JP6736191B1 - Hose fitting - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hose connecting tool capable of suppressing damage to a faucet and easily grasping a mounting method. A hose connector (10) includes a main body (100), a slide body (200), a slide mechanism that allows the slide body (200) to slide, and a regulation mechanism that regulates the rearward slide movement of the slide body (200). have. The main body portion 100 has a water discharge pipe inserting portion 104 having a packing 108 and a hose connecting portion 106. The slide body 200 has a contact pressing portion 222 that contacts the water discharge pipe f3 from above. The main body section 100 may have a slide operation section 110 that pushes the slide body 100 forward by an operation and constitutes the regulation mechanism. The slide body 100 may have a front opening 214 configured to receive a part of the water discharge pipe f3 that extends in a curved manner as the slide body 100 moves forward. [Selection diagram] Figure 1

Description

The present disclosure relates to hose fittings.

As a hose connector for connecting a hose to a faucet, there is known a type in which a plurality of screws dispersed in the circumferential direction are tightened and fixed to the faucet. In this type, it takes time and effort to evenly tighten the plurality of screws. On the other hand, Japanese Patent Laid-Open No. 6-265060 discloses a fixture for a faucet joint fixed to a faucet with a ring-shaped tightening fitting and one fixing screw. Further, Japanese Patent Application Laid-Open No. 2017-219190 discloses a hose connector that allows a bent and extending discharge pipe to be sandwiched by pressing one of the slide body and the main body against the other.

JP-A-6-265060 JP, 2017-219190, A

In the fixture disclosed in JP-A-6-265060, the faucet is easily damaged because the tip of the screw hits the faucet. In the hose connector of JP-A-2017-219190, one-touch connection is possible, and it is easy to fix it to the faucet. On the other hand, in this hose connector, the slide body and the main body are separated. Therefore, some users may be confused about the attachment method at the beginning of use.

The present disclosure provides a hose connector that can suppress damage to a faucet and can easily grasp a mounting method.

In one aspect, the hose connector includes a main body portion, a slide body capable of sliding forward of a faucet approaching a water discharge pipe and rearward away from the water discharge pipe, and a slide mechanism enabling the slide movement. A regulating mechanism for regulating the rearward sliding movement of the slide body. The main body portion has a water discharge pipe inserting portion having a packing and a hose connecting portion. The slide body has a contact pressing portion that contacts the water discharge pipe from above.

In one aspect, it is possible to provide a hose connector that can prevent the faucet from being damaged and can easily grasp a mounting method.

FIG. 1 is a perspective view showing a connected state in which the hose connector according to the first embodiment is attached to a faucet. FIG. 2 is a front view of FIG. FIG. 3 is a cross-sectional view taken along the line AA of FIG. FIG. 3 shows a central cross section including the center line of the water discharge pipe. FIG. 4 is a perspective view of the water faucet and the hose connector of the first embodiment. FIG. 5 is an exploded perspective view of the hose connector shown in FIG. 6A is a perspective view of the first member according to the first embodiment as viewed obliquely from above, and FIG. 6B is a perspective view of the first member as viewed from obliquely below. 6C is a plan view of the first member, FIG. 6D is a front view of the first member, and FIG. 6E is a cross section taken along line AA of FIG. 6D. It is a figure. FIG. 7A is a perspective view of the slide body according to the first embodiment as seen obliquely from above, and FIG. 7B is a perspective view of this slide body as seen from obliquely below, and FIG. ) Is a bottom view of this slide body, FIG.7(d) is a front view of this slide body, FIG.7(e) is sectional drawing along the AA line of FIG.7(d). FIG. 8 is a perspective view showing a connected state in which the hose connector according to the second embodiment is attached to the faucet. FIG. 9 is a front view of FIG. FIG. 10 is a sectional view taken along the line AA of FIG. FIG. 19 shows a central cross section including the center line of the water discharge pipe. FIG. 11 is a perspective view of the water faucet and the hose connector of the second embodiment. FIG. 12 is an exploded perspective view of the hose connector shown in FIG. 11. FIG. 13A is a perspective view of the first member according to the second embodiment as viewed obliquely from above, and FIG. 13B is a perspective view of the first member as viewed obliquely from below. 13C is a plan view of the first member, FIG. 13D is a front view of the first member, and FIG. 13E is a cross section taken along line AA of FIG. 13D. It is a figure. FIG. 14A is a perspective view of the annular slide body according to the second embodiment as seen obliquely from above, and FIG. 14B is a perspective view of the annular slide body as seen from obliquely below. 14C is a plan view of the annular slide body, FIG. 14D is a front view of the annular slide body, and FIG. 14E is a cross section taken along line AA of FIG. 14D. It is a figure. FIG. 15A is a perspective view of the slide body according to the second embodiment as seen obliquely from above, and FIG. 15B is a perspective view of the slide body as seen from obliquely below, and FIG. ) Is a bottom view of this slide body, FIG.15(d) is a front view of this slide body, FIG.15(e) is sectional drawing along the AA line of FIG.15(d). FIG. 16 is a sectional view in which a part of FIG. 3 is enlarged. 17A is a sectional view of the first member according to the first embodiment, and FIG. 17B is a sectional view of the first member according to the second embodiment and the annular slide body attached to the first member. It is a figure. FIG. 18A is a cross-sectional view showing a slide body that tilts backward when inserting the water discharge pipe f3 into the water discharge pipe inserting portion, and FIG. 18B is a cross-sectional view showing a slide body that tilts forward in the connected state. is there. FIG. 19 is a cross-sectional view in which a part of FIG. 3 is enlarged, showing a water discharge pipe outer circumference circle and a water discharge pipe inner circumference circle. FIG. 20 is an enlarged cross-sectional view showing the hose connector of the third embodiment. FIG. 21 is an enlarged sectional view showing the hose connector of the fourth embodiment. FIG. 22 is a perspective view showing a connected state in which the hose connector according to the fifth embodiment is attached to the faucet. 23 is a cross-sectional view of FIG. FIG. 24 is a sectional view of the second member in the hose connector of the fifth embodiment. FIG. 25 is a perspective view showing a connected state in which the hose connector according to the sixth embodiment is attached to the faucet. FIG. 26 is a plan view of the hose connector of FIG. 25 as seen from above. 27 is a sectional view taken along the line AA of FIG. FIG. 27 shows a central cross section including the center line of the water discharge pipe. FIG. 28 is a perspective view of the water faucet and the hose connector of the sixth embodiment. FIG. 29 is an exploded perspective view of the hose connector shown in FIG. 28. 30A is a perspective view of the first member according to the sixth embodiment as seen obliquely from above, and FIG. 30B is a perspective view of the first member as seen from another angle. FIG. 30C is a plan view of this first member, and FIG. 30D is a side view of this first member. 31A and 31B are partially enlarged views of the plan view of the sixth embodiment. FIG. 32 is a perspective view showing a connected state in which the hose connector according to the seventh embodiment is attached to the faucet. 33 is a plan view of the hose connector of FIG. 32 as viewed from above. 34 is a sectional view taken along the line AA of FIG. FIG. 34 shows a central cross section including the center line of the water discharge pipe. FIG. 35 is a perspective view of the water faucet and the hose connector of the seventh embodiment. FIG. 36 is an exploded perspective view of the hose connector shown in FIG. 35. FIG. 37(a) is a perspective view of the slide body according to the seventh embodiment as seen obliquely from above, and FIG. 37(b) is a perspective view of the slide body as seen from another angle. ) Is a rear view of the slide body, and FIG. 37D is a front view of the slide body. FIG. 38 is a perspective view showing a connected state in which the hose connector according to the eighth embodiment is attached to the faucet. FIG. 39 is a perspective view showing a connected state in which the hose connector according to the ninth embodiment is attached to the faucet.

Hereinafter, the present invention will be described in detail based on preferred embodiments with reference to the drawings as appropriate.

In the present application, terms such as “upper”, “upper”, “lower”, “lower”, “up and down”, etc. are used based on a typical faucet posture. If the faucet pose is not typical, these phrases are interpreted in line with the pose. In addition, the vertical relationship of the hose connector is determined in the reference state described later, unless otherwise specified.

[First Embodiment]
FIG. 1 is a perspective view of a water faucet f1 to which a hose connector 10 according to the first embodiment is attached. 2 is a front view of the faucet f1 with the hose connector 10 of FIG. 1, and FIG. 3 is a sectional view taken along the line AA of FIG. FIG. 4 is a perspective view showing a state in which the hose connector 10 and the faucet f1 are separated, and FIG. 5 is an exploded perspective view of the hose connector 10. 1 to 3 show a state (connection state) in which the hose connector 10 is connected to the faucet f1. In this connected state, the slide body 200 is in contact with the water discharge pipe f3 (bent portion f5) from above. In the connected state of the hose connector 10, the slide operation part 110 (screw member) is tightened, and the hose connector 10 is fixed to the faucet f1.

The faucet f1 has a faucet body f2, a water discharge pipe f3, and a handle f4. The water discharge pipe f3 is connected to the faucet body f2. The water that has passed through the faucet body f2 is discharged through the water discharge pipe f3. A valve (not shown) is built in the faucet f1. This valve is opened and closed by operating (rotating) the handle f4. By operating the handle f4, the discharge water is switched and the water discharge amount is adjusted.

In the present embodiment, the water faucet f1 has a water discharge pipe f3 fixed to a water faucet body f2. Those skilled in the art will refer to this faucet f1 as a horizontal faucet. This designation is defined by JIS B 2061. In addition, in this faucet f1, the boundary between the faucet body f2 and the water discharge pipe f3 is not necessarily clear, but a portion on the downstream side of the valve may be regarded as the water discharge pipe f3. Further, a portion having a constant thickness (outer diameter) may be regarded as the water discharge pipe f3.

Examples of the faucet f1 that can be used by the hose connector 10 include a lateral faucet, a lateral faucet (water outlet rotation type), and a lateral faucet (flexible type). These designations are also defined by JIS B 2061. The horizontal faucet (rotating spout) is also called a universal home faucet. The horizontal faucet (flexible type) is also called a universal faucet.

At least a part of the water discharge pipe f3 is bent and extends. That is, the water discharge pipe f3 has a bent portion f5. Further, the water discharge pipe f3 has a water discharge port f6. Water is discharged from the water discharge port f6. The water discharge pipe f3 extends from the faucet body f2 and terminates at a water discharge port f6. The bent portion f5 is bent so that the water discharge port f6 faces downward.

As well shown in FIG. 5, the hose connector 10 has a main body 100 and a slide body 200. The slide body 200 is attached to the main body 100 in a state of being able to slide.

The slide body 200 as a whole has a structure in which the front portion and the lower portion of the hollow member are omitted. That is, the hollow portion of the slide body 200 is opened forward and downward. Details of the slide body 200 will be described later.

As shown in FIG. 3, the main body 100 has a slide body placement portion 102, a water discharge pipe insertion portion 104, a hose connection portion 106, packing 108, and a slide operation portion 110. As shown in FIG. 5, the main body 100 has a packing 108, a first member 112, a second member 114, and a slide operation unit 110 from the viewpoint of components.

As shown in FIG. 3, the first member 112 and the second member 114 are joined by a screw mechanism while sandwiching the packing 108. The first member 112 and the second member 114 that are joined together constitute the water discharge pipe insertion portion 104 having a cavity inside. The water discharge pipe insertion portion 104 has an upper opening, and the water discharge pipe f3 is inserted into the water discharge pipe insertion portion 104 from the upper opening. The slide body placement portion 102 is formed above the first member 112. The slide body placement portion 102 is formed on the upper portion of the main body portion 100. The hose connecting portion 106 is formed below the second member 114. The hose connecting portion 106 is formed in the lower portion of the main body portion 100. A hose (not shown) is connected to the hose connection portion 106. An annular seal member (O-ring or the like) is attached to the circumferential groove 107 of the hose connecting portion 106. Illustration of this annular seal member is omitted (see FIG. 3 ).

The main body section 100 has a pressing support section 120 that supports the slide operation section 110. When the slide operation unit 110 presses the slide body 200, a reaction force of this pressing force is generated. The press support portion 120 receives this reaction force.

As shown in FIG. 3, in the present embodiment, the operation support portion 120 is a wall portion. The press support portion 120 is a part of the first member 112. A screw hole 122 is formed in the operation support portion 120. In this embodiment, the slide operation part 110 is a screw member. The slide operation part 110 has a shaft part 124 and a head part 126. A male screw portion is formed on the shaft portion 124. The male screw portion is screwed into the screw hole 122 (screw coupling). The head 126 has a shape that allows the user to easily rotate it. When the slide operating portion 110 is rotated in the first direction (tightening direction), the slide operating portion 110 moves forward with respect to the pressing support portion 120 (slide body arranging portion 102). By this movement, the slide operation unit 110 presses the slide body 200 and moves the slide body 200 forward. When the slide operating part 110 is rotated in the second direction (loosening direction) opposite to the first direction, the slide operating part 110 moves backward. To achieve the connected state, the slide body 200 is moved forward until the slide body 200 contacts the water discharge pipe f3.

In the present embodiment, the slide operation part 110 is a screw member. The screw member presses the slide body 200 by being screwed in and moving forward. The screw mechanism having the screw member does not move unless it is rotated, and therefore includes a restricting mechanism that restricts the backward sliding movement of the slide body 200. The mechanism of the slide operation portion is not limited to the screw mechanism, and for example, a ratchet mechanism can be adopted. The toggle mechanism may be combined with the ratchet mechanism.

In addition, in the present application, the front means a direction in which the slide body 200 slides and approaches the water discharge pipe f3. In the present application, “rearward” means a direction away from the water discharge pipe f3 when the slide body 200 slides. In FIG. 3, the front D1 and the rear D2 are indicated by arrows.

As shown in FIG. 5, the packing 108 is an annular member. As shown in FIG. 3, the packing 108 has a base portion 130 and an inwardly extending portion 132. The base 130 is annular. The inward extension 132 is annular. Since the base 130 is sandwiched between the first member 112 and the second member 114, the packing 108 is fixed to the main body 100. In the connected state, the water discharge pipe f3 is inserted into the water discharge pipe insertion portion 104 from above. The water discharge pipe f3 passes through the packing 108 and reaches the water discharge pipe insertion portion 104. The inwardly extending portion 132 of the packing 108 is in close contact with the outer surface of the water discharge pipe f3. The packing 108 ensures the sealing property.

The main body part 100 has a lower contact part 134 that can contact the faucet f1 from below in the connected state. The lower contact portion 134 is formed on the first member 112. As shown in FIG. 3, the lower contact portion 134 contacts the faucet body f2 from below in the connected state.

As shown in FIG. 4, the hose connector 10 is not separated as a whole. The method of attaching the hose connector 10 to the faucet f1 can be easily understood. The user can intuitively understand how to attach the hose connector 10.

In attaching the hose connector 10 to the faucet f1, first, the water discharge pipe f3 is inserted into the water discharge pipe insertion portion 104 from above. Next, the slide operation unit 110 is operated (rotated) to slide the slide body 200 forward D1. This operation is continued until the slide body 200 contacts the water discharge pipe f3. The contact state of the slide body 200 with the water discharge pipe f3 achieves the connected state. In this way, the hose connector 10 can be easily attached.

FIG. 6A is a perspective view of the first member 112 as seen obliquely from above. FIG. 6B is a perspective view of the first member 112 as seen obliquely from below. FIG. 6C is a plan view of the first member 112. FIG. 6D is a front view of the first member 112. FIG. 6E is a cross-sectional view taken along the line AA of FIG.

As described above, the first member 112 (main body portion 100) has the slide body placement portion 102. The first member 112 has the lower contact portion 134 described above. The first member 112 has an upper opening 140 of the water discharge pipe insertion portion 104. The first member 112 has a female screw portion 142 that can be screwed into the second member 114. The 1st member 112 comprises the outer wall of the water discharge pipe insertion part 104 (refer FIG. 3).

The slide body placement portion 102 has the above-described pressing support portion 120 and screw hole 122. Further, the slide body placement portion 102 has a slide bottom surface 144 and a wall portion 146 extending upward from the slide bottom surface 144. The slide bottom surface 144 is a flat surface. The slide bottom surface 144 extends between the upper opening 140 and the wall portion 146. The wall portions 146 are provided behind, on the right side and on the left side of the slide bottom surface 144. A portion of the wall portion 146, which is behind the slide bottom surface 144, constitutes the pressing support portion 120. At the front D1 of the slide bottom surface 144, the wall portion 146 is interrupted. A wall portion missing portion 147 is formed in the front D1 of the slide bottom surface 144. Due to the wall missing portion 147, the slide body placement portion 102 is open toward the front D1. The slide body placement portion 102 is open toward the front D1 and upward.

The slide body placement portion 102 has a first slide engagement portion 148. The first slide engagement portions 148 are arranged dispersedly on the left and right. The first slide engagement portion 148 has a left engagement portion 148a and a right engagement portion 148b.

A protrusion 150 a and a protrusion 150 b are provided on the inner surface of the wall 146. The protrusion 150a and the protrusion 150b have the same vertical position.

The protruding portion 150 a extends in parallel with the slide bottom surface 144 at a position above the slide bottom surface 144. The protrusion 150a is a ridge extending in the sliding direction (front-back direction). A slide groove is formed by the protrusion 150a and the slide bottom surface 144. That is, the left engagement portion 148a is a slide groove formed between the protrusion 150a and the slide bottom surface 144. The protruding portion 150b extends in parallel with the slide bottom surface 144 at a position above the slide bottom surface 144. The protrusion 150b is a protrusion that extends in the sliding direction (front-back direction). A slide groove is formed by the protrusion 150b and the slide bottom surface 144. That is, the right engaging portion 148b is a slide groove formed between the protruding portion 150b and the slide bottom surface 144. As described above, in the present embodiment, the first slide engagement portion 148 included in the main body portion 100 is a slide groove.

FIG. 7A is a perspective view of the slide body 200 as viewed obliquely from above. FIG. 7B is a perspective view of the slide body 200 as viewed obliquely from below. FIG. 7C is a bottom view of the slide body 200. FIG. 7D is a front view of the slide body 200. FIG. 7E is a cross-sectional view taken along the line AA of FIG. 7D.

The slide body 200 includes an upper forming portion 202 and a lower extending portion 204 extending downward from the upper forming portion 202. The downward extending portion 204 has a lower end surface 206, a left wall portion 208, a right wall portion 210, and a rear wall portion 212. The downward extending portion 204 has a missing front portion. In other words, the downward extension 204 has a front opening 214. As a result, the slide body 200 is open toward the front D1. The slide body 200 does not have a bottom. The slide body 200 is open downward. The slide body 200 is open toward the front D1 and downward.

The slide body 200 has a pressed portion 218. The pressed portion 218 is the outer surface of the rear wall portion 212. The front end of the slide operation part 110 contacts the pressed part 218. In the present embodiment, the tip of the shaft portion 124 of the slide operation portion 110 contacts the pressed portion 218. The pressed part 218 is pressed by the slide operation part 110. By this pressing, the slide body 200 moves to the front D1.

The slide body 200 has a second slide engagement portion 220. The second slide engagement portions 220 are arranged so as to be dispersed on the left and right. The second slide engagement portion 220 has a left engagement portion 220a and a right engagement portion 220b. The left engagement portion 220a is provided on the outer surface of the left wall portion 208. The left engagement portion 220a constitutes a slide protrusion. The slide protrusion 220a is a ridge portion extending in the slide direction (front-back direction). The right engagement portion 220b is provided on the outer surface of the right wall portion 210. The right engaging portion 220b constitutes a slide protrusion. The slide protrusion 220b is a protrusion that extends in the slide direction (front-back direction). As described above, in the present embodiment, the second slide engagement portion 220 included in the slide body 200 is a slide protrusion.

The first slide engagement portion 148 and the second slide engagement portion 220 form a slide mechanism that allows the slide body 200 to slide. The left engaging portion (slide groove) 148a is slidably engaged with the left engaging portion (slide protrusion) 220a. A right engaging portion (slide protrusion) 220b is slidably engaged with the right engaging portion (slide groove) 148b. This slide mechanism allows the slide body 200 to move with respect to the main body section 100 (slide body arranging section 102).

The slide body 200 is mounted on the slide bottom surface 144 of the slide body placement portion 102 while achieving the engagement between the first slide engagement portion 148 and the second slide engagement portion 220. Due to the gravity acting on the slide body 200, the lower end surface 206 of the slide body 200 is in contact with the slide bottom surface 144. When the slide body 200 slides, the lower end surface 206 slides on the slide bottom surface 144.

The slide body 200 has a contact pressing portion 222. The contact pressing portion 222 is a protruding portion that protrudes downward. The contact pressing portion 222 projects downward from the upper forming portion 202. The contact pressing portion 222 projects downward inside the slide body 200. In the connected state, the contact pressing portion 222 contacts the water discharge pipe f3 from above. Details of the contact presser 222 will be described later.

[Second Embodiment]
FIG. 8 is a perspective view of the faucet f1 to which the hose connector 20 according to the second embodiment is attached. 9 is a front view of the faucet f1 with the hose connector 20 of FIG. 8, and FIG. 10 is a cross-sectional view taken along the line AA of FIG. FIG. 11 is a perspective view showing a state where the hose connector 20 and the faucet f1 are separated, and FIG. 12 is an exploded perspective view of the hose connector 20. 8 to 10 show a state (connection state) in which the hose connector 20 is connected to the faucet f1.

The faucet f1 has a faucet body f2, a water discharge pipe f3, and a handle f4. The water discharge pipe f3 is connected to the faucet body f2. The water that has passed through the faucet body f2 is discharged through the water discharge pipe f3. A valve (not shown) is built in the faucet f1. This valve is opened and closed by operating (rotating) the handle f4. By operating the handle f4, the discharge water is switched and the water discharge amount is adjusted. The faucet f1 is as described in the first embodiment.

As shown in FIG. 12, the hose connector 20 has a main body 300, a slide body 400, and a slide fastener. The slide body 400 is attached to the main body section 300 in a slidable manner.

The slide body 400 as a whole has a structure in which the front portion and the lower portion of the hollow member are omitted. Details of the slide body 400 will be described later.

As shown in FIG. 10, the main body 300 includes a slide body placement portion 302, a water discharge pipe insertion portion 304, a hose connection portion 306, packing 308, a slide operation portion 310, and an annular slide body 318. As shown in FIG. 12, the main body 300 includes a packing 308, a first member 312, a second member 314, a slide operation unit 310, and an annular slide body 318 from the viewpoint of components.

As shown in FIG. 10, the first member 312 and the second member 314 are coupled by a screw mechanism while sandwiching the packing 308. The combined first member 312 and second member 314 form a water discharge pipe insertion portion 304 having a cavity inside. The water discharge pipe insertion portion 304 has an upper opening, and the water discharge pipe f3 is inserted into the water discharge pipe insertion portion 304 through the upper opening. The slide body placement portion 302 is formed on the first member 312. The slide body placement portion 302 is formed on the upper portion of the main body portion 300. The hose connection portion 306 is formed on the lower portion of the second member 314. The hose connecting portion 306 is formed on the lower portion of the main body portion 300. A hose (not shown) is connected to the hose connection portion 306. An annular seal member (O-ring or the like) is attached to the circumferential groove 307 of the hose connecting portion 306, but the annular seal member is not shown (see FIG. 10).

The main body section 300 has a pressing support section 320 that supports the slide operation section 310. When the slide operation unit 310 presses the slide body 400, a reaction force of this pressing force is generated. The pressing support 320 receives this reaction force.

The annular slide body 318 is a member that does not exist in the hose connector 10 of the first embodiment. The annular slide body 318 is an annular member as a whole. In the connected state, the water discharge pipe f3 is inserted through the annular slide body 318. Details of the structure and function of the annular slide body 318 will be described later.

As shown in FIGS. 10 and 12, in the present embodiment, the operation support portion 320 is provided on the annular slide body 318. A screw hole 322 is formed in the operation supporting portion 320 (annular slide body 318). In this embodiment, the slide operation part 310 is a screw member. The slide operation part 310 has a male screw part 324 and a head part 326. The male screw portion 324 is screwed (screwed) into the screw hole 322. The head 326 has a shape that allows the user to easily rotate it. When the slide operating portion 310 is rotated in the first direction (tightening direction), the slide operating portion 310 moves forward D1 with respect to the pressing support portion 320 (annular slide body 318). In other words, the annular slide body 318 moves rearward D2 with respect to the slide operation part 310. By these movements, the slide operation unit 310 presses the slide body 200, and at the same time, the annular slide body 318 is pulled toward the rear D2. As a result, the water discharge pipe f3 is sandwiched between the slide body 400 and the front portion 362 (described later) of the annular slide body 318, and the connected state is achieved.

The structure and function of the packing 308 are the same as those of the packing 108 described above.

As shown in FIG. 11, the hose connector 20 is not separated as a whole. The method of attaching the hose connector 20 to the faucet f1 can be easily understood. The user can intuitively understand how to attach the hose connector 20.

In the attachment of the hose connector 20 to the faucet f1, first, the water discharge pipe f3 is inserted into the water discharge pipe insertion portion 304 from above while being inserted into the annular slide body 318. Next, the slide operation unit 310 is operated (rotated) to slide the slide body 400 forward. This operation is continued until the slide body 400 contacts the water discharge pipe f3. The contact state of the slide body 400 with the water discharge pipe f3 achieves the connected state. In this way, the hose connector 20 can be easily attached.

FIG. 13A is a perspective view of the first member 312 as seen obliquely from above. FIG. 13B is a perspective view of the first member 312 as seen obliquely from the lower side. FIG. 13C is a plan view of the first member 312. FIG. 13D is a front view of the first member 312. FIG. 13E is a cross-sectional view taken along the line AA of FIG.

As described above, the first member 312 (main body portion 300) has the slide body placement portion 302. The first member 312 has an upper opening 340 of the water discharge pipe insertion portion 304. The first member 312 has a female screw portion 342 that can be screwed with the second member 314. The 1st member 312 comprises the outer wall of the water discharge pipe insertion part 304 (refer FIG. 10).

The slide body placement portion 302 has a slide mounting surface 344 and a wall portion 346 extending upward from the slide mounting surface 344. The slide mounting surface 344 is a flat surface. The slide mounting surface 344 extends between the upper opening 340 and the wall portion 346. The wall portions 346 are provided on the right and left sides of the slide mounting surface 344. The wall portion 346 is interrupted in front of and behind the slide bottom surface 144. A wall missing portion 345 is formed behind the slide mounting surface 344. Due to the wall portion missing portion 345, the slide body placement portion 302 is opened rearward. A wall missing portion 347 is formed in front of the slide mounting surface 344. Due to the wall missing portion 347, the slide body placement portion 302 is open toward the front. The slide body placement portion 302 is open toward the front, the rear, and the top.

The slide body placement portion 302 has a first slide engagement portion 348. The first slide engagement portions 348 are arranged so as to be dispersed on the left and right. The first slide engagement portion 348 has a left engagement portion 348a and a right engagement portion 348b. The left engaging portion 348a is a slide groove. The slide groove 348a extends in the slide direction (front-rear direction). The slide groove 348a is provided on the inner surface of the wall portion 346. The slide groove 348 a extends parallel to the slide mounting surface 344 at a position above the slide mounting surface 344. The right engaging portion 348b is a slide groove. The slide groove 348b extends in the slide direction (front-back direction). The slide groove 348b is provided on the inner surface of the wall portion 346. The slide groove 348 b extends parallel to the slide mounting surface 344 at a position above the slide mounting surface 344. The slide groove 348a and the slide groove 348b have the same vertical position. As described above, the first slide engaging portion 348 of the main body 300 is a slide groove.

FIG. 14A is a perspective view of the annular slide body 318 as seen from the diagonally upper side. FIG. 14B is a perspective view of the annular slide body 318 as seen from the diagonally lower side. FIG. 14C is a plan view of the annular slide body 318 seen from above. FIG. 14D is a front view of the annular slide body 318. FIG. 14E is a cross-sectional view taken along the line AA of FIG.

The annular slide body 318 is an annular member as a whole. The annular slide body 318 has a water discharge pipe insertion hole 360, a front portion 362, a rear portion 364, a left side portion 366, and a right side portion 368. The water discharge pipe insertion hole 360 is a through hole. In the connected state, the water discharge pipe f3 is inserted through the water discharge pipe insertion hole 360 (see FIG. 10). In the connected state, the water discharge pipe insertion hole 360 penetrates the annular slide body 318 in the vertical direction. The front portion 362 is located in front of the water discharge pipe insertion hole 360. The rear part 364 is located behind the water discharge pipe insertion hole 360. The left side portion 366 is located on the left side of the water discharge pipe insertion hole 360. The right side portion 368 is located on the right side of the water discharge pipe insertion hole 360.

The annular slide body 318 has a slide upper surface 370. The slide upper surface 370 is formed around the water discharge pipe insertion hole 360. The upper surfaces of the left side portion 366 and the right side portion 368 are slide upper surfaces 370. A portion of the rear portion 364 near the left side portion 366 also constitutes the slide upper surface 370. The slide upper surface 370 is a flat surface.

The rear portion 364 has the above-described pressing support portion 320. The rear portion 364 has a rear standing portion 372. The rear standing portion 372 has a pressing support portion 320. As described above, the pressing support 320 has the screw hole 322.

The front part 362 has a lower contact part 374 that can contact the faucet f1 from below in the connected state. As shown in FIG. 3, the lower contact portion 374 is in contact with the faucet body f2 and/or the water discharge pipe f3 from below. Further, the front portion 362 has a back contact portion 376 that can contact the faucet f1 from the rear in the connected state. The lower contact portion 374 may be the rear contact portion 376. In the present embodiment, the front portion 362 is the lower contact portion 374 and also the back contact portion 376. In the front portion 362, the position of the lower contact portion 374 and the position of the back contact portion 376 may be the same or may be different.

FIG. 15A is a perspective view of the slide body 400 as viewed from diagonally above. FIG. 15B is a perspective view of the slide body 400 as viewed obliquely from below. FIG. 15C is a bottom view of the slide body 400 as viewed from below. FIG. 15D is a front view of the slide body 400. FIG. 15E is a cross-sectional view taken along the line AA of FIG.

The slide body 400 has an upper forming portion 402 and a lower extending portion 404 extending downward from the upper forming portion 402. The downward extending portion 404 has a lower end surface 406, a left wall portion 408, a right wall portion 410, and a rear wall portion 412. A front portion of the downward extending portion 404 is missing. In other words, the downward extension 404 has a front opening 414. As a result, the slide body 400 is open toward the front. The slide body 400 does not have a bottom. The slide body 400 is open downward. The slide body 400 is open forward and downward.

The slide body 400 has a pressed portion 418. The pressed portion 418 is the outer surface of the rear wall portion 412. The front end of the slide operation part 310 contacts the pressed part 418. In the present embodiment, the tip of the male screw part 324 of the slide operation part 310 contacts the pressed part 418. The pressed portion 418 is pressed by the slide operation portion 310. By this pressing, the slide body 400 moves forward.

The slide body 400 has a second slide engagement portion 420. The second slide engagement portion 420 is a slide protrusion. The second slide engagement portions 420 are arranged so as to be dispersed on the left and right. The second slide engagement portion 420 has a left engagement portion 420a and a right engagement portion 420b. The left engagement portion 420a is provided on the outer surface of the left wall portion 408. The left engagement portion 420a constitutes a slide protrusion. The slide protrusion 420a is a protrusion having a circular cross section. The right engagement portion 420b is provided on the outer surface of the right wall portion 410. The right engaging portion 420b constitutes a slide protrusion. The slide protrusion 420b is a protrusion having a circular cross section. As described above, in the present embodiment, the second slide engagement portion 420 included in the slide body 400 is a slide protrusion.

The slide body 400 has a contact pressing portion 422. The contact pressing portion 422 is a protruding portion that protrudes downward inside the slide body 400. In the connected state, the contact pressing portion 422 contacts the water discharge pipe f3 from above. Details of the contact pressing portion 422 will be described later.

The first slide engagement portion 348 and the second slide engagement portion 420 form a slide mechanism that allows the slide body 400 to slide. The slide protrusion 420a is engaged with the slide groove 348a. The slide protrusion 420b is engaged with the slide groove 348b. This slide mechanism allows the slide body 400 to move with respect to the main body section 300 (slide body arranging section 302).

In the second embodiment, unlike the first embodiment, an annular slide body 318 is provided. The hose connector 20 of the second embodiment has a sub-slide mechanism that allows the annular slide body 318 to slide.

As shown in FIG. 13D, the slide body placement portion 302 has a third slide engagement portion 380 in addition to the above-described first slide engagement portion 348. The third slide engagement portion 380 is a slide groove. The third slide engagement portions 380 are arranged so as to be dispersed on the left and right. The third slide engagement portion 380 has a left engagement portion 380a and a right engagement portion 380b. The left engaging portion 380a is a slide groove. The slide groove 380a extends in the slide direction (front-rear direction). The slide groove 380a is provided on the inner surface of the wall portion 346. The slide groove 380 a extends parallel to the slide mounting surface 344 at a position above the slide mounting surface 344. The right engaging portion 380b is a slide groove. The slide groove 380b extends in the slide direction (front-back direction). The slide groove 380b is provided on the inner surface of the wall portion 346. The slide groove 380b extends parallel to the slide mounting surface 344 at a position above the slide mounting surface 344. The slide groove 380a and the slide groove 380b have the same vertical position.

The third slide engagement portion 380 is located below the first slide engagement portion 348. As well shown in FIGS. 13D and 13E, the third slide engaging portion 380 (slide grooves 380a, 380b) is located below the first slide engaging portion 348 (slide grooves 348a, 348b). It is located in.

As shown in FIGS. 14A to 14E, the annular slide body 318 has a fourth slide engagement portion 330. The fourth slide engagement portions 330 are arranged so as to be dispersed on the left and right. The fourth slide engagement portion 330 has a left engagement portion 330a and a right engagement portion 330b. The left engagement portion 330a is formed by the outer edge portion of the left side portion 366. The left engaging portion 330a constitutes a slide protrusion. The slide protrusion 330a constitutes a ridge portion extending in the slide direction. The right engaging portion 330b is formed by the outer edge portion of the right side portion 368. The right engaging portion 330b constitutes a slide protrusion. The slide protrusion 330b constitutes a ridge portion extending in the slide direction.

The third slide engagement portion 380 and the fourth slide engagement portion 330 form a sub-slide mechanism that allows the annular slide body 318 to slide. The left engaging portion 330a (slide projection) is slidably engaged with the left engaging portion 380a (slide groove). The right engaging portion 330b (slide protrusion) is slidably engaged with the right engaging portion 380b (slide groove). With this slide mechanism, the annular slide body 318 can move with respect to the main body section 300 (slide body arranging section 302).

As shown in FIGS. 10 and 11, the slide body 400 is placed on the annular slide body 318. The annular slide body 318 is placed on the slide mounting surface 344 of the slide body placement portion 302, and the slide body 400 is placed on the annular slide body 318. The lower end surface 406 of the slide body 400 is in contact with the slide upper surface 370 of the annular slide body 318. When the annular slide body 318 slides, the annular slide body 318 slides on the slide mounting surface 344. The direction of slide movement of the annular slide body 318 is the front-back direction. In the slide movement of the slide body 400, the slide body 400 slides on the slide upper surface 370 of the annular slide body 318. The sliding movement direction of the slide body 400 is the front-back direction. Since the slide upper surface 370 is the surface on which the slide body 400 is placed, it is also the slide bottom surface.

Since the slide body 400 is placed on the annular slide body 318, when the annular slide body 318 moves, the slide body 400 also moves with the annular slide body 318. However, since the slide body 400 can move with respect to the annular slide body 318, the movement in the front-rear direction is independent between the annular slide body 318 and the slide body 400.

In the connected state, the position of the slide body 400 is determined by the contact with the water discharge pipe f3. When the position of the slide body 400 is determined, the position of the slide operation unit 310 that presses the slide body 400 is also determined. On the other hand, the position of the annular slide body 318 is determined by the contact between the front portion 362 and the faucet f1. By operating (rotating) the slide operating part 310, the position of the annular slide body 318 with respect to the slide operating part 310 changes. By rotating the slide operation part 310 in the first direction (tightening direction), the slide body 400 is pressed forward D1 and pressed against the water discharge pipe f3, and at the same time, the annular slide body 318 is drawn rearward D2 and is moved forward. The portion 362 is pressed against the faucet f1 (water discharge pipe f3). As a result, the water discharge pipe f3 is sandwiched between the front portion 362 and the slide body 400, and the hose connector 20 is fixed to the water faucet f1. The front portion 362 of the annular slide body 318 has two protrusions 384 (see FIG. 14C). The protrusion 384 projects toward the center side of the water discharge pipe insertion hole 360. It is these protrusions 384 that are in contact with the faucet f1 (water discharge pipe f3) in the front portion 362.

Examples of the hose connector according to the present application include the hose connector 10 and the hose connector 20 described above. In any of the embodiments, the slide operation portion (screw member) is in contact with the slide body and does not contact with the faucet f1. Therefore, the faucet f1 is not damaged by the slide operating portion (screw member or the like).

The hose connector according to the present application may have the following configurations.

[Abutting retainer that abuts from above]
It is preferable that the slide body has a contact pressing portion that abuts against the water discharge pipe f3 (bent portion f5) from above. The slide body 200 of the hose connector 10 has a contact pressing portion 222. The slide body 400 of the hose connector 20 has a contact pressing portion 422.

The contact pressing part 222 contacts the water discharge pipe f3 from above. The "contact from above" means a contact in which the force (contact force) applied to the water discharge pipe f3 by the contact has a component in the water discharge direction. The contact pressing part 222 has a downward surface. In the contact pressing portion 222, the downward surface is the lower end surface of the contact pressing portion 222 protruding downward. This downward surface contacts the water discharge pipe f3 from above.

FIG. 16 is an enlarged sectional view in which a part of FIG. 3 is enlarged. As shown in FIG. 16, the contact force F has a component F1 in the water discharge direction and a component F2 in the front direction. The contact pressing portion 222 is in contact with the water discharge pipe f3 from above. The contact pressing portion 222 is in contact with the bent portion f5 from above. The slide body 200 receives the bent portion f5 of the water discharge pipe f3 from the front opening 214 inside the slide body 200. The slide body 200 receives the convex curved surface f51 of the bent portion f5 from the front opening 214 inside the slide body 200. As a result, the contact pressing portion 222 can contact the water discharge pipe f3 (bent portion f5) from above. Further, in the process of reaching the connected state, the water discharge pipe f3 can contact the side wall portions (left wall portion 208, right wall portion 210) and the rear wall portion 212 of the slide body 200, and the posture of the slide body 200 is suitable for the connected state. Easy to adjust to the state. The same applies to the slide body 400.

The water discharge direction is the direction in which water is discharged. To be precise, the water discharge direction is defined as follows. As shown in FIG. 16, when the water discharge pipe f3 has a straight portion f7 that extends straight and reaches the water discharge port f6, the direction of the center line of the straight portion f7 is defined as the water discharge direction D3. When the water discharge pipe f3 is bent to the water discharge port f6, the direction of a straight line perpendicular to the plane including the end face f8 of the water discharge port f6 is defined as the water discharge direction D3.

As described above, the water discharge pipe f3 has the bent portion f5. The outer surface of the bent portion f5 has a convex curved surface f51 and a concave curved surface f52. The convex curved surface f51 is formed outside the bend (outer peripheral side), and the concave curved surface f52 is formed inside the bend (inner peripheral side). When the faucet f1 is viewed from the front, the concave curved surface f52 is located on the back side of the water discharge pipe f3.

The contact pressing portion 222 is in contact with the convex curved surface f51. At the position where the convex curved surface f51 abuts on the abutting pressing portion 222, the convex curved surface f51 is inclined so as to be downward as it goes rearward D2. This tilt causes a component F1 in the water discharge direction D3. When the hose connector 10 tries to come out in the water discharge direction D3 due to the water pressure, the component F1 in the water discharge direction D3 increases, and the contact pressing portion 222 has a reaction force of the same magnitude as the component F1 in the water discharge direction D3. It works in the opposite direction. Therefore, the hose connector 10 is effectively prevented from coming off.

[Shape of contact presser]
As shown in FIGS. 3, 7(b) and 7(e), in the slide body 200 of the hose connector 10, the contact pressing portion 222 includes a shape that becomes forward as it goes upward. The lower surface (lower end surface) of the contact pressing portion 222 includes a shape that becomes forward as it goes upward. As shown in FIG. 10, FIG. 15B and FIG. 15E, the contact pressing portion 422 of the slide body 400 of the hose connector 20 also includes a shape that becomes forward as it goes upward. The shape of the contact pressing portion 422 is the same as the shape of the contact pressing portion 222.

As shown in FIG. 7B, the lower surface of the contact pressing portion 222 has a stepped shape. As shown in FIG. 7E, the lower surface of the contact pressing portion 222 has a first protruding portion 222a and a second protruding portion 222b. The first protrusion 222a is located above and in front of the second protrusion 222b. The combination of the first projecting portion 222a and the second projecting portion 222b is an example of a shape that becomes forward as it goes upward. In addition, the lower surface of the contact pressing portion 222 has a slope 222c that becomes forward as it goes upward. The slope 222c is an example of a shape that becomes forward as it goes upward. As described above, as a shape that becomes forward as it goes upward, a stepped shape, a slope, and a combination thereof are illustrated. The lower surface of the contact pressing portion 222 may be stepwise forward as it goes upward, or may be gradually forward as it goes upward. When this shape is a slope, this slope may be a flat surface or a curved surface. This curved surface may be a convex curved surface or a concave curved surface.

The shape that becomes forward as it goes upward enhances adaptability to different water discharge pipes f3. That is, due to this shape, even if the shape of the water discharge pipe f3 changes, the contact pressing portion 222 easily comes into contact with the water discharge pipe f3 from above. Further, since the slide body moves in the front-rear direction, the contact pressing portion 222 also moves in the front-rear direction. The combination of the movement in the front-rear direction and the shape that becomes forward as it goes upward increases the adaptability to different water discharge pipes f3. This shape can contribute to an increase in the number of contact points with the water discharge pipe f3. In the connected state, the contact pressing part 222 can contact the discharge pipe f3 of the horizontal faucet from above. In the connected state, the contact pressing part 222 can contact the water discharge pipe f3 of the horizontal faucet (water discharge port rotation type) from the upper side. In the connected state, the contact pressing part 222 can contact the discharge pipe f3 of the horizontal faucet (free form) from above. The shape that becomes forward as it goes upward increases the versatility of the hose connector.

[Lower contact part]
The lower contact portion contacts the faucet f1 (water discharge pipe f3 and/or faucet body f2) from below. As shown in FIGS. 3 and 4, the hose connector 10 has a lower contact portion 134 that can contact the faucet f1 from below in the connected state. The lower contact portion 134 projects forward. The lower contact portion 134 extends forward from the water discharge pipe insertion portion 104. The slide body 200 is located behind the water discharge pipe f3, whereas the lower contact portion 134 is located in front of the water discharge pipe f3. When viewed from the user of the faucet f1, the lower contact portion 134 is located behind the water discharge pipe f3. The main body 100 of the first embodiment is in contact with a portion of the water faucet f1 other than the water discharge pipe f3 (water faucet main body f2).

The contact force applied to the faucet f1 by the lower contact portion 134 has a vertically upward component. As shown in FIGS. 10 and 11, the hose connector 20 has a lower contact portion 374 that can contact the faucet f1 from below in the connected state. The contact force applied to the faucet f1 by the lower contact portion 374 has a vertically upward component.

As shown in FIG. 3, in the connected state, the water faucet f1 is sandwiched between the contact pressing portion 222 and the lower contact portion 134 of the slide body 200. By the operation (tightening) of the slide operation part 110, the force of pinching is increased. The hose connector 10 is unlikely to come off the faucet f1 even when a high water pressure is applied. As shown in FIG. 10, in the connected state, the water faucet f1 is sandwiched between the contact pressing portion 422 and the lower contact portion 374 of the slide body 400. The hose connector 10 is unlikely to come off the faucet f1 even when a high water pressure is applied.

When the hose connector 10 comes out of the faucet f1 due to water pressure or the like, the hose connector 10 rotates in the rotation direction R1 along the bend of the bent portion f5 (see FIG. 3 ). The reaction force of the contact force of the lower contact portion 134 gives the hose connector 10 a rotational moment (rotation blocking moment) in the direction opposite to the rotational direction R1. The lower contact portion 134 suppresses the rotation of the hose connector 10 that occurs when the hose connector 10 comes off the faucet f1. The lower contact portion 134 can effectively prevent the hose connector 10 from coming off due to water pressure.

When the hose connector 20 comes out of the faucet f1 due to water pressure or the like, the hose connector 20 translates and rotates in the rotation direction R1 along the bend of the bent portion f5 (see FIG. 10). The reaction force of the contact force of the lower contact portion 374 gives the hose connector 20 a rotational moment (rotation blocking moment) in the direction opposite to the rotational direction R1. The lower contact portion 374 suppresses the rotation of the hose connector 20 that occurs when the hose connector 20 comes off the faucet f1. The lower contact portion 374 can effectively prevent the hose connector 20 from coming off due to water pressure.

The lower abutment preferably accommodates any faucet. The lower contact portion preferably contacts the faucet f1 from below in the connected state attached to the lateral faucet. The lower contact portion preferably contacts the faucet f1 from the lower side in a connected state attached to the horizontal faucet (rotating spout). The lower contact portion preferably contacts the faucet f1 from the lower side in a connected state attached to the horizontal faucet (free-form).

As will be described later, the water discharge pipe outer peripheral circle C1 is defined in the faucet f1. The diameter of the water discharge pipe outer circumference circle C1 of the horizontal faucet is 37 mm or more and 42 mm or less. The diameter of the water discharge pipe outer peripheral circle C1 of the horizontal faucet (water discharge port rotation type) is 48 mm or more and 51 mm or less. The diameter of the discharge pipe outer peripheral circle C1 of the horizontal faucet (free form) is 67 mm or more and 70 mm or less. From the viewpoint of compatibility with various faucets, the lower abutment portion abuts the faucet f1 from the lower side in a connected state in which it is attached to the faucet having a diameter of the discharge pipe outer circumferential circle C1 of 37 mm or more and 70 mm or less. Is preferred. From the viewpoint of compatibility with a horizontal faucet and a horizontal faucet (rotating spout), the lower contact portion is connected to a faucet having a diameter C1 of the outer circumference of the discharge pipe of 37 mm or more and 51 mm or less. In, it is preferable to contact the faucet f1 from below.

[Back contact part]
As shown in FIG. 10, the hose connector 20 has a back contact portion 376. As described above, the back contact portion 376 is the front portion 362 of the annular slide body 318. As described above, the hose connector 20 has the sub-slide mechanism that allows the annular slide body 318 to slide. When the slide operating portion 310 is rotated in the first direction (tightening direction), the annular slide body 318 moves rearward D2 with respect to the slide operating portion 310, and the back contact portion 376 contacts the concave curved surface f52 of the bending portion f5. Contact. The contact force generated by the contact of the back contact portion 376 includes a backward component. As a result, the faucet f1 (water discharge pipe f3) is sandwiched between the contact pressing portion 422 and the back contact portion 376 of the slide body 400. The hose connector 20 is configured such that the pinching force is increased by the operation (tightening) of the slide operation part 310. The hose connector 20 is unlikely to come off the faucet f1 even when a high water pressure is applied.

[Slide mechanism]
As described above, the hose connector 10 allows the slide body 200 to slide with respect to the main body 100 by the first slide engaging portion 148 which is a slide groove and the second slide engaging portion 220 which is a slide protrusion. A slide mechanism is configured. The hose connector 20 includes a slide mechanism that allows the slide body 400 to slide with respect to the main body 300 by the first slide engagement portion 348 that is a slide groove and the second slide engagement portion 420 that is a slide protrusion. Has been done. The combination of the slide protrusion and the slide groove is an example of a slide mechanism. The configuration of the slide mechanism is not limited as long as the slide movement is achieved. The shape of the slide protrusion is not limited. The slide protrusion may be a protrusion having a longitudinal direction in the sliding direction, such as the second slide engaging part 220, or a protrusion having a circular cross section, such as the second slide engaging part 420, It may be a protrusion having another shape. Further, in the hose connector 10 and the hose connector 20, the slide protrusion is provided on the slide body and the slide groove is provided on the main body portion, but conversely, the slide protrusion is provided on the main body portion and the slide groove is slid. It may be provided on the body.

[Smooth operation of slide mechanism]
From the viewpoint of smooth operability of the slide mechanism, it is preferable that the contact position where the slide operation part contacts the slide body is close to the slide center plane SP1. The slide center plane SP1 is the center plane of the slide mechanism. When the slide mechanism has a slide groove, the slide center plane SP1 is a plane including the center line L1 of the slide groove. The slide center plane SP1 is preferably flat. The center line L1 may be the center line of the bottom surface of the slide groove. When the slide mechanism has slide grooves on both sides as in the above-described first and second embodiments, the slide center plane SP1 has a center line L1 of one (left side) slide groove and the other (right side). It may be a plane including the center line L1 of the slide groove.

FIG. 17A is a sectional view of the first member 112 according to the first embodiment, like FIG. 6E. FIG. 17B is a sectional view according to the second embodiment and is a sectional view in which FIG. 13E and FIG. 14E are combined. That is, FIG. 17B is a sectional view of a member in which the annular slide body 318 is attached to the first member 312.

What is indicated by a chain double-dashed line in FIGS. 17A and 17B is a locus line L2 of the pressing contact point from the slide operation portion of the slide body. The pressing contact points move along with the movement of the slide body, and a set of continuously moving pressing contact points is the trajectory line L2. In the first and second embodiments, the locus line L2 coincides with the center line of the male screw part of the slide operation part. In the first and second embodiments, the locus line L2 coincides with the center line of the screw hole. When the slide operation portion and the slide body are in surface contact, the centroid of the contact surface is regarded as the pressing contact point, and the locus of this centroid is set as the locus line L2.

In the first and second embodiments, the slide mechanism is configured by the movement of the slide protrusion in the slide groove. In these embodiments, the pressure contact point of the slide body from the slide operation portion is located above the center line L1 of the slide groove. This relationship is established regardless of the position of the slide body. That is, as shown in FIGS. 17A and 17B, the locus line L2 is located above the center line L1. The locus line L2 is located above the slide center plane SP1. This hierarchical relationship can be determined in the reference state described later. As described above, in the slide mechanism, the slide groove may be formed in the slide body.

In the second embodiment, the pressure contact point of the slide body from the slide operation portion is located within the range of the vertical width of the slide groove. This relationship is established regardless of the position of the slide body. That is, as shown in FIG. 17B, the locus line L2 is located within the range of the vertical width of the slide groove 348. This hierarchical relationship can be determined in the reference state described later.

What is indicated by a double-headed arrow S1 in FIGS. 17A and 17B is the distance between the slide center plane SP1 and the trajectory line L2. The distance S1 is also the vertical distance between the center line L1 of the slide groove and the locus line L2. The distance S1 can be measured in the reference state described later. From the viewpoint of smooth operation of the mechanism of the slide body, the distance S1 is preferably 5 mm or less, more preferably 4 mm or less, and further preferably 3 mm or less. The distance S1 may be 0 mm. That is, the locus line L2 may be located on the slide center plane SP1. The vertical positions of the locus line L2 and the center line L1 may match. As described below, the distance S1 is preferably larger than 0 mm from the viewpoint of the forward inclination of the slide body in the connected state.

In the first and second embodiments, the locus line L2 is parallel to the slide center plane SP1. The locus line L2 is parallel to the center line L1 of the slide groove (left engaging portion) 148a, and is parallel to the center line L1 of the slide groove (right engaging portion) 148b. The distance between the center line L1 of the slide groove 148a and the locus line L2 is equal to the distance between the center line L1 of the slide groove 148b and the locus line L2. These configurations contribute to smooth operation of the slide mechanism.

The height of the slide body is shown by a double-headed arrow H1 in FIGS. 7D and 15D. Considering the preferable range of the distance S1 and the height H1, S1/H1 is preferably ¼ or less, and more preferably ⅕ or less. S1/H1 may be 0. As described later, it is preferable that S1/H1 is larger than 0 from the viewpoint of the forward inclination of the slide body in the connected state. The height H1 is the height of the entire slide body, and is the height in the vertical direction measured in the reference state described later.

In the first and second embodiments, the pressing contact point of the slide body from the slide operation portion is located below the center of gravity of the slide body. If the pressing contact point is located above the center line L1 of the slide groove, the slide body may tilt forward during the sliding movement, but the pressing contact point should be below the center of gravity of the slide body. Thus, the forward tilt of the slide body during the slide movement can be suppressed. From the viewpoint of smooth operability of the slide mechanism, this pressing contact point is preferably located below the center of gravity of the slide body. This relationship is preferably established in the entire movement range of the slide body. That is, the locus line L2 is preferably located below the center of gravity of the slide body. This hierarchical relationship can be determined in the reference state described later.

[Structure that allows tilting of slide body]
The slide mechanism described above may be configured to allow the tilt of the slide body in at least a part of the moving range of the slide body. The slide mechanism may be configured to allow the slide body to tilt forward and/or backward.

In the hose connector 10 of the first embodiment, the configuration that allows the slide body 200 to tilt is the play (gap) between the slide protrusion 220 and the slide groove 148. The degree of inclination can be adjusted by the width of the play (gap) and the length of the slide protrusion 220 in the longitudinal direction. In the hose connector 20 of the second embodiment, the configuration that allows the slide body 400 to tilt is the shape of the slide protrusion 420. Since the slide protrusion having a circular cross section can rotate in the slide groove 348, the inclination of the slide body 400 is allowed. The degree of inclination of the slide body 400 is restricted by the relationship between the slide body 400 and the ground contact surface (slide top surface (slide bottom surface) 370) and play in the sub-slide mechanism.

As shown in FIG. 7E, the lower end surface 206 of the slide body 200 forms a convex curved surface. This convex curved surface is in contact with the slide bottom surface 144. The lower end surface 206 reduces the installation area with the slide bottom surface and enhances the slidability with respect to the slide bottom surface 144. Further, the lower end surface 206 facilitates tilting of the slide body 200 and enhances stability of the slide body 200 when tilted.

The slide mechanism may be configured to allow the rearward inclination of the slide body. The slide mechanism may be configured to allow the rearward inclination of the slide body when the water discharge pipe is inserted into the water discharge pipe insertion portion. The rearward inclination of the slide body facilitates insertion of the water discharge pipe f3 into the water discharge pipe insertion portion. FIG. 18A is a cross-sectional view showing an example of the inclination of the slide body 200 when the water discharge pipe f3 is inserted into the water discharge pipe inserting portion 104. The rearward inclination of the slide body 200 facilitates insertion of the water discharge pipe f3. Further, the rearward inclination of the slide body 200 can reduce the rearward movement amount of the slide body 200 when the water discharge pipe f3 is inserted. Therefore, the operation amount of the slide operation unit 110 can be suppressed. Further, the stroke of sliding movement can be reduced, and the hose connector 10 can be downsized.

The slide mechanism may be configured to allow the forward inclination of the slide body. The forward inclination of the slide body contributes to improving the fixing property of the hose connecting tool 10 in the connected state. FIG. 18B is a sectional view showing an example of the inclination of the slide body 200 in the connected state. The forward inclination of the slide body 200 contributes to increasing the downward component F1 (described above) of the contact force F. Further, due to this forward inclination, the contact position between the contact pressing portion 222 of the slide body 200 and the water discharge pipe f3 can be set further forward. Therefore, the hose connector 10 is unlikely to come off the faucet f1. Further, the forward inclination angle enhances adaptability to the change in shape of the water discharge pipe f3. That is, the inclination angle can be changed corresponding to various shapes of the water discharge pipe f3. In the connected state, the slide body 200 can lean forward while contacting the water discharge pipe f3 of the horizontal faucet from above. In the connected state, the slide body 200 can tilt forward while contacting the water discharge pipe f3 of the horizontal faucet (rotating water discharge port) from above. In the connected state, the slide body 200 can lean forward while contacting the water discharge pipe f3 of the horizontal faucet (flexible type) from above. The hose connector 10 has excellent versatility.

From the viewpoint of enhancing the advantage caused by the inclination of the slide body, the inclination angle width θ in the front-rear direction of the slide body is preferably 10° or more, more preferably 20° or more at the slide position where the inclination of the slide body is allowed. , 30° or more is more preferable. From the viewpoint of smooth operation of the slide mechanism, the inclination angle width θ is preferably 40° or less, more preferably 38° or less, and 35 at the slide position where the inclination of the slide body is allowed. Less than or equal to 0 is more preferable.

The tilt angle width θ is a tilt angle width between when the slide body is tilted forward to the limit and when the slide body is tilted backward to the limit. The inclination angle width θ is measured in a state where the inclination of the slide body is not restricted by the slide operation portion and the water discharge pipe. In addition, the inclination angle width θ is measured with the hose connection tool in the standard state.

In the present application, the reference state is defined as a state in which the center line CL1 (FIG. 3) of the water discharge pipe insertion portion (hose connection portion) is in the vertical direction, and the slide operation portion and the faucet f1 are not in contact with the slide body. To be done.

In the measurement of the tilt angle width θ, the slide body is tilted in the front-rear direction at the hose connection part in the reference state. When a plane parallel to the front-rear direction (sliding direction) and parallel to the vertical direction is used as the reference plane, the slide body is tilted along the reference plane. That is, when tilted, every point belonging to the slide moves along this reference plane. When two arbitrary points are determined on the cross section of the slide body parallel to the reference plane, the angle change of the line segment connecting these two points is the inclination angle width θ.

18(a) and 18(b), the hose connector 10 of the first embodiment is used, but in the case of the hose connector 10, there is play between the slide protrusion 220 and the slide groove 148. By providing the (gap), the slide body 200 can be tilted. On the other hand, in the hose connector 20 of the second embodiment, since the slide protrusion 420 has a cylindrical shape, the slide body 400 tilts even without the play (gap). From the viewpoint of allowing the tilt of the slide body 200, the slide protrusion 220 according to the first embodiment may have the same cylindrical shape as the slide protrusion 420. In this way, each configuration of the first embodiment and each configuration of the second embodiment can be replaced with each other.

In the embodiment shown in FIGS. 17A and 17B, the pressing contact point (trajectory line L2) from the slide operation portion of the slide body is located above the center line L1 of the slide groove. This configuration can promote the forward tilting of the slide body in the connected state and enhance the fixability of the hose connector. From the viewpoint of tilting the slide body forward in the connected state, the distance S1 is preferably 1 mm or more, more preferably 3 mm or more, and further preferably 5 mm or more.

In the embodiment of FIG. 17B, the pressing contact point (trajectory line L2) from the slide operation portion of the slide body is located within the range of the vertical width of the slide groove 348. This configuration helps to achieve both smooth operation of the slide mechanism and fixing of the hose connector.

From the viewpoint of achieving both the smooth operability of the slide mechanism and the fixability of the hose connector, the inclination angle width θ may be large at the slide position which can be in the connected state, and the inclination angle width θ may be made small at other slide positions. .. From this viewpoint, the slide mechanism of the hose connector may have the following configuration (a).
(A) The moving range of the slide body includes a first range and a second range located behind the first range, and the tilt angle width θ in the first range is in the second range. It is larger than the inclination angle width θ.

This configuration (a) can be achieved, for example, by changing the width of the slide groove. For example, by keeping the width of the slide groove constant from the rear end of the slide groove to the middle point by a predetermined value and making the width of the slide groove from the middle point to the front end larger than the predetermined value, the configuration (a) can be obtained. Can be achieved. In this case, the width of the slide groove from the intermediate point to the front end may be gradually increased toward the front. From the viewpoint of smooth operation of the slide mechanism, the inclination angle width θ in the second range is preferably 10° or less, more preferably 5° or less, and further preferably 3° or less. The inclination angle width θ in the second range may be substantially 0° (less than 0.5°).

From the viewpoint of compatibility between the ease of inserting the water discharge pipe f3 and the fixability of the hose connector, the inclination angle width θ is large at the slide position where the water discharge pipe f3 can be inserted, and the inclination angle width θ is large at other slide positions. May be reduced. From this viewpoint, the slide mechanism of the hose connector may have the following configuration (b).
(B) The moving range of the slide body includes a first range and a second range located behind the first range, and the tilt angle width θ in the second range is in the first range. It is larger than the inclination angle width θ.

This configuration (b) can be achieved, for example, by changing the width of the slide groove. For example, the width of the slide groove is kept constant at a predetermined value from the front end of the slide groove to the middle point, and the width of the slide groove is made larger than the predetermined value from the middle point to the rear end. Can be achieved. In this case, the width of the slide groove from the intermediate point to the rear end may be gradually increased toward the rear. From the viewpoint of smooth operation of the slide mechanism, the inclination angle width θ in the first range is preferably 10° or less, more preferably 5° or less, and further preferably 3° or less. The inclination angle width θ in the first range may be substantially 0° (less than 0.5°).

The following configuration (c) in which the configuration (a) and the configuration (b) are combined is also possible.
(C) The moving range of the slide body includes a first range, a second range located behind the first range, and a third range located behind the second range. The tilt angle width θ in the first range is larger than the tilt angle width θ in the second range, and the tilt angle width θ in the third range is larger than the tilt angle width θ in the second range.

This configuration (c) can be achieved, for example, by changing the width of the slide groove. For example, in the middle region of the slide groove, the width of the slide groove is kept constant at a predetermined value, the width of the slide groove from the middle region to the rear end is made larger than the predetermined value, and the width from the middle region to the front end is increased. The configuration (c) can be achieved by making the width of the slide groove larger than the predetermined value. In this case, the width of the slide groove from the intermediate region to the front end may be gradually increased toward the front. Further, the width of the slide groove from the intermediate region to the rear end may be gradually increased toward the rear. From the viewpoint of smooth operation of the slide mechanism, the inclination angle width θ in the intermediate region is preferably 10° or less, more preferably 5° or less, and further preferably 3° or less. In the intermediate region, the inclination angle width θ may be substantially 0° (less than 0.5°).

[Outer circle of discharge pipe, inner circle of discharge pipe]
In the present application, an outer circumference circle of the water discharge pipe and an inner circumference circle of the water discharge pipe are defined. The outer circumference circle of the water discharge pipe and the inner circumference circle of the water discharge pipe are defined in a central cross section including the center line of the water discharge pipe f3.

FIG. 19 is the same sectional view as FIG. 16. FIG. 19 includes a central cross section of the water discharge pipe f3. As shown in FIG. 19, the water discharge pipe outer circumferential circle C1 and the water discharge pipe inner circumferential circle C2 are defined in this central cross section. The water discharge pipe outer circumference circle C1 is a circle along the outer surface cross section line E1 of the convex curved surface f51 in the central cross section. The water discharge pipe inner circumference circle C2 is a circle along the outer surface cross section line E2 of the concave curved surface f52 in the central cross section.

More precisely, the discharge pipe outer peripheral circle C1 is defined as follows. The outer surface section line E1 has a first end point P1, a second end point P2, and a middle point P3. The first end point P1 is a boundary point between a curve and a straight line or an inflection point. Similarly, the second end point P2 is a boundary point between a curved line and a straight line or an inflection point. The midpoint P3 is the midpoint of a finite curve having the points P1 and P2 at both ends. The water discharge pipe outer peripheral circle C1 is a circle that passes through the first end point P1, the second end point P2, and the midpoint P3.

Similarly, the water discharge pipe inner circumferential circle C2 is defined as follows. The outer surface section line E2 has a first end point P4, a second end point P5, and a midpoint P6. The first end point P4 is a boundary point between a curve and a straight line or an inflection point. Similarly, the second end point P5 is a boundary point or an inflection point between the curve and the straight line. The midpoint P6 is the midpoint of a finite curve having the points P4 and P5 at both ends. The water discharge pipe inner circumferential circle C2 is a circle passing through the first end point P4, the second end point P5, and the midpoint P6.

As shown in FIG. 19, in the central cross section, the lower contact portion 134 is located outside the water discharge pipe inner circumferential circle C2. When the hose connector 10 comes out of the faucet f1 due to water pressure or the like, the hose connector 10 rotates in the rotation direction R1 along the bend of the bent portion f5. The center of this rotation is substantially at or near the center of the water discharge pipe inner circumferential circle C2. As described above, the reaction force of the contact force of the lower contact portion 134 gives the hose connector 10 a rotation moment (rotation blocking moment) in the direction opposite to the rotation direction R1. Since the lower contact portion 134 is located outside the inner circumferential circle C2 of the water discharge pipe, this rotation blocking moment increases. The lower contact portion 134 can effectively prevent the hose connector 10 from coming off due to water pressure.

In the embodiment of FIG. 19, the lower contact portion 134 is located inside the water discharge pipe outer circumferential circle C1 in the central cross section. In this embodiment, the lower contact portion 134 does not have an outer contact portion that may be located outside the water discharge pipe outer peripheral circle C1.

[Outer contact part]
FIG. 20 is a sectional view of the hose connector 30 of the third embodiment. The hose connector 30 has a lower contact portion 134 a that is larger than the lower contact portion 134 of the hose connector 10. The hose connector 30 is the same as the hose connector 10 except for the lower contact portion.

The lower contact portion 134a has an outer contact portion 136 located outside the water discharge pipe outer peripheral circle C1 in the central cross section. When the hose connector 30 comes out of the faucet f1 due to water pressure or the like, the hose connector 30 rotates in the rotation direction R1 along the bend of the bent portion f5. The center of this rotation is substantially the center of the water discharge pipe outer circumference circle C1 or the vicinity thereof. The reaction force of the contact force of the outer contact portion 136 gives the hose connector 30 a rotational moment (rotation blocking moment) in a direction opposite to the rotational direction R1. Since the outer contact portion 136 is located outside the water discharge pipe outer circumferential circle C1, this rotation blocking moment increases. The outer contact portion 136 can effectively prevent the hose connector 30 from coming off due to water pressure.

FIG. 21 is a sectional view of the hose connector 40 of the fourth embodiment. The hose connector 40 is such that the additional member m1 is attached to the lower contact portion 134 of the hose connector 10. By attaching the additional member m1 to the lower contact portion 134, the lower contact portion 134b is formed. The lower contact portion 134b is larger than the lower contact portion 134. The lower contact portion 134b has an outer contact portion 138 located outside the discharge pipe outer peripheral circle C1 in the central cross section. The outer contact portion 138 is formed of the additional member m1.

The reaction force of the contact force of the outer contact portion 138 gives the hose connector 40 the rotation inhibiting moment. Since the outer contact portion 138 is located on the outer side of the water discharge pipe outer peripheral circle C1, this rotation blocking moment becomes large. The outer contact portion 138 can effectively prevent the hose connector 40 from coming off due to water pressure.

The additional member m1 is detachably attached to the main body 100. The additional member m1 can be attached or detached depending on the shape of the faucet f1. The removable additional member m1 enhances the adaptability of the hose connector 40 to different faucets f1.

The outer abutment preferably accommodates any faucet. It is preferable that the outer contact portion is located outside the water discharge pipe outer circumferential circle C1 in the connected state attached to the horizontal faucet. It is preferable that the outer abutment portion is located outside the water discharge pipe outer circumferential circle C1 in the connected state attached to the horizontal faucet (water spout rotary type). The outer contact portion is preferably positioned outside the water discharge pipe outer circumference circle C1 in the connected state attached to the horizontal faucet (free-form).

The diameter of the water discharge pipe outer circumference circle C1 of the horizontal faucet is 37 mm or more and 42 mm or less. The diameter of the water discharge pipe outer peripheral circle C1 of the horizontal faucet (water discharge port rotation type) is 48 mm or more and 51 mm or less. The diameter of the discharge pipe outer peripheral circle C1 of the horizontal faucet (free form) is 67 mm or more and 70 mm or less. From the viewpoint of compatibility with various faucets, the outer abutment portion is located outside the water discharge pipe outer circumference circle C1 in a connected state where the water discharge pipe outer circumference circle C1 has a diameter of 37 mm or more and 70 mm or less. Is preferred. From the viewpoint of compatibility with the horizontal faucet and the horizontal faucet (rotating spout), the outer contact portion is in a connected state in which it is attached to the faucet having a diameter of the discharge pipe outer peripheral circle C1 of 37 mm or more and 51 mm or less. More preferably, it is located outside the water discharge pipe outer circumference circle C1.

In FIG. 3, what is indicated by a double-headed arrow W1 is the maximum distance between the center line CL1 of the water discharge pipe inserting portion 104 (hose connecting portion 106) and the lower contact portion 134. This distance W1 is a distance between the center line CL1 and the front end of the lower contact portion 134. This distance W1 is measured along the direction perpendicular to the center line CL1. From the viewpoint of increasing the rotation preventing moment and the versatility, the distance W1 is preferably 30 mm or more, more preferably 33 mm or more, and further preferably 35 mm or more. From the viewpoint of downsizing of the hose connector, the distance W1 is preferably 39 mm or less, more preferably 37 mm or less, and even more preferably 35 mm or less.

In the second embodiment, since the lower contact portion 374 moves, the distance W1 changes. From the viewpoint of increasing the rotation blocking moment described above, it is preferable that the distance W1 does not change as in the lower contact portion 134 of the first embodiment.

In FIG. 15, what is indicated by a double-headed arrow H2 is the height from the lowest point of the slide body to the lowest point of the contact pressing portion. The height H2 is measured in the reference state, and is measured along the vertical direction. If the height H2 is too small, the variation of the water discharge pipe that can be received by the slide body decreases, and the versatility decreases. From this viewpoint, the height H2 is preferably 10 mm or more, more preferably 15 mm or more, and further preferably 18 mm or more. If the height H2 is too large, the height H1 described above becomes too large, and the posture of the slide body tends to be unstable. If the height H1 is too large, the slide body may interfere with the handle f4 of the faucet f1. From these viewpoints, the height H2 is preferably 25 mm or less, more preferably 23 mm or less, and further preferably 20 mm or less.

As described above, it is not preferable that the distance W1 and the height H1 are too large or too small. Considering the smooth operability of the height slide operation, versatility, and downsizing of the hose connector, it is preferable that H1/W1 is within a predetermined range. As a lower limit, H1/W1 is preferably 1/2 or more, more preferably 1/1.5 or more, and further preferably 1/1 or more. As an upper limit, H1/W1 is preferably 2/1 or less, more preferably 1.5/1 or less, and even more preferably 1.3/1 or less.

In FIG. 17A, what is indicated by a broken line PL1 is an extension plane in which the slide bottom surface 144 is extended forward. The lower contact portion 134 is located below the extension plane PL1. That is, the lower contact portion 134 is located below the slide bottom surface 144. This hierarchical relationship can be determined based on the reference state. From the viewpoint of sealability, the insertion length of the water discharge pipe f3 inserted into the water discharge pipe insertion portion 104 in the connected state needs to be a certain length or more. In particular, when the water discharge pipe f3 is short, this insertion length becomes insufficient, and the sealing performance may deteriorate. By setting the lower contact portion 134 to the lower side, when the water discharge pipe f3 is inserted into the water discharge pipe insertion portion 104, it is possible to prevent the lower contact portion 134 from hitting the faucet f1 and causing the insertion length to be insufficient. It

[Fifth Embodiment]
FIG. 22 is a perspective view showing a connected state in which the hose connector 50 according to the fifth embodiment is attached to the faucet. 23 is a cross-sectional view of FIG. FIG. 24 is a cross-sectional view of the second member of the hose connector 50. 22 and 23 show a connected state in which the hose connector 50 is connected to the faucet f10.

The hose connector 50 is attached to the faucet f10. The water faucet f10 is a horizontal water faucet (free form) defined by JIS B 2061.

The faucet f10 has a faucet body f12, a water discharge pipe f13, and a handle f14. The water discharge pipe f13 is connected to the faucet body f12. A part of the water discharge pipe f13 is bent and extends. That is, the water discharge pipe f13 has a bent portion f15. Further, the water discharge pipe f13 has a water discharge port f16. Water is discharged from the water discharge port f16. The water discharge pipe f13 extends from the faucet body f12 and terminates at a water discharge port f16. The water discharge pipe f13 has an intermediate straight portion f17 in addition to the bent portion f15. The middle straight portion f17 extends straight along a straight line. The intermediate straight portion f17 is located between the faucet body f12 and the bent portion f15. The bent portion f15 is located between the intermediate straight portion f17 and the water outlet f16.

The hose connector 50 has a main body 500 and a slide body 200. The slide body 200 is attached to the main body 500 in a state of being slidable. The slide body 200 is the same as that of the first embodiment described above.

The main body portion 500 includes a slide body placement portion 102, a water discharge pipe insertion portion 504, a hose connection portion 106, a packing 108, and a slide operation portion 110. From the viewpoint of components, the main body portion 500 includes the packing 108, the first member 512, the second member 114, and the slide operation portion 110. As shown in FIG. 23, the first member 512 and the second member 114 are coupled by a screw mechanism while sandwiching the packing 108. The joined first member 512 and second member 114 constitute a water discharge pipe inserting portion 504 having a cavity inside.

As shown in FIG. 24, an engagement protrusion t1 is provided on the inner surface of the first member 512. That is, the engagement protrusion t1 is provided on the inner surface of the water discharge pipe insertion portion 504. The first member 512 is the same as the first member 112 of the first embodiment, except for the existence of the engagement protrusion t1. The water discharge pipe inserting portion 504 is the same as the water discharge pipe inserting portion 104 of the first embodiment, except for the presence of the engagement protrusion t1. The main body portion 500 is the same as the main body portion 100 of the first embodiment, except for the presence of the engagement protrusion t1. The hose connector 50 is the same as the hose connector 10 of the first embodiment, except for the existence of the engagement protrusion t1.

The engagement protrusion t1 projects into the cavity of the water discharge pipe insertion portion 504. The engagement protrusion t1 projects inward in the radial direction of the water discharge pipe inserting portion 504.

As shown in FIG. 23, the lower contact portion 134 of the hose connector 50 is not in contact with the faucet f10. The hose connector 50 can be brought into a connected state with the lower contact portion 134 not contacting the faucet f10. Depending on the usage state of the hose connector 50, the lower contact portion 134 may contact the water discharge pipe f13 (intermediate straight portion f17).

The water discharge pipe f13 of the water faucet f10 has an annular protrusion f18 formed along the water discharge port f16. The annular protrusion f18 forms the lower end of the water discharge pipe f13. The annular protrusion f18 protrudes outward in the radial direction of the water outlet f16.

As shown in FIG. 23, the engagement protrusion t1 is engaged with the annular protrusion f18. The engagement protrusion t1 is engaged with the upper side of the annular protrusion f18. As shown in FIG. 24, the engagement protrusion t1 has a tip t2. The tip t2 is engaged with the annular protrusion f18. This engagement prevents the hose connector 50 from coming off the water discharge pipe f13 under high water pressure.

In the connected state where the hose connector 50 is connected to the faucet f10, the engagement protrusion t1 can engage with the annular protrusion f18. The hose connector 50 has excellent retaining performance at high water pressure.

[Sixth Embodiment]
FIG. 25 is a perspective view of the water faucet f1 to which the hose connector 60 according to the sixth embodiment is attached. 26 is a plan view of the faucet f1 with the hose connector 60 of FIG. 25, and FIG. 27 is a sectional view taken along the line AA of FIG. FIG. 28 is a perspective view showing a state where the hose connector 60 and the water faucet f1 are separated, and FIG. 29 is an exploded perspective view of the hose connector 60. 25 to 27 show a state (connection state) in which the hose connector 60 is connected to the faucet f1. In this connected state, the slide body 700 is in contact with the water discharge pipe f3 (bent portion f5) from above. The faucet f1 is the same as that shown in FIG.

As shown in FIG. 29, the hose connector 60 has a main body portion 600 and a slide body 700. The slide body 700 is attached to the main body section 600 in a slidable state.

As shown in FIG. 27, the main body section 600 has a slide body disposing section 602, a water discharge pipe inserting section 604, a hose connecting section 606, and a packing 608. As shown in FIG. 29, from the viewpoint of components, the main body 600 has a packing 608, a first member 612, a second member 614, and a third member 616.

As shown in FIG. 27, the first member 612 and the second member 614 are coupled by a screw mechanism while sandwiching the packing 608 via the third member 616. The first member 612, the second member 614, and the third member 616 that are joined together constitute a water discharge pipe insertion portion 604 having a cavity inside. The water discharge pipe insertion portion 604 has an upper opening, and the water discharge pipe f3 is inserted into the water discharge pipe insertion portion 604 through the upper opening. The slide body placement portion 602 is formed on the first member 612. The slide body placement portion 602 is formed on the upper portion of the main body portion 600. The hose connection portion 606 is formed on the lower portion of the second member 614. The hose connecting portion 606 is formed on the lower portion of the main body portion 600. A hose (not shown) is connected to the hose connection portion 606.

In the above-described first embodiment, the main body section 100 has the slide operation section 110. On the other hand, the main body section 600 of the present embodiment does not have a slide operation section for pressing and moving the slide body. The slide body 700 is slid by being pressed by a finger or the like. Both the forward sliding movement and the backward sliding movement are performed by directly applying a force to the slide body 700 with a finger or the like.

The main body part 600 has a lower contact part 634 that can contact the faucet f1 from below in the connected state. The lower contact portion 634 is formed on the first member 612. As shown in FIG. 27, the lower contact portion 634 contacts the faucet f1 (faucet body f2) from below in the connected state.

As shown in FIG. 28, the hose connector 60 is not separated as a whole. The method of attaching the hose connector 60 to the faucet f1 can be easily understood. The user can intuitively understand how to attach the hose connector 60.

In attaching the hose connector 60 to the faucet f1, first, the water discharge pipe f3 is inserted into the water discharge pipe insertion portion 604 from the upper side. The slide body 700 is slid forward by pressing the slide body 700 with a finger or the like. This pressing is continued until the slide body 700 contacts the water discharge pipe f3. When the slide body 700 comes into contact with the water discharge pipe f3, the regulation mechanism described later is switched from the non-regulated state to the regulated state to fix the slide body 700. As will be described later, this switching can be performed only by turning the regulation operation unit 708. In this way, the hose connector 60 can be easily attached.

FIG. 30A is a perspective view of the first member 612 as viewed obliquely from above. FIG. 30B is a perspective view of the first member 612 seen from another angle. FIG. 30C is a plan view of the first member 612. FIG. 30D is a side view of the first member 612.

As described above, the first member 612 (main body portion 600) has the slide body placement portion 602. The slide body placement portion 602 has a bottom surface 644 and a wall portion 646 extending upward from the bottom surface 644. The wall portions 646 are provided on the right and left sides of the bottom surface 644. The slide body placement portion 602 is open toward the front. The slide body placement portion 602 is open rearward.

The slide body placement portion 602 has a first slide engagement portion 648. The first slide engagement portions 648 are arranged so as to be dispersed on the left and right. The first slide engagement portion 648 is a slide protrusion. The slide protrusion 648 is a ridge (rail) extending in the slide direction (front-back direction).

As shown in FIG. 29, the slide body 700 includes a slide body portion 702, an engagement body 704, a cam moving body 706, and a restricting operation portion 708. The slide body portion 702 has a second slide engagement portion 710. A second slide engagement portion 710 is formed on each of the left and right sides of the slide body portion 702. The second slide engagement portion 710 is a slide groove. The slide body portion 702 has a contact pressing portion 712 (see FIGS. 27 and 29). As shown in FIG. 27, the contact pressing portion 712 has a shape that becomes forward as it goes upward. The contact pressing portion 712 is in contact with the water discharge pipe f3 (bent portion f5) from above in the connected state.

In the present embodiment, the slide mechanism that enables the slide body 700 to slide is configured by the slide protrusion 648 and the slide groove 710. As shown in FIG. 28, the slide body 700 floats from the bottom surface 644. The bottom surface of the slide body 702 is located above the bottom surface 644. The bottom surface of the slide body 702 is separated from the bottom surface 644. The engagement between the slide protrusion 648 and the slide groove 710 holds the slide body 700 at a position above the bottom surface 644. With this configuration, the height of the slide body 700 is adjusted. The bottom surface of the slide body 702 may be in contact with the bottom surface 644.

FIG. 31A is an enlarged view of a portion surrounded by a square line in FIG. However, in FIG. 31(a), the handle f4 of the water faucet f1 is removed. In FIG. 31A, the restricting operation portion 708 is located at the first rotation position RP1. FIG. 31(b) shows the case where the regulation operation part 708 is in the second rotation position RP2. In the present embodiment, the first rotation position RP1 and the second rotation position RP2 have a phase difference of 90°.

The slide body 700 has two engaging bodies 704 and two cam moving bodies 706. The left and right engaging bodies 704 are provided one by one. The cam moving bodies 706 are also provided one each on the left and right. Each of the engagement bodies 704 has a tooth portion 704a. The tooth portion 704a is configured by arranging a plurality of protrusions having a triangular cross section. Each of the cam moving bodies 706 has a cam contact portion 706a, an extending portion 706b, and a cam pressing portion 706c. With reference to FIG. 29, the restriction operation part 708 has a manual operation part 708a and a shaft part 708b. The shaft portion 708b has a rotation support portion 708c and a cam protrusion 708d. The manual operation part 708a has a shape that facilitates rotation of the regulation operation part 708 with the shaft part 708b as a rotation axis. As shown in FIG. 31A, two cam protrusions 708d are formed. The cam protrusions 708d are formed at every 180° in the circumferential direction of the shaft portion 708b.

The tooth portion 650 with which the tooth portion 704b of the engagement body 704 meshes is provided in the slide body placement portion 602. A tooth portion 650 is formed on the inner surface of the wall portion 646 of the slide body placement portion 602. A pair of left and right tooth portions 650 is provided corresponding to the pair of left and right engaging bodies 704. The tooth portion 650 is formed along the slide protrusion 648. The tooth portion 650 is configured by arranging a plurality of protrusions having a triangular cross section.

The rotation support portion 708c of the regulation operation portion 708 is inserted into a hole formed in the slide body portion 702 (see FIG. 27). The regulation operation part 708 can rotate around the shaft part 708b.

The slide body 702 has a guide groove 714 that regulates the moving direction of the cam moving body 706 (see FIG. 31A). The extending portion 706b of the cam moving body 706 is arranged in the guide groove 714. Since the extending portion 706b is constrained by the guide groove 714, it is restricted only in the direction along the movement guide groove 714 of the cam moving body 706.

In the hose connector 60, the restricting mechanism that restricts the backward movement of the slide body 700 has the engaging body 704, the cam moving body 706, and the restricting operation portion 708 on the slide body 700 side, and the slide body disposing portion 602 side. It has a tooth portion 650. By the rotation operation of the restriction operation portion 708, there are a restricted state in which the slide movement of the slide body 700 to the rear (and the front) is regulated and an unrestricted state in which the slide movement of the slide body 700 is allowed to the rear (and the front). Can be switched.

In FIG. 31(a), the regulation operation part 708 is in the first rotation position RP1. In this state, the cam protrusion 708d pushes the cam contact portion 706a, and the cam moving body 706 moves to the engaging body 704 side. As a result, the cam pressing portion 706c presses the back side of the tooth portion 704b of the engaging body 704, and the tooth portion 704b is pressed against the tooth portion 650. As long as the restricting operation portion 708 is located at the first rotation position RP1, the engagement between the tooth portion 704b and the tooth portion 650 is maintained. Therefore, the slide body 700 cannot slide. In this way, the regulation state is achieved by setting the regulation operation unit 708 to the first rotation position RP1.

In FIG. 31(b), the regulation operation part 708 is in the second rotation position RP2. In this state, the cam protrusion 708d separates from the cam contact portion 706a, and the cam moving body 706 is not pressed toward the engaging body 704 side. Therefore, the pressing of the tooth portion 704b against the tooth portion 650 is released. Therefore, the engagement between the tooth portion 704b and the tooth portion 650 is easily released by the force of sliding the slide body 700. In this way, the restriction operation unit 708 is set to the second rotation position RP2, whereby the non-regulation state is achieved.

As described above, the hose connector 60 has the restricting mechanism that restricts the rearward sliding movement of the slide body 700. The slide body 700 has a regulation operation section 708 for switching the regulation state and the non-regulation state of the regulation mechanism. The regulation operation unit 708 can switch between the regulation state and the non-regulation state by an operation (rotation operation). In the restricted state, the slide movement of the slide body 700 to the rear and the front is restricted. In the non-regulated state, the slide body 700 is allowed to slide backward and forward.

[Seventh Embodiment]
FIG. 32 is a perspective view of the faucet f1 to which the hose connector 70 according to the seventh embodiment is attached. FIG. 33 is a plan view of the faucet f1 with the hose connector 70 of FIG. 34 is a cross-sectional view taken along the line AA of FIG. FIG. 35 is a perspective view showing a state in which the hose connector 70 and the faucet f1 are separated. FIG. 36 is an exploded perspective view of the hose connector 70. 32 to 34 show a state (connection state) in which the hose connector 70 is connected to the faucet f1. In this connected state, the slide body 900 is in contact with the water discharge pipe f3 (bent portion f5) from above. In the connected state of the hose connector 70, the slide operation part 110 (screw member) is tightened, and the hose connector 70 is fixed to the faucet f1. The faucet f1 is the same as that shown in FIG.

As shown in FIG. 36, the hose connector 70 has a main body portion 800 and a slide body 900. The slide body 900 is attached to the main body 800 in a state of being slidable.

The slide body 900 is a solid member. Unlike the slide body 200 of the first embodiment described above, the slide body 900 does not have the side wall portion (the left wall portion 208, the right wall portion 210) and the rear wall portion 212. Details of the slide body 900 will be described later.

As shown in FIG. 34, the main body portion 800 has a slide body disposing portion 802, a water discharge pipe inserting portion 804, a hose connecting portion 806, packing 808, and a slide operating portion 110. The slide operation unit 110 is the same as that of the first embodiment. As shown in FIG. 36, the main body 800 has a packing 808, a first member 812, a second member 814, and a third member 816 from the viewpoint of components.

As shown in FIG. 34, the first member 812 and the second member 814 are coupled by a screw mechanism while sandwiching the packing 808 via the third member 816. The first member 812, the second member 814, and the third member 816 that are joined together constitute a water discharge pipe insertion portion 804 having a cavity inside. The water discharge pipe insertion portion 804 has an upper opening, and the water discharge pipe f3 is inserted into the water discharge pipe insertion portion 804 through the upper opening. The hose connection portion 806 is formed on the lower portion of the second member 814. A hose (not shown) is connected to the hose connection portion 806.

The main body section 800 has a pressing support section 820 that supports the slide operation section 110. When the slide operation unit 110 presses the slide body 900, a reaction force of this pressing force is generated. The pressing support portion 820 receives this reaction force.

As shown in FIG. 36, in this embodiment, the operation support portion 820 is a wall portion. The pressing support portion 820 is a part of the first member 812. A screw hole 822 is formed in the operation support portion 820. When the slide operating part 110 is rotated in the first direction (tightening direction), the slide operating part 110 presses the slide body 900 and moves the slide body 900 forward. When the slide operating part 110 is rotated in the second direction (loosening direction) opposite to the first direction, the slide operating part 110 moves backward. In order to achieve the connected state, the slide body 900 is moved forward until the slide body 900 contacts the water discharge pipe f3.

In the present embodiment, the slide operation part 110 is a screw member. This screw member presses the slide body 900 by being screwed in and moving forward. A screw mechanism having a screw member does not move unless it is rotated. Therefore, this screw mechanism is a regulation mechanism that regulates the backward sliding movement of the slide body 900.

As described above, the first member 812 (main body portion 800) has the slide body placement portion 802. The slide body placement portion 802 has a bottom surface 844 and a wall portion 846 that extends upward from the bottom surface 844. The wall portions 846 are provided on the right side, the left side, and the rear side of the bottom surface 844. The slide body placement portion 802 is open toward the front.

The slide body placement portion 802 has a first slide engagement portion 848. The first slide engagement portions 848 are arranged so as to be dispersed on the left and right. The first slide engagement portion 848 is a slide protrusion. The slide protrusion 848 is a ridge (rail) extending in the slide direction (front-back direction).

FIG. 37(a) is a perspective view of the slide body 900 as seen obliquely from above, FIG. 37(b) is a perspective view of the slide body 900 as seen from another angle, and FIG. 37(c) is a slide body 900. FIG. 37D is a rear view of the slide body 900, and FIG. 37D is a front view of the slide body 900 seen from the front.

The slide body 900 has a front surface 902, a rear surface 904, an upper surface 906, a lower surface 908, and a side surface 910. The lower surface 908 is parallel to the sliding direction. The lower surface 908 need not be parallel to the sliding direction. An angle θc formed by the front surface 902 and the lower surface 908 is 90°. The angle θc does not have to be 90°.

The side surface 910 is formed on each of the left and right sides of the slide body 900. A second slide engagement portion 912 is formed on each of the left and right side surfaces 910. The second slide engagement portion 912 is a slide groove.

The slide mechanism according to this embodiment includes a slide protrusion 848 and a slide groove 912. As shown in FIGS. 34 and 35, the slide body 900 floats from the bottom surface 844. The lower surface 908 of the slide body 900 is located above the bottom surface 844. The lower surface 908 is separated from the bottom surface 844. The engagement between the slide protrusion 848 and the slide groove 912 holds the slide body 900 at a position above the bottom surface 844. With this configuration, the height of the slide body 900 is adjusted.

The slide body 900 has a contact holding portion 914 that comes into contact with the water discharge pipe f3 from above (see FIG. 34). In the present embodiment, the contact pressing portion 914 is the lower edge of the front surface 902. The contact pressing portion 914 is the front edge of the lower surface 908. The contact pressing portion 914 is a corner portion formed by intersecting the front surface 902 and the lower surface 908. The corner may be rounded. A chamfer may be formed at this corner.

The slide body 900 does not have a portion located in front of the contact pressing portion 914. The slide body 900 does not have a portion below the contact pressing portion 914. The slide body 900 does not have a portion that can interfere with the water discharge pipe f3, other than the contact pressing portion 914 that is a corner portion. Therefore, the contact pressing portion 914 can surely contact the water discharge pipe f3 (bent portion f5). In addition, the contact presser 914 has excellent adaptability to changes in the shape of the water discharge pipe f3. The hose connector 70 has high versatility.

The slide body 900 has a pressed portion 916 that is pressed by the slide operation unit 110. The pressed portion 916 is provided on the rear surface 904. The pressed portion 916 has an engaging contact portion 918. The engagement contact portion 918 is a recess. The shape of the engaging contact portion 918 corresponds to the shape of the tip of the shaft portion 124 of the slide operation portion 110. The slide body 900 is pressed by the slide operation portion 110 in a state where the tip of the shaft portion 124 is inserted into the engagement contact portion 918. The pressing force is stably transmitted to the slide body 900 by the engagement between the tip of the shaft portion 124 and the engagement contact portion 918. The engagement contact portion 918 enhances smooth operation of the slide mechanism.

As shown by the slide body 900, the slide body may have a simple shape. For example, the slide body may be rod-shaped (round bar-shaped or the like) as a whole. It suffices for the slide body to have a contact pressing portion that contacts the water discharge pipe f3 from above. In the slide body 900, the contact pressing part is a corner, but the contact pressing part may be a convex curved surface, for example. A curved surface having a circular cross section is an example of this convex curved surface.

[Eighth Embodiment]
FIG. 38 is a perspective view of the faucet f1 to which the hose connector 80 according to the eighth embodiment is attached. The hose connector 80 has a main body 1000 and a slide body 1100. The slide body 1100 is attached to the main body 1000 in a state of being slidable in the front-rear direction.

The main body portion 1000 has an insertion member 1010 and a pressing support portion 1020 that supports the insertion member 1010. The pressing support portion 1020 supports the insertion member 1010 from the rear. The insertion member 1010 has a shape in which the width in the front-rear direction becomes smaller toward the lower side. The insertion member 1010 is a wedge-shaped member. The insertion member 1010 is inserted between the slide body 1100 and the pressing support portion 1020. When the insertion member 1010 is pressed downward, the insertion member 1010 is inserted deeper. Therefore, the slide body 1100 is pressed by the insertion member 1010 from the rear and slides forward.

In the connected state of the hose connector 80, the insertion member 1010 is pushed downward. Therefore, the insertion member 1010 is sandwiched between the pressing support portion 1020 and the slide body 1100 and compressed. The position of the insertion member 1010 in the insertion direction is maintained by the static friction force. The presence of the insertion member 1010 restricts the rearward movement of the slide body 1100. The insertion member 1010 constitutes a regulation mechanism that regulates the backward sliding movement of the slide body 1100. Further, the insertion member 1010 is a slide operation portion that pushes the slide body 1100 forward by an operation. This operation is to push the insertion member 1010 downward. When releasing the connection state, the insertion member 1010 is pulled out upward.

As the fixing means for fixing the position of the insertion member 1010 in the insertion direction, for example, a ratchet mechanism, a screwing mechanism, or the like can be adopted in addition to the use of the static friction force. As the ratchet mechanism, for example, the ratchet mechanism may be provided on the contact surface between the slide body 1100 and the insertion member 1010 and/or the contact surface between the pressing support portion 1020 and the insertion member 1010. Examples of the ratchet mechanism include a plurality of irregularities (teeth) having a shape that restricts the upward movement of the insertion member 1010 and facilitates the downward movement. As the screwing mechanism, a configuration may be adopted in which, in addition to the insertion member 1010, a screw mechanism in which the tip of the screw contacts the insertion member 1010 is provided. The position of the insertion member 1010 in the insertion direction can be fixed by tightening the screw of the screw mechanism when the insertion member 1010 is in the predetermined position. When the static friction force is used, the insertion member 1010 may be made of a soft material (soft resin, rubber, etc.) from the viewpoint of improving the fixing property of the insertion member 1010.

[Ninth Embodiment]
FIG. 39 is a perspective view of the faucet f1 to which the hose connector 90 according to the ninth embodiment is attached. The hose connector 90 has a main body 1200 and a slide body 1300. The slide body 1300 is attached to the main body section 1200 in a slidable state.

The main body 1200 includes a slide biasing member 1210, a pressing support 1220 that supports the slide biasing member, and a screw mechanism 1230. The slide biasing member 1210 is arranged between the pressing support portion 1220 and the slide body 1300. The slide biasing member 1210 is an elastic body. In the present embodiment, the slide biasing member 1210 is a compression spring (compression coil spring). Elastic bodies other than springs may be used. The slide biasing member 1210 presses the slide body 1300 from the rear. The slide biasing member 1210 biases the slide body 1300 forward. The slide biasing member 1210 constantly biases the slide body 1300 forward regardless of the position of the slide body 1300 in the front-rear direction. The screw mechanism 1230 has a screw member 1240. The main body part 1200 has a wall part 1250 located on the side of the slide body 1300, and the screw member 1240 is screwed into a screw hole formed in the wall part 1250. When the screw member 1240 is screwed in, the tip of the screw member 1240 comes into contact with the slide body 1300. By screwing the screw member 1240, the slide direction position of the slide body 1300 can be fixed.

The slide biasing member 1210 is a pressing member that always presses the slide body 1300 forward regardless of the operation. Further, the slide biasing member 1210 constitutes a regulation mechanism that regulates the backward sliding movement of the slide body 1300. Further, the screw mechanism 1230 is a regulation mechanism that regulates the backward sliding movement of the slide body 1300.

In the hose connector 90 of the ninth embodiment, when the water discharge pipe f3 is inserted into the water discharge pipe insertion portion, the slide body 1300 is automatically pressed against the water discharge pipe f3. Therefore, it is not necessary to press the slide body against the water discharge pipe f3 by the operation. When the water discharge pipe f3 is inserted into the water discharge pipe insertion portion, the slide body 1300 can be pushed backward against the biasing force of the slide biasing member 1210. This displacement can be achieved by pressing the water discharge pipe f3 against the slide body 1300. In this way, the hose connector 90 can be easily fixed to the water discharge pipe f3. The hose connector 90 has excellent mountability to the faucet f1.

The screw mechanism 1230 is used only for the purpose of fixing the slide body 1300. The screw mechanism 1230 is not for pressing the slide body for sliding movement unlike the slide operation unit 110 of the first embodiment. The amount of movement of the screw member 1240 when the screw mechanism 1230 is tightened is small. That is, the number of operations of the screw mechanism 1230 can be reduced.

Examples of the material of the slide body include resin and metal. The resin is preferable from the viewpoint of suppressing damage to the water faucet f1. As the resin, a resin excellent in strength and productivity is preferable. From the viewpoint of ease of molding, the resin is preferably a thermoplastic resin. From the viewpoint of moldability, polypropylene (PP), acrylonitrile butadiene styrene copolymer (ABS), and polyacetal (POM) are exemplified as more preferable resins. From the viewpoint of strength, polyacetal (POM) is more preferable. In each of the above-described embodiments, the material of the slide body is polyacetal (POM).

Examples of the material of the first member of the main body include resin and metal. As the resin, a resin that is inexpensive and has excellent productivity is preferable. From the viewpoint of ease of molding, the resin is preferably a thermoplastic resin. From the viewpoint of moldability, polypropylene (PP), acrylonitrile butadiene styrene copolymer (ABS) and polyacetal (POM) are exemplified as more preferable resins. ABS is more preferable because it is inexpensive and has excellent strength. In each of the above-described embodiments, the material of the first member of the main body is ABS.

Examples of the material of the second member of the main body include resin and metal. As the resin, a resin that is inexpensive and has excellent productivity is preferable. From the viewpoint of ease of molding, the resin is preferably a thermoplastic resin. From the viewpoint of moldability, polypropylene (PP), acrylonitrile butadiene styrene copolymer (ABS) and polyacetal (POM) are exemplified as more preferable resins. ABS is more preferable because it is inexpensive and has excellent strength. In each of the above-described embodiments, the material of the second member of the main body is ABS.

Examples of the material for the annular slide body (second embodiment) of the main body include resin and metal. The resin is preferable from the viewpoint of suppressing damage to the water faucet f1. As the resin, a resin excellent in strength and productivity is preferable. From the viewpoint of ease of molding, the resin is preferably a thermoplastic resin. From the viewpoint of moldability, polypropylene (PP), acrylonitrile butadiene styrene copolymer (ABS), and polyacetal (POM) are exemplified as more preferable resins. From the viewpoint of strength, polyacetal (POM) is more preferable. In the second embodiment described above, the material of the slide body is polyacetal (POM).

Regarding the above-described embodiment, the following supplementary notes are disclosed.
[Appendix 1]
Body part,
A slide body capable of sliding movement forward of the faucet approaching the water discharge pipe and backward away from the water discharge pipe;
A slide mechanism that enables the slide movement,
A restriction mechanism for restricting the rearward sliding movement of the slide body,
Has
The main body portion has a water discharge pipe insertion portion having a packing, and a hose connection portion,
A hose connector in which the slide body has a contact pressing portion that abuts the water discharge pipe from above.
[Appendix 2]
2. The hose connector according to appendix 1, wherein the main body section has a slide operation section that presses the slide body forward by an operation and that constitutes the regulation mechanism.
[Appendix 3]
3. The hose connector according to appendix 1 or 2, wherein the slide body has a front opening portion configured to receive a part of the water discharge pipe that extends in a curved manner as the slide body moves forward.
[Appendix 4]
4. The hose connector according to any one of appendices 1 to 3, wherein the contact pressing portion includes a shape that becomes forward as it goes upward.
[Appendix 5]
5. The hose connector according to any one of appendices 1 to 4, wherein the contact pressing portion is a protruding portion that protrudes downward in the slide body.
[Appendix 6]
6. The hose connector according to any one of appendices 1 to 5, wherein the slide mechanism is configured to allow the tilt of the slide body in at least a part of a moving range of the slide body.
[Appendix 7]
7. The hose connector according to appendix 6, wherein the slide mechanism is configured to allow the forward inclination of the slide body in the connected state.
[Appendix 8]
8. The hose connector according to appendix 6 or 7, wherein the slide mechanism is configured to allow a rearward inclination of the slide body when the water discharge pipe is inserted into the water discharge pipe insertion portion.
[Appendix 9]
The slide mechanism includes a slide groove and a slide protrusion,
9. The hose connector according to any one of appendices 1 to 8, wherein a pressing contact point of the slide body from the slide operation portion is located above a center line of the slide groove.
[Appendix 10]
The slide mechanism includes a slide groove and a slide protrusion,
10. The hose connector according to any one of appendices 1 to 9, wherein a pressing contact point of the slide body from the slide operation portion is located within a range of a vertical width of the slide groove.
[Appendix 11]
The hose connector according to appendix 9 or 10, wherein the pressing contact point is located below the center of gravity of the slide body.
[Appendix 12]
12. The hose connector according to any one of appendices 1 to 11, wherein the main body portion further includes a lower contact portion that extends forwardly and contacts the water faucet from below in a connected state. ..
[Appendix 13]
The main body portion has a slide bottom surface on which the slide body is placed, and a lower end surface of the slide body abuts,
13. The hose connector according to appendix 12, wherein the lower contact portion is located below the slide bottom surface.
[Appendix 14]
In the central cross section including the center line of the water discharge pipe, when the water discharge pipe outer circumference circle which is a circle along the outer surface cross section line of the convex curved surface of the water discharge pipe is defined,
The hose connector according to appendix 12 or 13, wherein the lower contact portion has an outer contact portion located outside the water discharge pipe outer peripheral circle in the central cross section.
[Appendix 15]
The main body portion has an engagement protrusion on the inner surface of the water discharge pipe insertion portion,
15. The hose connector according to any one of appendices 1 to 14, wherein, in the connected state, the engagement protrusion engages with an annular protrusion formed on the lower end of the discharge pipe.

The present application also describes other inventions which are not included in the inventions claimed in the independent claims. Each of the forms, members, configurations, etc. described in the claims and the embodiments of the present application is recognized as an invention based on the action and effect possessed by each.

Each form, member, configuration, etc. shown in each of the above-mentioned embodiments does not have all the forms, members, or configurations of these embodiments, but individually includes the invention according to the claims of the present application. It is applicable to all the inventions described.

10, 20, 30, 40, 50, 60, 70, 80, 90... Hose connector 100, 300, 500, 600, 800, 1000, 1200... Main body 102, 302, 602, 802... -Slide body placement section 104, 304, 504, 604, 804... Water discharge pipe insertion section 110, 310... Slide operation section 200, 400, 700, 900, 1100, 1300... Slide body 214, 414... ..Front openings 222, 422, 712, 914... Contact pressing portions 136, 138... Outer contact portions 134, 374... Lower contact portions 148, 348... First slide members Joint part (slide groove)
220, 420... Second slide engaging portion (slide protrusion)
648, 848... First slide engaging portion (slide protrusion)
710, 912... Second slide engaging portion (slide groove)
L1... Center line of slide groove L2... Locus line of pressing contact point from slide operation part in slide body f1, f10... Water faucet f2, f12... Water faucet body f3, f13... Discharge pipe f5, f15... Bent portion f51... Convex curved surface f52... Concave curved surface t1... Engaging protrusion D1... Front D2... Rear

Claims (14)

Body part,
A slide body capable of sliding movement forward of the faucet approaching the water discharge pipe and backward away from the water discharge pipe;
A slide mechanism that enables the slide movement,
A restriction mechanism for restricting the rearward sliding movement of the slide body,
Has
The main body portion has a water discharge pipe insertion portion having a packing, and a hose connection portion,
The slide body has an abutting pressing portion that abuts the bent portion of the water discharge pipe from above,
In the center cross section of the water discharge pipe, the water discharge pipe outer circumferential circle along the outer cross-section line of the bent portion with which the contact pressing portion abuts has a diameter of 37 mm or more and 70 mm or less,
A hose connector configured such that the contact force applied to the bent portion of the water discharge pipe by the contact has a component F1 in the water discharge direction and a component F2 in the front direction. Body part,
A slide body capable of sliding movement forward of the faucet approaching the water discharge pipe and backward away from the water discharge pipe;
A slide mechanism that enables the slide movement,
A restriction mechanism for restricting the rearward sliding movement of the slide body,
Has
The main body portion has a water discharge pipe insertion portion having a packing, and a hose connection portion,
The slide body has a contact pressing portion that abuts the water discharge pipe from above,
The slide body has a front opening that is configured to receive a part of the bent portion of the water discharge pipe that bends and extends along with the forward movement .
The slide body hose fitting height from the lowest point to the lowest point of the contact pressing portion Ru der least 10mm of. Body part,
A slide body capable of sliding movement forward of the faucet approaching the water discharge pipe and backward away from the water discharge pipe;
A slide mechanism that enables the slide movement,
A restriction mechanism for restricting the rearward sliding movement of the slide body,
Has
The main body portion has a water discharge pipe insertion portion having a packing, a hose connection portion, and a slide operation portion that pushes the slide body toward the front by an operation,
The slide body has a contact pressing portion that abuts the water discharge pipe from above,
The slide mechanism includes a slide groove and a slide protrusion,
A hose connector in which a pressing contact point of the slide body from the slide operation portion is located above a center line of the slide groove. Body part,
A slide body capable of sliding movement forward of the faucet approaching the water discharge pipe and backward away from the water discharge pipe;
A slide mechanism that enables the slide movement,
A restriction mechanism for restricting the rearward sliding movement of the slide body,
Has
The main body portion has a water discharge pipe insertion portion having a packing, a hose connection portion, and a slide operation portion that pushes the slide body toward the front by an operation,
The slide body has a contact pressing portion that abuts the water discharge pipe from above,
The slide mechanism includes a slide groove and a slide protrusion,
A hose connector in which the pressing contact point of the slide body from the slide operation portion is located within the range of the vertical width of the slide groove. The hose connector according to claim 3 , wherein the pressing contact point is located below the center of gravity of the slide body. Body part,
A slide body capable of sliding movement forward of the faucet approaching the water discharge pipe and backward away from the water discharge pipe;
A slide mechanism that enables the slide movement,
A restriction mechanism for restricting the rearward sliding movement of the slide body,
Has
The main body portion has a water discharge pipe insertion portion having a packing, and a hose connection portion,
The slide body has a contact pressing portion that abuts the water discharge pipe from above,
The main body portion further has a lower contact portion that extends toward the front and contacts the faucet from below in the connected state,
The main body portion has a slide bottom surface on which the slide body is placed, and a lower end surface of the slide body abuts,
The hose connector in which the lower contact portion is located below the slide bottom surface. Body part,
A slide body capable of sliding movement forward of the faucet approaching the water discharge pipe and backward away from the water discharge pipe;
A slide mechanism that enables the slide movement,
A restriction mechanism for restricting the rearward sliding movement of the slide body,
Has
The main body portion has a water discharge pipe insertion portion having a packing, and a hose connection portion,
The slide body has a contact pressing portion that abuts the water discharge pipe from above,
The main body portion has an engagement protrusion on the inner surface of the water discharge pipe insertion portion,
A hose connector in which, in the connected state, the engagement protrusion engages with an annular protrusion formed on the lower end of the discharge pipe. The hose connector according to claim 1 , 2, 6, or 7 , wherein the main body portion has a slide operation portion that presses the slide body forward by an operation and that constitutes the regulation mechanism. .. The hose connector according to any one of claims 1 to 8, wherein the contact pressing portion includes a shape that becomes forward as it goes upward. The hose connector according to any one of claims 1 to 9 , wherein the contact pressing portion is a protruding portion that protrudes downward inside the slide body. The hose connector according to any one of claims 1 to 10 , wherein the slide mechanism is configured to allow the tilt of the slide body in at least a part of a moving range of the slide body. The hose connection according to any one of claims 1 to 11 , wherein the main body portion further has a lower contact portion that extends forwardly and abuts against the faucet from below in a connected state. Ingredient In the central cross section including the center line of the water discharge pipe, when the water discharge pipe outer circumference circle which is a circle along the outer surface cross section line of the convex curved surface of the water discharge pipe is defined,
The hose connector according to claim 12 , wherein the lower contact portion has an outer contact portion located outside the water discharge pipe outer circumferential circle in the central cross section. Before SL slide mechanism is constituted by the slide groove and the slide projection, it said and one of said slide groove or said slide protruding to the slide member is provided, the other of the slide groove or said slide protruding into the body portion The hose connector according to any one of claims 1 to 13, which is provided.

Images