTER ASSEMBLY}

The present invention relates to a filter assembly.

Generally, the water treatment apparatus is a device that filters heavy metals or foreign substances contained in water. The water treatment apparatus includes a water purifier, a bidet, a humidifier, a dishwasher, and a refrigerator having a water purification function.

The water treatment apparatus may be provided with one or more filter assemblies for filtering water. The filter assembly may fuse the housing cap to the filter housing with the filter member inserted into the filter housing. At this time, the filter housing and the housing cap are separately manufactured by a mold and then fused.

A fused groove is formed at one side of the filter housing and a fused rib is formed at a rim of the housing cap so as to be inserted into the fused groove. When the housing cap is mounted on one side of the filter housing, the fusion rib of the housing cap corresponds to the fusion groove of the filter housing. When the housing cap is rotated, the fusion rib and the fusion groove are rubbed together, and the fusion rib and the fusion groove are fusion-bonded.

However, in the conventional filter assembly, a fusion groove is formed on one side of the filter housing so that the filter housing can be detached from the mold. Therefore, the filter housing has to be formed to have the same thickness as the whole mold structure. At this time, the filter housing must have a minimum thickness for forming the fusion grooves and the surrounding structures (ribs) on both sides of the fusion grooves, so that the thickness of the filter housing as a whole becomes thick. Furthermore, as the thickness of the filter housing is increased, the weight, manufacturing cost, and cost of the filter assembly are significantly increased.

In addition, when the housing cap is mounted on the filter housing, there is a case where the fusion rib is not inserted into a normal position of the fusion groove when an external impact is applied. In this case, since the housing cap is abnormally fused to the filter housing, fusion failure may occur. In addition, when the housing cap is supported by a jig on one side of the filter housing, incomplete fusion bonding can be caused by the tolerance of the jig.

Further, it is difficult to confirm whether the fusion of the filter housing and the housing cap is normally performed. Therefore, when the filter assembly is finely welded or defective, a separate test is performed to determine whether or not the filter assembly is defective, so that the productivity is lowered and additional equipment is required.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the problems described above and to provide a filter assembly capable of improving the productivity and reducing the thickness and weight of the filter housing through a new fused portion design.

It is another object of the present invention to provide a filter assembly in which defective fusion can be minimized even when an external impact or a jig tolerance is generated during a welding process.

It is still another object of the present invention to provide a filter assembly that enables confirmation of defective welding of a filter assembly during a manufacturing process.

According to an aspect of the present invention, there is provided a filter assembly comprising: a filter housing having a cavity formed therein and having a fusion rib formed along one side thereof; A filter member disposed inside the filter housing to filter water flowing into the filter housing; And a housing cap having a fused groove formed to be fitted into the fused rib of the filter housing, wherein one end of the housing cap is inserted into the filter housing while one outer peripheral surface of the filter housing is in contact with the fused rib, A guide portion can be formed.

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The outer surface of the filter housing may be formed with a fusing depth confirming portion corresponding to an end of the guide portion when the housing cap and the filter housing are normally fused.

The distance between the end of the filter housing and the fusing depth verifying portion may be longer than the distance between the fusing groove entrance of the filter housing cap and the end of the guide portion.

The fusing depth verifying unit may be formed in a circular shape along the circumferential direction of the filter housing.

According to the present invention, the thickness and weight of the filter housing can be reduced.

According to the present invention, even if an external impact or a jig tolerance occurs during the fusing process, defective fusion can be minimized.

According to the present invention, not only the production of the filter housing but also the productivity of the filter assembly and production process can be shortened.

According to the present invention, it is possible to confirm whether the fusion of the filter assembly is poor or not during the manufacturing process.

1 is a perspective view showing a filter assembly according to the present invention.
2 is an exploded cross-sectional view of the filter assembly of FIG.
FIG. 3 is an exploded cross-sectional view showing a fusion structure of the filter housing and the housing cap of FIG. 2;
FIG. 4 is a cross-sectional view illustrating a state where one end of the filter housing of FIG. 2 is inserted into the guide portion of the housing cap.
FIG. 5 is a cross-sectional view illustrating a state in which the housing cap is mounted on the filter housing before the filter housing and the housing cap of FIG. 2 are fused.
FIG. 6 is a cross-sectional view illustrating a state where the housing cap is fused to the filter housing of FIG. 2. FIG.

In order to accomplish the above object, a filter assembly according to the present invention will be described.

FIG. 1 is a perspective view showing a filter assembly according to the present invention, and FIG. 2 is an exploded sectional view showing a filter assembly.

Referring to FIGS. 1 and 2, the filter assembly 100 includes a filter housing 110, a filter member 120, and a housing cap 130.

A hollow is formed in the filter housing 110. The inflow-side housing cap part 111 may be integrally formed on the inflow side of the filter housing 110. The filter housing 110 may be formed in a cylindrical shape.

The inflow-side housing cap part 111 may be formed with an inflow tube part 112 so as to be connected to a purified water pipe (not shown). In addition, a plurality of support ribs (not shown) may be radially formed in the inflow-side housing cap portion 111. Therefore, it has a structure in which water can pass through the support ribs.

The filter member 120 is detachably disposed inside the filter housing 110. At this time, the inlet side cover 121 is coupled to the water inlet side end of the filter member 120, and the discharge side cover 125 is coupled to the water discharge side end of the filter member 120.

A housing cap 130 is disposed at one end of the filter housing 110. A discharge tube 131 may be formed at the center of the housing cap 130 so as to be coupled to a discharge side purified water pipe (not shown).

The filter housing 110 and the housing cap 130 may be made of various synthetic resins such as polypropylene.

3 is an exploded cross-sectional view showing a fusion structure of the filter housing and the housing cap.

Referring to FIG. 3, at one end of the filter housing 110, a fusion rib 115 may be formed along the rim. At this time, the cross-section of the fusion rib 115 has a wedge shape in which the inner side surface and the outer side surface are tapered. The fused ribs 115 may have a circular ring shape as a whole.

In this manner, the filter housing 110 can be formed to have a thinner thickness than the filter housing 110 without forming the fusion grooves 135 and the peripheral structure of the fusion grooves 135 (ribs formed on both sides of the fusion grooves) Since only the welding ribs 115 are formed, the overall thickness of the filter housing 110 can be made relatively thin. The thickness of the filter housing 110 can be reduced by about 30 to 50% compared with the conventional one by forming the fusion ribs 115 in the filter housing 110 as in the present invention.

Both side surfaces of the fusion rib 115 may be formed to be tapered. The fused ribs 115 may have a wedge shape that becomes thinner toward the end.

A fused groove 135 may be formed in the housing cap 130 so as to fit into the fusing rib 115 of the filter housing 110 along the rim. At this time, the fused grooves 135 may have a circular ring shape as a whole.

The fused grooves 135 are formed to be smaller than the fused ribs 115. As the housing cap 130 is rotated, both sides of the fusing rib 115 are fused to both sides of the fusing groove 135, so that the fusing rib 115 is fused to the fusing groove 135. At this time, the housing cap 130 is inserted into the filter housing 110 by a predetermined distance (hereinafter referred to as " fusion depth ") as much as the fusion rib 115 melts when fused.

Both sides of the fused groove 135 may be tapered. Both side surfaces of the fused groove 135 are tapered so that they can be widened toward the entrance. At this time, a portion near the inlet of the fused groove 135 may be rounded so that the fused rib 115 is smoothly guided to the fused groove 135.

When the housing cap 130 is lifted by the jig to one end of the filter housing 110, the fusing ribs 115 are slid along one side or both sides of the fused groove 135, (130) is positioned at the correct rotational position.

Also, when the tolerance of the jig is slightly generated, the housing cap 130 may be positioned slightly on the filter housing 110 so that the rotation center of the housing cap 130 may not match. However, according to the present invention, since the fusing ribs 115 of the filter housing 110 slip down on one side or both sides of the fused groove 135, the rotation center of the housing cap 130 is appropriately corrected .

Since both side surfaces of the welding groove 135 are tapered and both side surfaces of the welding rib 115 are tapered, even if the housing cap 130 is inserted in a slightly inclined state, And the welding ribs 115 are tapered, the correction range can be further enlarged.

A guide portion 137 may be formed at one end of the housing cap 130 so that the outer circumferential surface of the filter housing 110 can be inserted while being in contact with the outer circumferential surface of the filter housing 110. The guide portion 137 may be formed in a cylindrical shape.

The guide part 137 is formed so that when the fusing rib 115 of the filter housing 110 is fitted into the fused groove 135, the housing cap 130 is fitted in parallel with the longitudinal direction of the filter housing 110 do. Furthermore, it is possible to prevent a tolerance from being generated when the fusing ribs 115 are fitted into the fusing grooves 135.

A fusing depth verifying part 117 is formed on an outer surface of the filter housing 110 so as to correspond to an end of the guide part 137 when the housing cap 130 and the filter housing 110 are normally fused .

The distance L1 between the end of the filter housing 110 and the fusing depth verifying portion 117 is a distance between the inlet of the fusing groove 135 of the housing cap 130 and the end of the guide portion 137 May be longer than the distance L2 by the fused depth (L1 > L2).

Therefore, it can be confirmed whether or not fusion bonding is normal by confirming whether or not the fusing depth verifying part 117 corresponds to the end of the guide part 137.

The fusing depth verification unit 117 is formed along the circumferential direction of the filter housing 110. The fusing depth detection unit 117 may be formed in a circular shape. When the housing cap 130 is completely fused to the filter housing 110, the filter housing 110 is rotated to check whether the filter housing 110 and the housing cap 130 are fused to each other by a normal fusing depth. .

The fusing process of the filter assembly according to the present invention will be described.

4 is a sectional view showing a state in which one end of the filter housing is inserted into the guide portion of the housing cap.

Referring to FIG. 4, after the filter member 120 is inserted into the filter housing 110, the filter housing 110 is jigged. The housing cap 130 is mounted on one end of the filter housing 110 by a jig.

The guide part 137 of the housing cap is inserted into the filter housing 110 while being in contact with the outer circumferential surface of the filter housing 110. At this time, the housing cap 130 can be inserted along the direction substantially parallel to the longitudinal direction of the filter housing 110 without being shaken by the guide portion 137.

5 is a cross-sectional view showing a state in which the housing cap is put on the filter housing before the filter housing and the housing cap are fused.

5, when the housing cap 130 is further inserted into one end of the filter housing 110, the fusing rib 115 of the filter housing 110 is inserted into the fused groove of the housing cap 130 135). The fusing ribs 115 of the filter housing 110 are formed in the fused grooves 135 of the housing cap 130 because both sides of the fusing ribs 115 and the side faces of the fused grooves 135 are tapered. As shown in Fig. Therefore, even if an external impact is applied to the filter housing 110 and the housing cap 130 or a tolerance is generated, the fusion rib 115 and the fusion groove 135 can be accurately fitted.

When the housing cap 130 is rotated with respect to the rotation center, the fusing ribs 115 of the housing cap 130 rub against both sides of the fusing groove 135. At this time, since the fusing ribs 115 are formed thicker than the fusing grooves 135, both side surfaces of the fusing ribs 115 are rubbed against both side surfaces of the fusing grooves 135.

6 is a cross-sectional view showing a state in which a housing cap is fused to a filter housing.

Referring to FIG. 6, the housing cap 130 is continuously rotated to generate molten material on the friction surfaces of the fusing ribs 115 and the fused grooves 135 by frictional heat. At this time, the fusing ribs 115 are melted by frictional heat and become smaller.

As the fusion rib 115 melts, the housing cap 130 enters the filter housing 110 side. At this time, the friction surface of the fusion rib 115 and the fusion groove 135 generates more molten material.

Then, if it is determined that the preset welding time has been reached, the jig stops the housing cap 130.

When the housing cap 130 is stopped, both sides of the fusing rib 115 and both side faces of the fused groove 135 are fused by the molten material. At this time, since the fused rib 115 has two fused areas, the fusing time can be shortened as compared with the structure in which the fused ribs 115 are fused three-dimensionally (fused to both sides and end faces). Here, the fused portions of the fused ribs 115 and the fused grooves 135 are shown by the drawing number 138.

When the fusion of the filter assembly 100 is completed, it is possible to confirm whether the end of the guide part 137 corresponds to the fusing depth verifying part 117.

At this time, if the end of the guide part 137 corresponds to the fusing depth verifying part 117 as a whole, it is determined that the filter assembly 100 is normally fused.

On the other hand, if the end of the guide part 137 does not correspond to the fusing depth verifying part 117 or does not correspond at all, it is determined that the filter assembly 100 is not normally fused.

As described above, it is possible to determine whether the filter assembly 100 is defective according to whether the guide portion 137 corresponds to the fusing depth verifying portion 117 or not.

INDUSTRIAL APPLICABILITY The present invention has remarkable industrial applicability because it can reduce the thickness and weight of the filter housing and confirm beforehand whether the fusion of the filter assembly is defective or not.

100: filter assembly 110: filter housing
115: Fusing rib 117: Fusing depth checking part
120: filter member 130: housing cap
135: welding groove 137: guide portion

Claims (5)

A filter housing in which a hollow is formed and a fusion rib is formed along one side edge;
A filter member disposed inside the filter housing to filter water flowing into the filter housing; And
And a housing cap in which a fused groove is formed so as to be fitted to a fusing rib of the filter housing,
Wherein a guide portion is formed at one end of the housing cap to prevent a tolerance from being generated when the outer circumferential surface of the filter housing is in contact with the outer circumferential surface of the filter housing and the fusion rib is inserted into the fusion groove. delete The method according to claim 1,
Wherein the outer surface of the filter housing is formed with a fusing depth confirming portion corresponding to an end of the guide portion when the housing cap and the filter housing are normally fused. The method of claim 3,
Wherein a distance between an end of the filter housing and a fusing depth confirmation part is formed to be longer than a distance between a fused groove entrance of the filter housing cap and an end of the guide part. The method of claim 3,
Wherein the fusing depth verifying portion is formed in a circular shape along a circumferential direction of the filter housing.

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