JP7196012B2 - drain hose fitting - Google Patents

Description

TECHNICAL FIELD The present invention relates to a drain hose connector used for connecting the drain hose to a waste water treatment member that guides the waste water flowing out of the drain hose to a predetermined location.

Drain water from air conditioners and water heaters is discharged as waste water from drain hoses. When such wastewater flows directly on the floor surface of verandas and common corridors of multi-family buildings such as condominiums and apartments, office buildings, commercial facility buildings, etc., stains and the like occur on the floor surface. . In order to prevent this, conventionally, a drainage treatment member for an air conditioner drain is installed on the floor surface to guide the drainage flowing out from the drain hose to a predetermined location such as a rain gutter or a side ditch. A drain hose connector is attached to the waste water treatment member for connecting the end of the drain hose to the waste water treatment member.
For example, Patent Literature 1 discloses a hose holding cylinder having a hose insertion opening at the upper end that rises vertically upward, a hose retaining part protruding from the inner surface of the hose holding cylinder, and support legs formed on both sides of the lower end of the hose holding cylinder. A drain hose fitting is disclosed comprising: This hose holding tube holds two drain hoses side by side in the width direction of the wastewater treatment member (the direction perpendicular to the longitudinal direction of the wastewater treatment member). However, when using a connector that holds two drain hoses in the width direction in this way, it is necessary to attach a correspondingly wide wastewater treatment member to the floor, and the installation space for the wastewater treatment member is large. area.

In Patent Document 2, there is disclosed a one-sided open cylindrical portion having first and second insertion spaces into which a drain hose can be inserted and removed in the axial direction, and a main body that guides drainage from the drain hose to the side of a wastewater treatment member. and , wherein the first insertion space and the second insertion space are arranged side by side in the front-rear direction. Such a drain hose connector is attached to the waste water treatment member so that the longitudinal direction of the drain hose connector extends along the longitudinal direction of the waste water treatment member. According to the drain hose connector of Patent Document 2, it is possible to use a waste water treatment member that is narrower than that of Patent Document 1, and the installation place of the waste water treatment member can be relatively small.

JP 2009-264461 A JP 2013-204607 A

However, in recent years, due to the high functionality of air conditioners, not only dew condensation water (normal drain water) generated from air conditioners, but also a large amount of waste water is temporarily generated by the self-cleaning function of air conditioners. A large amount of waste water may be generated not only from the air conditioner but also from the water heater.
In the drain hose connectors of Patent Documents 1 and 2, it is not assumed that such a large amount of waste water is generated, and a drain hose connector that can smoothly flow a large amount of waste water to the waste water treatment member is provided. It has been demanded.

SUMMARY OF THE INVENTION An object of the present invention is to provide a drain hose connector in which drain hoses can be inserted side by side in the front-rear direction, and a large amount of waste water from the drain hose can smoothly flow to a waste water treatment member through a water passage without overflowing. is.

The drain hose connector of the present invention is a drain hose connector attached to a belt-shaped wastewater treatment member laid on a floor surface, and comprises a cylindrical portion into which a drain hose can be inserted, and a drain hose for draining water. a case body having a water flow port for flowing water to a processing member side, the case body including a front wall portion in which the water flow port is opened, and left and right side wall portions continuously provided on both sides of the front wall portion; and, inside the case body, an internal space defined by the front wall portion and the side wall portions and facing the water flow port is formed, and the tubular portion It has a first insertion cylinder part into which the first drain hose can be inserted along the axial direction thereof, and a second insertion cylinder part into which the second drain hose can be inserted, wherein the first insertion cylinder part is the second insertion cylinder part. The first insertion cylinder part and the second insertion cylinder part are positioned in front of the second insertion cylinder part and arranged side by side in the front-rear direction. The angle is greater than the angle of the axial direction of the second insertion cylinder with respect to the lower surface of the case body.

In a preferred drain hose connector of the present invention, the case body has a partition wall portion, and the partition wall portion is provided between the first insertion tubular portion and the second insertion tubular portion to provide the first insertion tube portion. It partitions the tubular portion and the second insertion tubular portion.
In the preferred drain hose connector of the present invention, the first insertion cylinder part and the second insertion cylinder part are arranged so that the axial direction of the first insertion cylinder part and the axial direction of the second insertion cylinder part intersect in the internal space. A cylindrical portion is formed.
In the preferred drain hose connector of the present invention, the inclination angle of the first insertion cylinder with respect to the lower surface in the axial direction is 60 degrees to 85 degrees, and the inclination of the second insertion cylinder with respect to the lower surface in the axial direction. The angle is 10 degrees to 30 degrees.

According to the drain hose connector of the present invention, even when a large amount of waste water flows out from the drain hose, the waste water can be smoothly guided to the waste water treatment member for treatment without overflowing from the tubular portion.

1 is a reference perspective view of a waste water treatment structure of the present invention; FIG. FIG. 2 is a partially omitted perspective view including a cross section cut along line II-II of FIG. 1; FIG. 2 is a partially omitted cross-sectional view taken along line III-III of FIG. 1; FIG. 4 is a partially omitted cross-sectional view taken along line IV-IV of FIG. 3; FIG. 4 is an end view cut along line VV of FIG. 3; An end view is a view that shows only the shape of a cut surface and does not show the shape on the back side of the cut surface. The front view of a waste water treatment member. The middle part omission top view which looked at the same waste water treatment member from the surface side. The perspective view which looked at the drain hose connector from the left rear side and upper side. The perspective view which looked at the same drain hose connector from the right front side and lower side. The front view of the same drain hose connector. The rear view of the same drain hose connector. The right side view of the same drain hose connector. The top view of the same drain hose connector. The bottom view of the same drain hose connector. FIG. 14 is a cross-sectional view taken along line XV-XV of FIG. 13; Sectional drawing cut|disconnected by the XVI-XVI line of FIG. FIG. 15 is a cross-sectional view taken along line XVII-XVII of FIG. 15;

Hereinafter, the present invention will be described with appropriate reference to the drawings.
In this specification, in the description of the drain hose connector, "front" refers to the side on which drainage from the drain hose inserted into the drain hose connector flows, and "rear" refers to the opposite side. "Bottom" refers to the side facing the wastewater treatment member when the drain hose fitting is installed, and "top" refers to the opposite side. Moreover, in the present specification, the term "substantially" means the range allowed in the technical field to which the present invention belongs.
In this specification, the numerical range represented by "lower limit value X to upper limit value Y" means the lower limit value X or higher and the upper limit value Y or lower. When a plurality of numerical ranges are described separately, an arbitrary lower limit value and an arbitrary upper limit value can be selected, and "an arbitrary lower limit value to an arbitrary upper limit value" can be set.

[Overview of wastewater treatment structure]
FIG. 1 is a perspective view of the wastewater treatment structure B of the present invention, FIG. 2 is a partially omitted perspective view including a cross section of the wastewater treatment structure B of FIG. 1 cut in the width direction, and FIG. FIG. 4 is a partially omitted cross-sectional view of the drain hose connector 1 cut in the front-rear direction of the treatment structure B, and FIG. It is an abbreviated cross-sectional view, and FIG. 5 is an end view of the first insertion tube portion 3 cut in the horizontal direction.
The wastewater treatment structure B comprises a wastewater treatment member 8 which is a band-shaped member laid on the floor surface A and has a drainage channel 81, and a drain hose connector 1 installed on the drainage channel 81 of the wastewater treatment member 8. and have The lower surface of the drain hose connector 1 is placed on the drainage channel 81, and the front-back direction is aligned with the longitudinal direction of the waste water treatment member 8 (the front-back direction of the drain hose connector 1 is the longitudinal direction of the waste water treatment member 8). (substantially parallel) and installed in the wastewater treatment member 8 .
Hereinafter, after explaining each of the waste water treatment member 8 and the drain hose connector 1, the waste water treatment structure B obtained by constructing them will be described in detail.

[Wastewater treatment materials]
6 is a front view of the waste water treatment member 8, and FIG. 7 is a plan view thereof.
The wastewater treatment member 8 is a member installed on the floor surface of a common corridor or the like in order to guide the wastewater flowing out from the drain hose of the air conditioner attached to the drain hose connector 1 to a predetermined location such as a rain gutter or a side ditch. is.
6 and 7, the overall shape of the waste water treatment member 8 is band-like. In addition, in FIG. 7, the middle portion of the waste water treatment member 8 having the same shape is omitted.
The belt-like shape means a substantially rectangular shape in a plan view in which the length in the longitudinal direction is sufficiently longer than the width direction (the width direction is a direction orthogonal to the longitudinal direction).
Normally, the waste water treatment member 8 is formed so that its length in the longitudinal direction is larger than the actual size of the construction site, and is appropriately cut for use according to the construction site.

On the surface of the wastewater treatment member 8, a pair of left and right groove edge projections 82, 82 arranged on both sides in the width direction protrude. The groove edge ridges 82 are projections that are continuous in the longitudinal direction (that is, ridges). The groove edge ridges 82 are formed in a substantially triangular shape when viewed in cross section, but the cross sectional shape of the groove edge ridges 82 is not limited to a substantially triangular shape. It may have a semi-elliptical shape, a substantially rectangular shape, or the like (not shown).
The drainage channel 81 is a portion sandwiched between the pair of groove edge ridges 82, 82, and is a portion recessed in a generally central region in the width direction. The drainage channel 81 has a substantially horizontal surface and extends in a belt shape in the longitudinal direction. The drainage channel 81 is formed sufficiently lower than the groove edge ridge 82 .
A straightening ridge 83 may be provided in the drainage channel 81 as necessary. The straightening ridges 83 are formed in a part of the drainage channel 81 in the width direction. The straightening ridges 83 function as guides that guide the drainage along the drainage channel 81 so as to flow in the longitudinal direction. Although one rectification ridge 83 may be provided, in the illustrated example, a plurality of rectification ridges 83 (for example, three) are formed at predetermined intervals in the width direction. The protrusion height of the rectifying ridges 83 is not particularly limited, but is preferably sufficiently lower than that of the groove edge ridges 82 . The rectifying ridges 83 are formed in a substantially triangular shape (substantially isosceles triangular shape, etc.) when viewed in cross section, but are not limited thereto. etc. (not shown).

The waste water treatment member 8 is flexible and can be easily bent.
The material for forming the wastewater treatment member 8 is not particularly limited, and conventionally known materials can be used, and thermoplastic resin is generally used. Examples of the thermoplastic resin include vinyl chloride-based resins such as vinyl chloride and vinyl chloride-vinyl acetate copolymers; polyolefin-based resins; urethane-based resins; vinyl acetate-based resins such as ethylene-vinyl acetate copolymers; Acrylic resins such as resins; polyamide resins; ester resins; various elastomers such as olefin elastomers and styrene elastomers. These can be used alone or in combination of two or more. It is preferable to use a vinyl chloride resin as the main component resin because it has excellent flexibility and is easy to process. The forming material may be foamed, but is usually non-foamed.
The waste water treatment member 8 is obtained by extruding the thermoplastic resin.

[Drain hose connector]
8 and 9 are perspective views of the drain hose connector 1, and FIGS. 10 to 14 are six views of the drain hose connector 1 (however, the left side view is omitted because it appears symmetrically with the right side view). ), and FIGS. 15 to 17 are sectional views of the drain hose connector 1 including the tubular portion.
8 to 14, the drain hose connector 1 of the present invention includes cylindrical portions 3 and 4 into which flexible drain hoses can be inserted and removed in the axial direction, and drainage from the drain hoses. It has a case body 2 having a water flow port 5 for flowing to the member 8 side.

Two cylindrical portions 3 and 4 are formed. In this specification, the tubular portions 3 and 4 refer to tubular spaces formed inside the drain hose connector 1 (case body 2).
One cylindrical portion 3 (first insertion cylindrical portion 3) can insert the first drain hose along its axial direction, and the other cylindrical portion 4 (second insertion cylindrical portion 4) is the first It is arranged behind the insertion cylinder part 3 and into which the second drain hose can be inserted. Therefore, the first insertion cylinder portion 3 and the second insertion cylinder portion 4 are arranged side by side in the front-rear direction of the case body 2 .
The case body 2 can, for example, stand on its own on a horizontal plane with its lower surface 2a facing downward.

The first insertion tube portion 3 and the second insertion tube portion 4 are arranged such that the respective axial directions L3 and L4 have desired angles with respect to the lower surface 2a of the case body 2 (non-parallel to the lower surface 2a of the case body 2). ), which has been extended.
Here, the lower surface 2a of the case body 2 conceptually means a plane including a portion in contact with a horizontal plane when the case body 2 is made to stand on its own.
The angle of the axial direction L3 of the first insertion cylinder part 3 with respect to the lower surface 2a of the case body 2 is larger than the angle of the axial direction of the second insertion cylinder part 4 with respect to the lower surface of the case body.
Preferably, the axial direction L3 of the first insertion cylinder portion 3 and the axial direction L4 of the second insertion cylinder portion 4 are inclined at an acute angle with respect to the lower surface 2a of the case body 2, The angle of the axial direction L3 of the cylindrical portion 3 with respect to the lower surface 2a is larger than the angle of the second insertion cylindrical portion 4. As shown in FIG.
Further, the first insertion cylinder part 3 and the second insertion cylinder part 4 are arranged so that the axial direction L3 of the first insertion cylinder part 3 and the axial direction L4 of the second insertion cylinder part 4 intersect in the internal space 29. formed.
In FIG. 15, the axial direction L3 of the first insertion tube portion 3 and the axial direction L4 of the second insertion tube portion 4 are indicated by two-dot chain lines.

Specifically, the case body 2 includes a front wall portion 21, left and right side wall portions 22, 22, a bottom wall portion 23 connected to the lower side of the left and right side wall portions 22, 22, and left and right side wall portions. 22 , 22 , a rear wall portion 24 connected to the bottom wall portion 23 , and a top wall portion 25 connected to the upper side of the left and right side wall portions 22 , 22 .

The front wall portion 21 is a wall portion directed toward the side where water flows when the drain hose connector 1 is installed in the wastewater treatment member 8, and the rear wall portion 24 is directed toward the side opposite to the water flow. It is a wall that is
A water flow port 5 is formed below the front wall portion 21 . The water passage port 5 is defined by a notch portion 51 obtained by notching the entire lower portion or a portion of the lower portion of the front wall portion 21 . Note that when the notch portion 51 is formed in a part of the lower portion of the front wall portion 21 , the lower end surface of the front wall portion 21 where the notch portion 51 is not formed faces the lower surface 2 a of the case body 2 . Configure.
A pair of left and right side wall portions 22 , 22 cooperate with the front wall portion 21 to define an internal space 29 . As shown in FIG. 12, the side wall portions 22, 22 are formed in a substantially fan shape when viewed from the side. However, the side view shape of the side wall portions 22, 22 is not limited to the substantially fan shape, and may be substantially a rectangular shape such as a substantially rectangular quadrangular shape, a substantially square shape, a substantially parallelogram shape, or the like.

The bottom wall portion 23 is a wall portion that closes the bottom portion of the case body 2 . The lower surface of the bottom wall portion 23 constitutes the lower surface 2 a of the case body 2 . The bottom wall portion 23 may be provided over the entire front-rear direction of the case body 2 , or may be provided at a part of the case body 2 in the front-rear direction. In the illustrated example, the bottom wall portion 23 is not provided near the front wall portion 21 but is provided on the rear side of the case body 2 . Therefore, in the vicinity of the front wall portion 21 in the bottom portion of the case body 2, the bottom wall portion 23 is not provided and an opening is formed.
In the opening, the lower end surfaces of the pair of side wall portions 22, 22 constitute the lower surface 2a of the case body 2. As shown in FIG. Therefore, in the illustrated example, the lower surface 2 a of the case body 2 is composed of the lower end surface of the front wall portion 21 , the front lower end surfaces of the side wall portions 22 and 22 , and the lower surface of the bottom wall portion 23 .
When the drain hose connector 1 of the present invention is installed in the drainage channel 81 having the rectifying ridges 83, the recess 26 in which the rectifying ridges 83 are fitted extends in the front-rear direction on the lower surface of the bottom wall portion 23. provided. The grooves 26 are provided corresponding to the rectifying ridges 83, and in the illustrated example, three grooves 26 are formed at predetermined intervals in the width direction.
Since the drain hose connector 1 is placed on the drain channel 81 of the waste water treatment member 8, the case body 2 may have no bottom wall (not shown). In the case body 2 that does not have a bottom wall portion, the lower end surfaces of the pair of side wall portions 22 and 22 and the lower end surface of the front wall portion 21 constitute the lower surface 2a of the case body 2 .

An insertion opening 31 (hereinafter referred to as the first insertion opening 31) of the first insertion cylinder section 3 is opened in a part of the top wall portion 25. As shown in FIG.
An insertion port 41 (hereinafter referred to as a second insertion port 41) of the second insertion cylinder portion 4 is opened in a part of the rear wall portion 24. As shown in FIG.
In the illustrated example, the first insertion opening 31 and the second insertion opening 41 are substantially square-shaped openings, but are not limited to this shape, and may be substantially rectangular such as substantially rectangular, substantially triangular, substantially hexagonal, or the like. may be substantially polygonal, substantially circular, substantially elliptical, or the like.

The first insertion tubular portion 3 has a substantially tubular shape extending from the first insertion port 31 into the case body 2 .
The first insertion tube portion 3 is composed of an elongated space surrounded by a partition wall portion 27 that continues from the front wall portion 21 , both side wall portions 22 and 22 , and the top wall portion 25 . The first drain hose can be inserted into and removed from the first insertion tubular portion 3 (long space) along the axial direction thereof. The first insertion tubular portion 3 allows the first drain hose to be inserted with the axial direction L3 of the tubular portion substantially parallel to the axial direction of the first drain hose, and inserts the first drain hose. It has a function to guide In addition, the first insertion tubular portion 3 has a function of holding the inserted first drain hose in cooperation with a rib portion which will be described later. When the first drain hose is inserted into the first insertion cylinder part 3, the axial direction of the first drain hose and the axial direction L3 of the first insertion cylinder part 3 substantially coincide.
When the first insertion port 31 has a substantially square shape such as a substantially square shape or a substantially rectangular shape, the first insertion tube portion 3 has a substantially square tube shape extending from the first insertion port 31 . Since the first insertion cylinder part 3 is formed into a substantially square cylinder shape including the first insertion port 31, there is a gap between the four corners of the substantially square cylinder shape and the outer peripheral surface of the substantially cylindrical first drain hose. A relatively large gap is generated between the first drain hose and the first drain hose so that it can be easily inserted into the first insertion cylindrical portion 3 while being deformed. Further, the first insertion cylinder part 3 is formed in a substantially square cylinder shape with a size such that the outer peripheral surface of the substantially cylindrical first drain hose contacts the inner surface of the first insertion cylinder part 3 at four points. Thus, the first drain hose is stably held.

The first insertion tube portion 3 is formed such that its axial direction L3 forms a desired angle with respect to the lower surface 2a of the case body 2. As shown in FIG.
The angle of the axial direction L3 of the first insertion tube portion 3 with respect to the lower surface 2a of the case body 2 may be an obtuse angle, a right angle, or an acute angle. Acute angle. Referring to FIG. 15, an angle D3 of the axial direction L3 of the first insertion tube portion 3 (the inclination angle of the axial direction L3 of the first insertion tube portion 3 with respect to the lower surface 2a of the case body 2) is Although the angle is not particularly limited as long as it is larger than the angle D4 of the axial direction L4 of the second insertion tube portion 4, it is preferable that the angle intersects with the axial direction L4 of the second insertion tube portion 4 in the internal space 29. Since the drainage from the first drain hose can be guided to the internal space 29 and discharged through the water passage 5, the angle D3 of the axial direction L3 of the first insertion cylinder part 3 is, for example, 60 degrees to 90 degrees, preferably , 60 degrees or more and less than 90 degrees, more preferably 60 degrees to 85 degrees, still more preferably 65 degrees to 85 degrees, and most preferably 65 degrees to 80 degrees.

A rib portion 32 (hereinafter referred to as a first rib portion 32) is formed on the first insertion tube portion 3 and protrudes toward the axial direction L3 of the tube portion. The first rib portion 32 extends in a long shape along the axial direction L3 of the cylindrical portion. In other words, the first rib portion 32 is an elongated protrusion that protrudes toward the axial direction L3 and extends continuously in the axial direction L3.
Preferably, the first rib portion 32 is an elongated protrusion extending downward from the upper end portion of the side wall portion 22 .
The first rib portion 32 bites into the first drain hose inserted into the first insertion cylinder portion 3 and has a function of holding the first drain hose so that it does not come off easily from the first insertion cylinder portion 3 . In addition, since the first rib portion 32 is formed on the inner surface of the first insertion cylinder portion 3, the inner surface of the first insertion cylinder portion 3 and the portion of the first drain hose other than the portion in contact with the first rib portion 32 and the inner surface of the first insertion cylinder portion 3 There is a gap in all or part of the When the drainage from the first drain hose flows into the internal space 29, the air existing in the internal space 29 is exhausted to the outside of the first insertion cylinder part 3 through the gap, so that the drainage flows into the internal space 29 without hindrance. Become.

At least one first rib portion 32 may be provided on the inner surface of the first insertion tube portion 3 . For example, even if only one first rib portion 32 is provided, the presence of the first rib portion 32 narrows the effective space of the first insertion cylindrical portion 3 into which the first drain hose is inserted. As a result, the first drain hose can be held inside the first insertion cylindrical portion 3 .
Preferably, a plurality (two or more) of the first rib portions 32 are provided independently. For example, a pair of left and right first rib portions 32 , 32 protrude in the first insertion tube portion 3 . In the illustrated example, one first rib portion 32 protrudes from the inner surface of the right side wall portion 22 , and the other first rib portion 32 protrudes from the inner surface of the right side wall portion 22 . The 1 rib portions 32 , 32 are arranged to face each other with the axis of the first insertion tube portion 3 interposed therebetween.

Further, when there are a plurality of first rib portions 32, all the first rib portions 32 may have the same protrusion amount, or some of the first rib portions 32 may have different protrusion amounts, or , the amount of protrusion of all the first rib portions 32 may be different from each other.
Furthermore, the amount of protrusion of the first rib portion 32 may be the same from the top to the bottom (that is, the amount of protrusion of one first rib portion 32 may be constant), or the amount of protrusion of the first rib portion 32 may be constant. The amount of protrusion of the portion 32 may differ from the top to the bottom. Since the first drain hose can be easily inserted and fixed, it is preferable that the first rib portion 32 is formed so that the amount of protrusion increases from the top to the bottom.
In the illustrated example, each first rib portion 32 has a region in which the amount of protrusion increases very slightly as it goes downward. According to this first rib portion 32, the distance between the protruding top portions of the first rib portions 32 facing each other becomes slightly smaller as it goes downward. The hose can be bitten, and the first drain hose can be easily inserted into and held in the first insertion cylindrical portion 3 .

A stopper portion 33 (hereinafter referred to as a first stopper portion 33) is provided in the first insertion cylinder portion 3 to restrict the advancement of the first drain hose. The first stopper portion 33 engages a part of the cylindrical opening end of the first drain hose with the engaging portion 33a so that the inserted first drain hose does not advance ahead of the first stopper portion 33. It has a regulatory function.
The first stopper portion 33 is provided below the first insertion tube portion 3 , for example, at the lower end portion of each first rib portion 32 . In the illustrated example, as the first stopper portion 33 , a protrusion that protrudes toward the axis more than the first rib portion 32 is used. The step becomes the engaging portion 33a of the first stopper portion 33. As shown in FIG.
The distance from the first insertion port 31 to the locking portion 33a of the first stopper portion 33 (the length from the first insertion port 31 to the locking portion 33a in the direction parallel to the axial direction L3) is not particularly limited. , in order to stably hold the first drain hose in the first insertion cylindrical portion 3, it is preferably 15 mm or more.

The second insertion tubular portion 4 has a substantially tubular shape extending from the second insertion port 41 into the case body 2 .
The second insertion tube portion 4 is formed of an elongated space surrounded by both side wall portions 22 , 22 , a partition wall portion 27 continuing from the ceiling wall portion 25 , and a partition wall portion 28 continuing from the rear wall portion 24 . The second drain hose can be inserted into and removed from the second insertion tubular portion 4 (long space) along the axial direction thereof. The second insertion tubular portion 4 allows the second drain hose to be inserted with the axial direction L4 of the tubular portion substantially parallel to the axial direction of the second drain hose, and inserts the second drain hose. It has a function to guide In addition, the second insertion tubular portion 4 has a function of holding the inserted second drain hose in cooperation with a rib portion which will be described later. In a state where the second drain hose is inserted into the second insertion cylinder portion 4, the axial direction of the second drain hose and the axial direction L4 of the second insertion cylinder portion 4 substantially coincide.
When the second insertion port 41 has a substantially square shape such as a substantially square shape or a substantially rectangular shape, the second insertion tube portion 4 has a substantially square tube shape extending from the second insertion port 41 . Since the second insertion cylinder part 4 is formed into a substantially square cylinder shape including the second insertion port 41, there is a gap between the four corners of the substantially square cylinder shape and the outer peripheral surface of the substantially cylindrical second drain hose. A relatively large gap is generated in the second drain hose, so that the second drain hose can be easily inserted into the second insertion cylindrical portion 4 while being deformed. Further, the second insertion tube portion 4 is formed in a substantially square tube shape having a size such that the outer peripheral surface of the substantially cylindrical second drain hose contacts the inner surface of the second insertion tube portion 4 at four points. Thus, the second drain hose is stably held.

The second insertion tube portion 4 is formed such that its axial direction L4 forms a desired angle with respect to the lower surface 2a of the case body 2. As shown in FIG.
The angle of the axial direction L4 of the second insertion tube portion 4 with respect to the lower surface 2a of the case body 2 is preferably an acute angle. Referring to FIG. 15, an angle D4 of the axial direction L4 of the second insertion tube portion 4 (an inclination angle of the axial direction L4 of the second insertion tube portion 4 with respect to the lower surface 2a of the case body 2) Although it is not particularly limited as long as it is smaller than the angle D3 of the axial direction L3 of the insertion tube portion 3, it is preferable that the angle intersects with the axial direction L3 of the first insertion tube portion 3 in the internal space 29. That is, the first insertion cylinder part 3 and the second insertion cylinder part 4 are formed so that the axial direction L3 of the first insertion cylinder part 3 and the axial direction L4 of the second insertion cylinder part 4 intersect in the internal space 29. It is preferable that
The drainage from the second drain hose can be guided to the internal space 29 and discharged through the water passage 5, and even if a large amount of drainage is discharged from the second drain hose, the drainage is temporarily stored in the internal space 29. The angle D4 in the axial direction L4 of the second insertion tube portion 4 is preferably 10 to 30 degrees, more preferably 10 to 25 degrees, because the water can be discharged through the water passage 5 after being retained in the water. As shown in the figure, when the axial direction L4 of the second insertion tube portion 4 does not intersect with the lower surface 2a of the case body 2, the angle D4 is It refers to the angle of the lower surface 2a of the case body 2 with respect to the extended surface.

Further, as shown in FIG. 15, the second insertion cylinder part 4 has the lower end of the second insertion opening 41 positioned at a height of, for example, 7 mm to 20 mm, preferably 8 mm to 13 mm, from the lower surface 2a of the case body 2. position. 15 indicates the height position of the lower end of the second insertion opening 41 from the lower surface 2a of the case body 2. As shown in FIG. Due to the height position equal to or higher than the lower limit value, when the waste water is temporarily retained in the internal space 29, it is possible to prevent the waste water from flowing back through the second insertion cylinder part 4 or overflowing from the second insertion port 41. Due to the height position equal to or lower than the upper limit, the second insertion port 41 can be opened relatively wide, and a second drain hose of a general size can be easily inserted.

A rib portion 42 (hereinafter referred to as a second rib portion 42) is formed on the second insertion tube portion 4 and protrudes toward the axial direction of the tube portion. The second rib portion 42 extends in a long shape along the axial direction of the cylindrical portion. In other words, the second rib portion 42 is an elongated protrusion that protrudes toward the axial direction L4 and extends continuously in the axial direction L4.
Preferably, the second rib portion 42 is an elongated protrusion extending downward from the upper ends of the side wall portions 22 , 22 .
The second rib portion 42 has a function of biting into the second drain hose inserted into the second insertion cylinder portion 4 and holding the second drain hose so that it does not come off easily from the second insertion cylinder portion 4 . In addition, since the second rib portion 42 is formed on the inner surface of the second insertion cylinder portion 4 , the inner surface of the second insertion cylinder portion 4 and the portion of the second drain hose other than the portion in contact with the second rib portion 42 There is a gap in all or part of the When the drainage from the second drain hose flows into the internal space 29, the air existing in the internal space 29 is exhausted to the outside of the second insertion cylinder part 4 through the gap, so that the drainage flows into the internal space 29 without hindrance. Become.

At least one second rib portion 42 may be provided on the inner surface of the second insertion tube portion 4 . For example, even if only one second rib portion 42 is provided, the presence of the second rib portion 42 narrows the effective space of the second insertion cylindrical portion 4 into which the second drain hose is inserted. As a result, the second drain hose can be held inside the second insertion tube portion 4 .
Preferably, a plurality (two or more) of the second rib portions 42 are provided independently. For example, a pair of left and right second rib portions 42 protrude in the second insertion tube portion 4 . In the illustrated example, one second rib portion 42 protrudes from the inner surface of the right side wall portions 22, 22, and the other second rib portion 42 protrudes from the inner surface of the right side wall portions 22, 22. , the pair of second rib portions 42 are arranged to face each other across the axis of the second insertion cylinder portion 4 .

Further, when there are a plurality of second rib portions 42, all the second rib portions 42 may have the same protrusion amount, or some of the second rib portions 42 may have different protrusion amounts, or , the amount of protrusion of all the second rib portions 42 may be different from each other.
Furthermore, the amount of protrusion of the second rib portion 42 may be the same from the top to the bottom (that is, the amount of protrusion of one second rib portion 42 may be constant), or the amount of protrusion of the second rib portion 42 may be constant. The amount of projection of the portion 42 may differ from the top to the bottom. Since the second drain hose can be easily inserted and fixed, it is preferable that the second rib portion 42 is formed so that the amount of protrusion increases from the top to the bottom.
In the illustrated example, each second rib portion 42 has a region in which the amount of protrusion increases very slightly as it goes downward. According to this second rib portion 42, the distance between the protruding top portions of the second rib portions 42 facing each other is slightly reduced in the downward direction, and the second drain is moved while the protruding top portions of the pair of second rib portions 42 are slid. The hose can be bitten, and the second drain hose can be easily inserted into and held in the second insertion tubular portion 4 .

The second insertion tube portion 4 is provided with a stopper portion 43 (hereinafter referred to as a second stopper portion 43) that restricts the advancement of the second drain hose. The second stopper portion 43 engages a portion of the cylindrical opening end of the second drain hose with its engaging portion 43a so that the inserted second drain hose does not advance ahead of the second stopper portion 43. It has a regulatory function.
The second stopper portion 43 is provided below the first insertion cylinder portion 3 , for example, at the lower end portion of each second rib portion 42 . In the illustrated example, as the second stopper portion 43 , a protrusion that is larger than the second rib portion 42 and protrudes toward the axis is used. The step serves as a locking portion 43 a of the second stopper portion 43 .
The distance from the second insertion port 41 to the locking portion 43a of the second stopper portion 43 (the length from the second insertion port 41 to the locking portion 43a in the direction parallel to the axial direction L4) is not particularly limited. , in order to stably hold the second drain hose in the second insertion cylindrical portion 4, it is preferably 15 mm or more.

As described above, the first stopper portion 33 and the second stopper portion 43 are the advancing restricting portions of the first drain hose and the second drain hose inserted into the first insertion cylinder portion 3 and the second insertion cylinder portion 4, respectively. be.
Here, referring to FIG. 3, when the first drain hose 71 is inserted into the first insertion cylinder portion 3 until the cylinder opening end 71a is locked by the first stopper portion 33, the first drain hose 71 is The maximum insertion state of the second drain hose 72 is when the second drain hose 72 is inserted into the second insertion tube portion 43 until the tube opening end 72a is locked by the second stopper portion 43. be.

The first stopper portion 33 is arranged so that the tube opening end 71a of the first drain hose 71 does not intersect the axial direction L4 of the second insertion tube portion 4 in the maximum insertion state of the first drain hose 71. preferably. The open end of the tube of the drain hose has a substantially circular shape in three dimensions, and is linear in a cross-sectional view (side view). In FIG. 3, the axial direction L4 of the second insertion tube portion 4 is indicated by a chain double-dashed line.
By arranging the first stopper portion 33 in this way, the drainage flowing out from the second drain hose 72 is less likely to be blocked by the first drain hose 71 and reaches the water passage port 5 from the internal space 29 . More specifically, in the second drain hose 72 held in the second insertion cylindrical portion 4 inclined at an acute angle, the water drains from the second drain hose 72 in accordance with gravity, as indicated by the thick arrow in FIG. It flows out along the bottom side of the inside. When a large amount of water is discharged, the water in the second drain hose 72 is generally at the same level as or lower than the axial direction of the second drain hose 72 (the axial direction L4 of the second insertion cylinder part 4). Then, it flows out along the inside of the hose 72 . As described above, the second stopper portion 43 is arranged so that the tubular opening end 71a of the first drain hose 71 does not intersect the axial direction L4 of the second insertion tubular portion 4, so that the second drain hose 72 The wastewater coming out of the opening end 72a of the cylinder is less likely to collide with the tip of the first drain hose 71, and even if the case body 2 is made relatively small, it is easy to smoothly flow from the internal space 29 to the water passage 5.

On the other hand, in the maximum insertion state of the second drain hose 72, the second stopper portion is arranged so that the tube opening end 72a of the second drain hose 72 does not cross the first drain hose 71 inserted into the first insertion tube portion 3. 43 is preferably arranged. For example, the second stopper portion 43 is arranged so that the tube opening end 72a of the second drain hose 72 does not protrude into the tube of the first insertion tube portion 3 when the second drain hose 72 is fully inserted. preferably.
By arranging the second stopper portion 43 in this way, when inserting the first drain hose 71 and the second drain hose 72 into the first insertion cylinder portion 3 and the second insertion cylinder portion 4, one hose does not interfere with insertion of the other hose.

Referring to FIG. 15 , the axial direction L3 of the first insertion tube portion 3 and the axial direction L4 of the second insertion tube portion 4 intersect in the internal space 29 .
The internal space 29 is a space defined by the front wall portion 21 and the side wall portions 22 , 22 and is one space within the case body 2 facing the water passage port 5 of the front wall portion 21 . 15, the internal space 29 includes the front wall portion 21 of the case body 2, the lower surface 2a, the lower end portion of the first insertion cylinder portion 3 (locking portion 33a of the first stopper portion 33), and the second insertion cylinder. It is a region generally surrounded by the lower end portion of the portion 4 (locking portion 43a of the second stopper portion 43). In addition, when the lower end of the first insertion cylinder part 3 and the lower end of the second insertion cylinder part 4 are not clearly defined, conceptually, the lower end of the first insertion cylinder part 3 is locked by the first stopper part 33 . A virtual plane passing through the portion 33a and perpendicular to the axial direction L3 of the first insertion tube portion 3 is regarded as a virtual plane. A virtual plane passing through the stop portion 43a and perpendicular to the axial direction L4 of the second insertion tube portion 4 is regarded as a virtual plane. In FIG. 15, a virtual plane K3 passing through the engaging portion 33a and a virtual plane K4 passing through the engaging portion 43a are indicated by fine dotted lines.
In the drain hose connector 1 of the present invention, the internal space 29 has a large capacity, and even if a large amount of wastewater is temporarily discharged, the wastewater is retained in the internal space 29 and is constantly drained through the water flow port 5. Since a large amount of waste water can be discharged, it is possible to prevent the waste water from overflowing the drain hose connector 1 and the waste water treatment member 8. - 特許庁
The size of the internal space 29 is not particularly limited, but is, for example, 5 cm ³ to 7 cm ³ . The drain hose connector 1 having the internal space 29 of such a volume is not only condensed water (normal drain water) from the air conditioner, but also the self-cleaning function of the air conditioner and / or the drainage of the water heater. Even if a large amount of waste water flows, the waste water can be temporarily retained in the internal space 29, and the overflow of water from the drain hose connector 1 can be effectively prevented.

As described above, in a preferred embodiment, the first insertion cylinder part 3 and the second insertion cylinder part 3 are arranged so that the axial direction L3 of the first insertion cylinder part 3 and the axial direction L4 of the second insertion cylinder part 4 intersect in the internal space 29. 2. The arrangement and inclination angle of the insertion cylinder part 4 are set. Hereinafter, the point O at which the axial directions of the two cylindrical portions intersect is referred to as an intersection point.
The minimum value of the linear length from the locking portion 33a of the first stopper portion 33 of the first insertion tube portion 3 to the intersection point O is not particularly limited, but if it is too short, the internal space 29 becomes relatively too small. If it is too large, the case body 2 becomes too large. From this point of view, the linear length between the engaging portion 33a of the first stopper portion 33 and the intersection point O is preferably 5 mm or more, and more preferably 8 mm to 13 mm.
The minimum value of the linear length from the locking portion 43a of the second stopper portion 43 of the second insertion tube portion 4 to the intersection point O is not particularly limited, but if it is too short, the internal space 29 becomes relatively too small. If it is too large, the case body 2 becomes too large. From this point of view, the linear length between the engaging portion 43a of the second stopper portion 43 and the intersection point O is preferably 10 mm or more, and more preferably 15 mm to 20 mm.

The case body 2 is made of a relatively hard material that does not easily deform.
The material for forming the case body 2 is not particularly limited, and conventionally known materials can be used. Generally, synthetic resin, metal, etc. are used, and hard resin is preferably used. Examples of hard resins include polystyrene, AES resin (acrylonitrile-ethylene-propylene-diene-styrene), ASA resin (acrylonitrile-styrene-acrylic rubber), and the like.
The case body 2 made of hard resin can be integrally formed by injection molding or the like. Alternatively, the case body 2 may be formed by dividing the case body 2 into two or more parts, molding each part, and joining the parts by bonding with an adhesive or resin welding.

[Use of drain hose connector and wastewater treatment structure]
The drain hose connector 1 is installed on the floor surface A together with the waste water treatment member 8 .
1 to 5, a wastewater treatment member 8 is laid on a floor surface A, and a drain hose connector 1 is attached to the wastewater treatment member 8. As shown in FIG. A drain hose is attached to the drain hose connector 1 , and waste water flowing out from the drain hose is guided to a predetermined location such as a side ditch 91 through a drainage channel 81 of the waste water treatment member 8 .

The floor surface A can be, for example, a shared corridor of a structure such as an apartment building or a veranda, but is not limited to this. The floor surface A is sloped to guide water to the gutters 91 . In other words, the floor surface A is an inclined plane that gradually lowers toward the gutter 91 . Such a slope of the floor surface A is also called a water slope and is usually 1/50 to 1/100. In addition, 1/50 means a slope that is 1 cm lower than the length of 50 cm. Therefore, the water on the floor surface A flows along the water gradient from the wall surface 92 side of the structure to the gutter 91 side.
The waste water treatment member 8 is mounted on the floor surface A so that its longitudinal direction is substantially orthogonal to the side gutter 91, for example.

The back surface of the wastewater treatment member 8 is fixed to the floor surface A via an adhesive means. The bonding means 93 is not particularly limited, and examples thereof include using an adhesive, a double-sided adhesive tape, and the like. In the illustrated example, an adhesive is used as the bonding means 93 .
The side end faces of the floor sheet material 94 are joined to the both side end faces of the waste water treatment member 8 . As the floor sheet material 94, a sheet material made mainly of synthetic resin can be used, and in particular, a sheet material whose surface at least is made of vinyl chloride resin can be used.
The floor sheet material 94 is fixed to the floor surface A via an adhesive means 93 such as adhesive or double-sided adhesive tape. A gap filling material 95 may be provided between the side end surface of the waste water treatment member 8 and the side end surface of the floor sheet material 94 to improve watertightness. As the gap filling material 95, a welding rod made of resin, a sealing material, or the like can be used.

The drain hose connector 1 is attached on the drain channel 81 at the end of the waste water treatment member 8 (the end on the wall surface 92 side). The lower surface 2a of the case body 2 of the drain hose connector 1 is fixed onto the drainage channel 81 of the wastewater treatment member 8 via an adhesive means. Adhesive means are not particularly limited, and examples thereof include the use of adhesives, double-sided adhesive tapes, and the like. In addition, although it is preferable that the entire lower surface 2a of the case body 2 is fixed on the drainage channel 81, at least the lower surface of the bottom wall portion 23 of the case body 2 is fixed to the drainage channel 81. It is good if there is
For example, the lower surface 2a of the case body 2 is placed on the drainage channel 81 while the front wall portion 21 of the case body 2 is opposed to the side groove 91 side and the rear wall portion 24 is opposed to the wall surface 92 side. to the drainage channel 81 via an adhesive means (not shown) such as an adhesive, the drain hose connector 1 is attached to the drainage treatment member 8 . As described above, when the case body 2 has the bottom wall portion 23 and the rectifying ridges 83 are formed in the drainage channel 81, the grooves 26 of the bottom wall portion 23 correspond to the rectifying ridges 83. By placing the lower surface 2 a of the case body 2 on the drainage channel 81 , the drain hose connector 1 can be stably attached to the drainage treatment member 8 .

Since the water passage port 5 is formed in the front wall portion 21 of the case body 2 , when the drain hose connector 1 is attached to the waste water treatment member 8 , there is a gap between the water passage 81 of the waste water treatment member 8 and the water passage port 5 . A gap occurs in the Drainage from the drain hose flows over the drainage channel 81 of the drainage treatment member 8 from within the drain hose connector 1 through the gap.
The length of the gap in the vertical direction (the length between the drainage channel 81 and the upper end surface of the notch 51 defining the water passage 5) is not particularly limited, but if it is too small, it will be difficult for the drainage to flow out. If it is too large, the appearance of the drain hose connector 1 is not good, and there is a possibility that foreign matter may enter the case body 2 through the gap. From this point of view, the vertical length of the gap is, for example, 1.5 mm to 10 mm, preferably 2 mm to 8 mm, and more preferably 4 mm to 7 mm. By setting the length of the gap in the vertical direction within the above range, even if a large amount of waste water temporarily flows, the amount of waste water discharged from the water passage port 5 to the drainage channel 81 can be kept below a certain amount. It is possible to prevent the drain hose connector 1 from overflowing from the drain hose connector 1 .

A first drain hose 71 is inserted into the first insertion tubular portion 3 of the drain hose connector 1 attached to the waste water treatment member 8 , and a second drain hose 72 is inserted into the second insertion tubular portion 4 .
The first drain hose 71 is inserted with its axial direction along the axial direction of the first insertion cylinder portion 3 and bites into the first rib portion 32 to be held in the first insertion cylinder portion 3 . Since the first stopper portion 33 is provided, the first drain hose 71 is not inserted beyond the first stopper portion 33, and the maximum insertion length of the first drain hose 71 is up to the first stopper portion 33. is. It should be noted that the first drain hose 71 does not necessarily have to be inserted until it is locked by the first stopper portion 33, and it does not bite into the first rib portion 32 and inadvertently come out of the first insertion cylindrical portion 3. It should be inserted to the extent.

The second drain hose 72 is also inserted along the axial direction of the second insertion tubular portion 4 and is held in the second insertion tubular portion 4 by biting into the second rib portion 42 . Since the second stopper portion 43 is provided, the second drain hose 72 is not inserted beyond the second stopper portion 43, and the maximum insertion length of the second drain hose 72 is up to the second stopper portion 43. is. It should be noted that the second drain hose 72 does not necessarily have to be inserted until it is locked by the second stopper portion 43, and it does not bite into the second rib portion 42 and inadvertently come out of the second insertion tube portion 4. It should be inserted to the extent.
In the illustrated example, the first and second drain hoses 71 and 72 are substantially circular corrugated hoses (hereinafter referred to as corrugated hoses) that are generally used as drain hoses. However, a drain hose other than a corrugated hose may be attached to the drain hose connector 1. However, in consideration of biting into the first rib portion 32 and the second rib portion 42, the first and second drain hoses 71 and 72 are preferably corrugated hoses. A corrugated hose, as shown in FIG. 3, has a bellows-like shape in which valleys recessed in the circumferential direction are formed at predetermined intervals in the longitudinal direction, and is also called a corrugated tube. Since the corrugated hose has a strong restoring force against deformation due to its bellows-like shape, the restoring force makes it stronger against the first and second stopper portions 33 and 43 provided in the drain hose connector 1 of the present invention. Since it engages, it becomes difficult to unintentionally slip out of the first and second insertion tube portions 3 and 4 tube portions.
The outer peripheral lengths of the first and second drain hoses 71 and 72 are not particularly limited, and hoses having a diameter of 8 mm to 25 mm are exemplified independently. The first insertion tubular portion 3 and the second insertion tubular portion 4 may be formed in a tubular shape into which the first and second drain hoses 71 and 72 having the outer peripheral length can be inserted and removed.

In the wastewater treatment structure B, the wastewater discharged from the first and second first drain hoses 71 and 72 flows from the internal space 29 of the case body 2 through the water passage 5 (the gap between the water passage 5 and the drainage channel 81). After coming out of the drain hose connector 1 , it is discharged to a predetermined location such as a side ditch 91 along the drainage channel 81 .
In the drain hose connector 1 of the present invention, the first insertion cylinder part 3 and the second insertion cylinder part 4 are arranged side by side in the front-back direction of the case body 2, so the width of the waste water treatment member 8 does not increase. , the waste water treatment member 8 and the drain hose connector 1 can be installed even in a relatively narrow place.
Furthermore, in the drain hose connector 1 of the present invention, since the angle D3 of the first insertion cylinder portion 3 in the axial direction L3 is larger than the angle D4 of the second insertion cylinder portion 4, the drainage in the case body 2 is prevented from flowing into the inner space. The water flows smoothly from 29 through the water passage port 5 . In particular, the first insertion cylinder part 3 and the second insertion cylinder part 4 are formed so that the axial direction L3 of the first insertion cylinder part 3 and the axial direction L4 of the second insertion cylinder part 4 intersect in the internal space 29. Therefore, the wastewater discharged from the first and second first drain hoses 71 and 72 smoothly flows into the wastewater treatment member 8 through the water passage port 5 .

As in the past, in the drain hose connector in which the first and second drain hoses are held in parallel in the front-rear direction, when a large amount of drainage comes out of the first and second drain hoses (hereinafter referred to as the second drain hose) The wastewater discharged from the first drain hose is called the first water, and the wastewater discharged from the second drain hose is called the second water). Drainage sometimes overflowed from the insertion port of the part.
In this regard, according to the drain hose connector 1 of the present invention, the first water flows out at a relatively large acute angle with respect to the lower surface 2a of the case body 2, while the second water flows in the confluence region. It flows out so as to collide with the flow of the first water from behind. Therefore, the momentum of the first water and the second water cancels each other in the confluence area, the momentum of both water is relaxed, and the first water and the second water flow smoothly from the water passage 5 to the outside of the drain hose connector 1. will be discharged to

1 Drain hose connector 2 Case body 2a Lower surface of case body 21 Front wall part of case body 22 Side wall part of case body 29 Internal space 3 First insertion tube part L3 Axial direction of first insertion tube part 4 Second insertion tube Part L4 Axial direction of the second insertion cylinder part 71 First drain hose 72 Second drain hose 8 Wastewater treatment member A Floor surface B Wastewater treatment structure

Claims (4)

A drain hose connector attached to a belt-shaped wastewater treatment member laid on the floor,
a case body having a tubular portion into which a drain hose can be inserted;
The case body has a front wall portion in which the water passage is opened, and left and right side wall portions connected to both sides of the front wall portion, and the front wall portion is provided inside the case body. and an internal space defined by the side wall portions and facing the water flow port is formed,
The cylindrical portion has a first insertion cylindrical portion into which the first drain hose can be inserted along the axial direction thereof, and a second insertion cylindrical portion into which the second drain hose can be inserted, and the first insertion a cylindrical portion is positioned in front of the second insertion cylindrical portion, and the first insertion cylindrical portion and the second insertion cylindrical portion are arranged side by side in the front-rear direction;
The drain hose connector, wherein the angle of the axial direction of the first insertion cylinder with respect to the lower surface of the case body is larger than the angle of the axial direction of the second insertion cylinder with respect to the lower surface of the case body. The case body has a partition wall,
The drain hose connector according to claim 1 , wherein the partition wall portion is provided between the first insertion tubular portion and the second insertion tubular portion to partition the first insertion tubular portion and the second insertion tubular portion . 3. The first insertion cylinder part and the second insertion cylinder part are formed so that the axial direction of the first insertion cylinder part and the axial direction of the second insertion cylinder part intersect in the internal space. 3. The drain hose connector according to 1 or 2. The inclination angle of the first insertion cylinder with respect to the lower surface in the axial direction is 60 degrees to 85 degrees, and the inclination angle of the second insertion cylinder with respect to the lower surface in the axial direction is 10 degrees to 30 degrees. A drain hose fitting according to any one of claims 1 to 3.

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