JP2020139291A - Socket unit, faucet and construction method of faucet - Google Patents

Abstract

To provide the construction method of the faucet, that allows a faucet body to be easily mounted to a suitable position.SOLUTION: A crank type socket unit 20 for connecting the faucet body and piping 13 on a wall surface 11 comprises: a tubular joint 30 connected to the piping 13 on the wall surface 11 by screwing; and a socket body 40 that is provided with a connection part 60 connected to the faucet body, can be integrally rotated with respect to the joint 30, and is assembled so that the socket body can slide in an axial direction of the joint 30, wherein a stopper member 50 that regulates movement of the socket body 40 to at least one of a wall surface 11 side and a faucet body side at an arbitrary position is mounted to the joint 30.SELECTED DRAWING: Figure 6

Description

The present invention relates to a socket unit, a faucet, and a method for constructing a faucet.

Patent Document 1 describes a socket for connecting a faucet main body of a hot water mixing faucet and a pipe on a wall surface.
As shown in FIGS. 9A and 9B, the hot water pipe 13a and the water pipe 13b, which are the pipes 13 provided on the wall surface 11, are connected to the hot water supply pipe 90a of the faucet main body 90 via the pair of sockets 70. And is connected to the water supply pipe 90b. The socket 70 has a tubular joint 71 and a socket body 72 integrally formed with the joint 71, and the entire shape is a crank type. The joint 71 in the pair of sockets 70 is connected to the hot water pipe 13a and the water pipe 13b on the wall surface 11 by screwing, and the bag nut 72a as the connection portion of the socket body 72 is connected to the hot water supply pipe 90a of the faucet body 90. The faucet body 90 is attached to the wall surface 11 by being connected to the water supply pipe 90b.

JP-A-2010-96296

As shown in FIG. 9B, when the faucet body 90 is attached to the wall surface 11, the distance T between the axes of the bag nuts 72a in the pair of sockets 70 is the hot water supply pipe 90a and the water supply pipe of the faucet body 90. It is required to be equal to the distance between the axes of 90b. Further, the virtual straight line U connecting the ends of the bag nut 72a on the faucet body 90 side is required to be parallel to the wall surface 11. In order to adjust the position of the end portion of the bag nut 72a on the faucet body 90 side, it is necessary to screw the joint 71 of the socket 70, which is more distant from the wall surface 11 of the pair of sockets 70, into the wall surface 11 side. However, since the joint 71 and the socket body 72 rotate integrally, the distance T between the axes of the bag nut 72a also changes as the joint 71 is screwed. Since it is not possible to individually adjust the distance T between the axes of the bag nut 72a and the positions of the ends of the bag nut 72a on the faucet body 90 side, it is difficult to adjust both to suitable positions. I have a problem. The present invention has been made in view of such circumstances, and an object of the present invention is to provide a socket unit, a faucet, and a method for constructing a faucet in which a faucet main body can be easily attached to a suitable position.

The socket unit for solving the above-mentioned problems is a crank-type socket unit for connecting the faucet main body and the wall pipe, and has a tubular joint connected to the wall pipe by screwing and the water. The faucet body is provided with a connecting portion connected to the faucet body, and has a socket body assembled so as to be integrally rotatable with respect to the joint and slidably movable in the axial direction of the joint. The gist is that a stopper member that regulates the movement of the socket body to at least one of the faucet body sides is attached at an arbitrary position.

According to this configuration, by having the socket body assembled so as to be integrally rotatable with respect to the joint and slidable in the axial direction of the joint, the socket body is rotated to adjust the distance between the connecting portions, and then the socket is used. By sliding the main body, the position of the end portion of the faucet main body side between the connecting parts can be adjusted. In addition, the stopper member can regulate the movement of the socket body at an arbitrary position. Since the distance between the connection portions in the pair of sockets and the position of the end portion of the connection portions on the faucet body side can be individually adjusted, it becomes easy to attach the faucet body to a suitable position.

Regarding the socket unit, it is preferable that the stopper member regulates the movement of the socket body toward the wall surface side at an arbitrary position. According to this configuration, the movement of the socket body to the wall surface side can be suitably regulated by the stopper member.

It is preferable that the socket unit has a screw groove formed on the outer periphery of the joint, and the stopper member is attached in a state of being screwed into the screw groove. According to this configuration, the position of the stopper member can be easily adjusted.

It is preferable that the faucet includes the faucet main body and a pair of socket units connected to the faucet main body, and at least one of the pair of socket units is the socket unit. According to this configuration, the faucet can function as the socket unit.

The method of constructing a faucet for solving the above problems is a method of constructing a faucet for connecting a faucet to a hot water pipe on a wall surface and a water pipe, and the faucet is a pair with a faucet main body. It has a socket unit, and the socket unit is attached to a tubular joint, a socket body that is integrally rotatable with respect to the joint and slidable in the axial direction of the joint, and the joint. It has a stopper member that regulates the movement of the socket body to the wall surface side at an arbitrary position, the socket body includes a connection portion connected to the faucet body, and each joint in the pair of socket units. Is screwed into the hot water pipe and the water pipe to be connected, and then the socket body of the pair of socket units whose connection portion of the socket body is further separated from the wall surface is slid toward the wall surface side. The gist is that the stopper member is arranged at a position that restricts the movement of the socket body that has been slid and then moved to the wall surface side.

According to this configuration, the faucet body can be connected by sliding only the socket body whose connection portion of the socket body in the pair of socket units is farther from the wall surface. It will be easy to install in a suitable position.

According to the socket unit of the present invention, it becomes easy to attach the faucet body to a suitable position.

Perspective view of the faucet. Perspective view of the socket unit. An exploded perspective view of the socket unit. FIG. 2 is a sectional view taken along line 4-4 of FIG. (A) to (c) are diagrams for explaining the rotation mechanism of the socket body. (A) to (d) are diagrams illustrating a method of adjusting the position of the socket unit. Sectional view of the socket unit of the modified example. Sectional view of the socket unit of another modified example. (A) is a perspective view of a conventional faucet, and (b) is a plan view of a conventional socket.

An embodiment of the socket unit will be described.
As shown in FIGS. 1 and 2, the wall surface 11 of the bathroom is provided with a hot water pipe and a water pipe (not shown) as pipes. A crank-type socket unit 20 is connected to each of the hot water pipe and the water pipe, and the connection portion between the hot water pipe and the water pipe and the socket unit 20 is covered with a cover 14. The socket unit 20 has a hollow plate-like shape that is integrally rotatable with respect to the tubular joint 30 connected to the hot water pipe and the water pipe by screwing and slidable in the axial direction of the joint 30. It has a socket body 40. Further, the socket unit 20 has a stopper member 50 that regulates the movement of the socket body 40 toward the wall surface 11 at an arbitrary position.

The socket body 40 includes a connecting portion 60 at the other end on the opposite side of the socket body 40, which is opposite to the one end attached to the joint 30. The faucet body 12 is attached to the wall surface 11 by connecting the connection portion 60 of the socket body 40 to the hot water supply pipe and the water supply pipe (not shown) of the faucet body 12. With the faucet body 12 attached to the wall surface 11, the hot water pipe and the hot water supplied from the water pipe circulate inside the joint 30 of the socket unit 20 and the socket body 40, and the faucet body 12 It is configured to be supplied to the hot water supply pipe and the water supply pipe. The faucet 10 includes a faucet main body 12 and a socket unit 20, and functions as a mixing faucet capable of mixing hot water and switching between spouting and stopping of mixed water.

The joint 30, the socket body 40, and the stopper member 50 constituting the socket unit 20 will be described.
The joint 30 will be described.

As shown in FIGS. 3 and 4, the joint 30 is formed in a tubular shape. A threaded groove portion 31 having a threaded groove is provided on the outer periphery of the joint 30 on the one end side from the central portion in the axial direction. The thread groove portion 31 is provided with a locking groove 33 for locking the retaining ring 32 for regulating the position of the stopper member 50. The locking groove 33 is provided for one circumference in the circumferential direction of the joint 30, and the depth of the locking groove 33 is formed deeper than the depth of the groove of the threaded groove portion 31.

A first enlarged diameter portion 34 having a diameter larger than that of the screw groove portion 31 is formed on the other end side of the joint 30 in the axial direction of the thread groove portion 31. A first connecting surface 37a connecting the screw groove portion 31 and the first diameter expansion portion 34 is formed between the screw groove portion 31 and the first diameter expansion portion 34. The first connecting surface 37a is formed of a plane along the radial direction of the joint 30. A second diameter-expanded portion 35 having a diameter larger than that of the first diameter-expanded portion 34 is formed on the other end side of the joint 30 with respect to the first diameter-expanded portion 34. A second connecting surface 37b connecting the first diameter-expanded portion 34 and the second diameter-expanded portion 35 is formed between the first diameter-expanded portion 34 and the second diameter-expanded portion 35. The second connecting surface 37b is formed of a plane along the radial direction of the joint 30. An annular washer 38 having substantially the same shape as the second connecting surface 37b is arranged on the second connecting surface 37b. A third diameter-expanded portion 36 having a diameter larger than that of the second diameter-expanded portion 35 is formed on the other end side of the joint 30 with respect to the second diameter-expanded portion 35. The third diameter-expanded portion 36 is located at the other end of the joint 30. Grooves 34a and 36a are formed on the entire circumference of the outer periphery of the first diameter-expanded portion 34 and the third diameter-expanded portion 36, and O-rings 34b and 36b are arranged in the recessed grooves 34a and 36a. As will be described later, these O-rings 34b and 36b are positioned between the first diameter-expanded portion 34 and the third diameter-expanded portion 36 by abutting the first peripheral wall 41b and the second peripheral wall 42d of the socket body 40. The outer peripheral side of the second enlarged diameter portion 35 and the inner peripheral side of the socket body 40 are configured to be in a watertight state. The second enlarged diameter portion 35 is formed with a hole 35a that penetrates the joint 30 in the radial direction. On the outer circumference of the second enlarged diameter portion 35, one outer convex portion 35b is formed so as to project outward in the radial direction. The tip of the outer convex portion 35b is configured to be substantially equal to the outer diameter of the third enlarged diameter portion 36. A water stop valve 39 is attached to the joint 30 in a state of being inserted from the third diameter expansion portion 36 side.

The socket body 40 will be described.
As shown in FIGS. 3 and 4, the socket body 40 includes a pair of long vertical walls arranged to face each other and a connecting wall 43 connecting the peripheral edges of the pair of vertical walls, and has a hollow plate shape. It is configured. A circular first through hole 41a is formed on one end side of the first vertical wall 41, which is one of the vertical walls. The inner diameter of the first through hole 41a is slightly larger than the outer diameter of the first enlarged diameter portion 34 of the joint 30, and smaller than the outer diameter of the second enlarged diameter portion 35 of the joint 30. On one end side of the second vertical wall 42, which is the other vertical wall, a circular second through hole 42a is formed at a position on the same axis as the first through hole 41a. The inner diameter of the second through hole 42a is larger than the inner diameter of the first through hole 41a. The inner diameter of the second through hole 42a is slightly larger than the outer diameter of the third enlarged diameter portion 36 of the joint 30. A circular third through hole 42b is formed on the other end side of the second vertical wall 42. A screw groove 42c is formed on the inner circumference of the third through hole 42b. A bag nut 60b is attached to the screw groove 42c via a glan 60a. The gran 60a and the bag nut 60b constitute a hot water supply pipe of the faucet main body 12 and a connection portion 60 connected to the water supply pipe.

On the outer surface of the first vertical wall 41, a first peripheral wall 41b is formed which projects outward from the peripheral edge of the first through hole 41a in the thickness direction of the first vertical wall 41. On the inner surface of the first vertical wall 41, a circular step portion 41d having a thin thickness of the first vertical wall 41 is formed on the peripheral edge of the first through hole 41a. The outer diameter of the step portion 41d is slightly larger than the outer diameter of the second enlarged diameter portion 35 of the joint 30. On the inner surface of the second vertical wall 42, a second peripheral wall 42d protruding inward in the thickness direction of the second vertical wall 42 from the peripheral edge of the second through hole 42a is formed. The second peripheral wall 42d is composed of a portion where the wall thickness of the second vertical wall 42 is partially thickened toward the inside of the socket body 40, and an inner circumference of the connecting wall 43. At the position between the first through hole 41a and the second through hole 42a on the connection wall 43 of the socket body 40, one inward convex portion 43a protruding inward of the socket body 40 is formed. When the socket body 40 is assembled to the joint 30, the inner convex portion 43a is arranged at a position overlapping the outer convex portion 35b of the joint 30 along the circumferential direction of the joint 30.

The stopper member 50 will be described.
As shown in FIGS. 3 and 4, the stopper member 50 is formed in an annular shape, and a screw groove 50a is formed on the inner circumference. The stopper member 50 is attached to the joint 30 by screwing the thread groove 50a into the thread groove portion 31 of the joint 30. By changing the screwing position of the stopper member 50, the stopper member 50 can be arranged at an arbitrary position in the thread groove portion 31 of the joint 30. The surfaces 50b on both sides of the stopper member 50 in the axial direction are formed of a flat surface. As will be described later, the surface 50b of the stopper member 50 comes into contact with the first connecting surface 37a of the joint 30 in a state where each member of the socket unit 20 is assembled. Further, a slight gap W is formed between the tip end surface 41c of the first peripheral wall 41b of the socket body 40 and the surface 50b of the stopper member 50. By forming this gap W, idling of the socket body 40 is allowed. Further, when the socket body 40 moves to the wall surface 11, the surface 50b of the stopper member 50 comes into contact with the tip end surface 41c of the first peripheral wall 41b of the socket body 40, so that the socket body 40 to the wall surface 11 side. Movement is restricted. The stopper member 50 is located on the other end side of the joint 30 with respect to the locking groove 33 of the joint 30 in a state where the surface 50b of the stopper member 50 is in contact with the tip end surface 41c of the first peripheral wall 41b of the socket body 40. It is configured as follows.

A method of assembling each member constituting the socket unit 20 will be described.
As shown in FIG. 4, the screw groove portion 31 on one end side of the joint 30 is inserted into the second through hole 42a of the socket body 40, and the screw groove portion 31 is projected from the first through hole 41a of the socket body 40. The second connecting surface 37b between the first enlarged diameter portion 34 and the second enlarged diameter portion 35 of the joint 30 is housed in the stepped portion 41d of the socket body 40 together with the washer 38. When the second connecting surface 37b comes into contact with the stepped portion 41d via the washer 38, the joint 30 is further restricted from protruding from the first through hole 41a.

Next, the stopper member 50 is screwed into the thread groove portion 31 of the joint 30. The surface 50b of the stopper member 50 is brought into contact with the first connecting surface 37a of the joint 30. In this state, a slight gap W is formed between the tip end surface 41c of the first peripheral wall 41b of the socket body 40 and the surface 50b of the stopper member 50. Next, the retaining ring 32 is locked in the locking groove 33 of the joint 30. By locking the retaining ring 32 in the locking groove 33, it is possible to regulate the movement of the stopper member 50 toward one end side of the joint 30 with respect to the retaining ring 32. As a result, it is possible to secure a predetermined length required for connection with the pipe 13 in the thread groove portion 31 of the joint 30. Next, the bag nut 60b is attached to the third through hole 42b of the socket body 40 via the glan 60a. Further, the water stop valve 39 is attached to the second through hole 42a of the socket body 40. By the above method, each member constituting the socket unit 20 is assembled. The order in which each member is assembled can be changed as appropriate.

As shown in FIG. 4, in the state where each member is assembled, the socket unit 20 has the joint 30 and the bag nut 60b protruding in opposite directions from one end side and the other end side in the longitudinal direction of the socket body 40. It has a so-called crank-shaped shape.

In the state where each member is assembled, the first diameter-expanded portion 34 of the joint 30 and the first peripheral wall 41b of the socket body 40 are positioned so as to overlap in the radial direction of the joint 30, and the O-ring 34b of the first diameter-expanded portion 34 It abuts on the first peripheral wall 41b. Further, the third diameter-expanded portion 36 of the joint 30 and the second peripheral wall 42d of the socket body 40 are located at overlapping positions in the radial direction of the joint 30, and the O-ring 36b of the third diameter-expanded portion 36 comes into contact with the second peripheral wall 42d. .. The other end of the third enlarged diameter portion 36 is substantially flush with the outer surface of the second vertical wall 42 of the socket body 40. Further, the outer convex portion 35b of the second enlarged diameter portion 35 of the joint 30 and the inner convex portion 43a of the socket body 40 are at positions where they can come into contact with each other in the circumferential direction of the joint 30.

Since the socket body 40 and the joint 30 are assembled in a state where the two O-rings 34b and 36b are in contact with each other, the second diameter expansion portion located between the first diameter expansion portion 34 and the third diameter expansion portion 36 is located. The outer peripheral side of the portion 35 and the inner peripheral side of the socket body 40 are in a watertight state. Further, the socket body 40 can be rotated with respect to the joint 30. Further, when the position of the stopper member 50 is adjusted so that the surface 50b of the stopper member 50 and the tip end surface 41c of the first peripheral wall 41b of the socket body 40 do not come into contact with each other, the two O-rings 34b and 36b are formed. The socket body 40 can be slid and moved within the range of contact between the first peripheral wall 41b and the second peripheral wall 42d.

The rotation mechanism of the socket body 40 will be described.
As shown in FIG. 5A, when the inner convex portion 43a of the socket body 40 and the outer convex portion 35b of the joint 30 are in contact with each other, the socket body 40 is rotated in the direction of the arrow (clockwise in the drawing). Then, the joint 30 also rotates as one. That is, the socket body 40 and the joint 30 can be integrally rotated.

As shown in FIG. 5 (b), when the socket body 40 is rotated in the direction of the arrow (counterclockwise in the figure) from the state of FIG. 5 (a), the inner convex portion 43a and the outer convex portion 35b are in contact with each other. Is released, so that only the socket body 40 can be rotated, that is, the socket body 40 can be idled.

As shown in FIG. 5 (c), when the socket body 40 is further rotated in the direction of the arrow (counterclockwise in the drawing), the inner convex portion 43a and the outer convex portion 35b become different from each other in FIG. 5 (a). It will be in contact from the opposite side. The socket body 40 can be idled in the range where the inner convex portion 43a and the outer convex portion 35b come into contact with each other. That is, the socket body 40 is configured to be able to idle in a range of less than 360 degrees with respect to the joint 30.

A method of adjusting the position of the socket unit 20 will be described with reference to FIGS. 6A to 6D. In FIGS. 6A to 6D, the cover 14 is omitted for convenience. Further, the gap W between the surface 50b of the stopper member 50 and the tip end surface 41c of the first peripheral wall 41b of the socket body 40 is also omitted.

As shown in FIG. 6A, a pair of socket units 20 are attached to the pipe 13 of the wall surface 11. Specifically, the socket unit 20 is connected to the pipe 13 by screwing the thread groove portion 31 of each socket unit 20 into the pipe 13. At that time, by applying a force to the socket body 40 in the direction of rotation about the joint 30, the socket body 40 and the joint 30 can be integrally rotated and the socket unit 20 can be screwed. The hot water supply pipe and the water supply pipe (not shown) of the faucet body are temporarily fixed to the bag nuts 60b of the pair of socket units 20 in a temporarily fixed state.

As shown by an arrow in FIG. 6 (b), of the pair of socket units 20, the stopper member 50 of the socket unit 20 whose end of the bag nut 60b on the faucet body side is farther away from the wall surface 11. Is moved to the wall surface 11 side. By moving the stopper member 50 toward the wall surface 11, a gap S is formed between the tip end surface 41c of the first peripheral wall 41b of the socket body 40 and the surface 50b of the stopper member 50.

As shown by an arrow in FIG. 6 (c), the socket body 40 is slid to the wall surface 11 side to position the end of the bag nut 60b on the faucet body side so that the bag nut 60b in the other socket unit 20 is positioned. Make it the same position as the end of the faucet body side. That is, the virtual straight line connecting the ends of the bag nut 60b on the faucet body side is made parallel to the wall surface 11.

As shown by an arrow in FIG. 6D, the stopper member 50 is moved so that the surface 50b of the stopper member 50 comes into contact with the distal end surface 41c of the first peripheral wall 41b of the socket body 40. As a result, the movement of the socket body 40 to the wall surface 11 side is restricted. In this state, by mainly connecting each bag nut 60b to the hot water supply pipe and the water supply pipe of the faucet main body, the faucet main body is attached in parallel to the wall surface 11.

The action and effect of this embodiment will be described.
(1) The socket body 40 is assembled so as to be integrally rotatable with respect to the joint 30 and slidably movable in the axial direction of the joint 30, and the joint 30 can arbitrarily move the socket body 40 to the wall surface 11 side. A stopper member 50 that regulates the position is attached.

After rotating the socket body 40 to adjust the distance between the bag nuts 60b, the socket body 40 can be slid to adjust the position of the end portion of the bag nuts 60b on the faucet body 12 side. Further, the stopper member 50 can regulate the movement of the socket body 40 toward the wall surface 11 at an arbitrary position.

Therefore, the distance between the bag nuts 60b in the pair of socket units 20 and the position of the end portion of the bag nuts 60b on the faucet body 12 side can be individually adjusted, so that the faucet body 12 is in a suitable position. Easy to install on. Further, since the stopper member 50 is attached, it is possible to suppress the rattling of the faucet main body 12 after being attached to the pipe 13.

(2) When the screw groove portion 31 of each socket unit 20 is screwed into the pipe 13 for connection, the operator does not need to precisely adjust the position of the end portion of each bag nut 60b on the faucet body 12 side. That is, the operator may screw the thread groove portion 31 into the pipe 13 so that the positions of the ends of the bag nuts 60b on the faucet body 12 side are substantially the same. With the hot water supply pipe and water supply pipe of the faucet body 12 temporarily connected to each bag nut 60b of the socket unit 20 connected in this way, the faucet body 12 is parallel to the wall surface 11. Since the positions of 12 can be adjusted, work efficiency can be improved.

(3) A thread groove portion 31 is formed on the outer periphery of the joint 30, and the stopper member 50 is attached in a state of being screwed into the thread groove portion 31. Therefore, the position of the stopper member 50 can be easily adjusted. Further, it is possible to prevent the stopper member 50 from being easily detached from the joint 30.

(4) After each joint 30 in the pair of socket units 20 is screwed into the pipe 13 to be connected, the socket body of the pair of socket units 20 in which the connection portion 60 of the socket body 40 is further separated from the wall surface 11. The 40 is slid to the wall surface 11 side. After that, the stopper member 50 is arranged at a position that restricts the slide movement of the socket body 40 toward the wall surface 11.

Therefore, the faucet body 12 can be connected by sliding only the socket body 40 whose connection portion 60 of the socket body 40 in the pair of socket units 20 is farther from the wall surface 11. It becomes easy to attach the main body 12 to a suitable position. Further, when the stopper member 50 of one of the socket units 20 that is not slidably moved is located on the farthest end side, the socket body 40 of the one socket unit 20 has the surface 50b of the stopper member 50 and the socket body 40. The movement in the sliding direction is restricted except for the gap W between the first peripheral wall 41b and the tip end surface 41c. Therefore, rattling can be suppressed as compared with the case where both socket units 20 have a range of motion.

This embodiment can be modified and implemented as follows. The present embodiment and the following modified examples can be implemented in combination with each other within a technically consistent range.
In the present embodiment, the faucet body 12 is made parallel to the wall surface 11 by adjusting the position of the socket body 40 in a state where the hot water supply pipe and the water supply pipe of the faucet body 12 are temporarily connected to each bag nut 60b. The position of the faucet main body 12 was adjusted, and then the faucet main body 12 was mainly connected, but the present invention is not limited to this mode. The faucet body 12 may be connected after adjusting so that the virtual straight line connecting the ends of the bag nuts 60b on the faucet body 12 side is parallel to the wall surface 11. That is, the temporary connection of the faucet body 12 may be omitted.

The washer 38 arranged on the second connecting surface 37b that joins the first enlarged diameter portion 34 and the second enlarged diameter portion 35 of the joint 30 may be omitted.
-The retaining ring 32 attached to the joint 30 may be omitted. Similarly, the threaded groove 31 of the joint 30 may be configured without having a locking groove 33 to which the retaining ring 32 is attached.

The water stop valve 39 attached to the second through hole 42a of the joint 30 may be omitted. That is, the joint 30 may be configured without having a function as a water stop valve.

-In the present embodiment, the stopper member 50 is screwed into the thread groove portion 31 of the joint 30, but the present embodiment is not limited to this embodiment. For example, in the joint 30, a screw groove for screwing the stopper member 50 may be provided separately from the screw groove portion 31 screwed into the pipe 13.

In the present embodiment, a gap W is formed between the surface 50b of the stopper member 50 and the tip end surface 41c of the first peripheral wall 41b of the socket body 40 in a state where each member of the socket unit 20 is assembled. However, this gap W may not be formed. That is, the surface 50b of the stopper member 50 and the tip end surface 41c of the first peripheral wall 41b of the socket body 40 may be assembled in contact with each other within a range in which the socket body 40 is allowed to idle.

The stopper member 50 is not limited to the mode composed of the annular member. A member that can be arranged at a predetermined position of the joint 30 can be appropriately adopted. For example, the stopper member 50 may be composed of a C ring and may be configured so that it can be locked at a predetermined position of the thread groove portion 31 of the joint 30.

A spacer member may be interposed between the surface 50b of the stopper member 50 and the tip end surface 41c of the first peripheral wall 41b of the socket body 40. The movement of the socket body 40 may be restricted by interposing the spacer member.

-In the present embodiment, the socket body 40 is configured so that it can idle with respect to the joint 30, but the present embodiment is not limited to this mode. That is, the socket body 40 may be configured so that it can slide with respect to the joint 30 but cannot run idle. Even if it is configured so that it cannot run idle, the distance between the bag nuts 60b constituting the connection portion 60 in the pair of socket units 20 can be adjusted by integrally rotating the socket body 40 and the joint 30. Further, by adjusting the distance between the bag nuts 60b and then sliding the socket body 40, the position of the end portion of the bag nut 60b on the faucet body 12 side can be moved to the bag nut 60b in the other socket unit 20. It can be aligned with the position of the end of the faucet body 12 side. As a result, the virtual straight line connecting the ends of the bag nuts 60b on the faucet body 12 side can be made parallel to the wall surface 11.

The socket body 40 may be configured so that it can idle 360 degrees or more with respect to the joint 30. For example, if the outer shape of the joint 30 is shaped so that a force can be directly applied in the rotation direction and the joint 30 can be directly rotated and screwed into the pipe 13, the socket main body. The 40 may be configured so that it can idle 360 degrees or more with respect to the joint 30.

-In the present embodiment, the socket body 40 of the socket unit 20 is configured in the shape of a hollow plate, but the present invention is not limited to this embodiment. The socket body 40 may be formed in a tubular shape as long as it is configured so that hot water flows through the inside.

-In the present embodiment, the stopper member 50 restricts the movement of the socket body 40 to the wall surface 11 side at an arbitrary position, but the present invention is not limited to this embodiment. The stopper member 50 may be configured so that the movement of the socket body 40 to the faucet body side can be restricted at an arbitrary position, or the socket body 40b to both the faucet body side and the wall surface side. It may be configured so that the movement of the faucet can be regulated at any position.

For example, as shown in FIG. 7, a screw groove portion 31a is formed on the outer surface of the other end side of the joint 30a, and the screw groove portion 31a is inserted from the first through hole 41e side of the socket body 40a to penetrate the second through. It may be configured so as to protrude from the hole 42e side. By attaching the stopper member 50 to the screw groove portion 31a in a screwed state, the movement of the socket body 40a to the faucet body side can be restricted at an arbitrary position.

Further, for example, as shown in FIG. 8, the stopper member 50 may be arranged in both the thread groove portion 31b on one end side and the thread groove portion 31a on the other end side of the joint 30b. Each stopper member 50 can regulate the movement of the socket body to both the faucet body side and the wall surface side at an arbitrary position.

-Although the socket unit 20 of the present embodiment is connected to both the hot water pipe and the water pipe, it may be connected to only one of the hot water pipe and the water pipe. That is, the socket unit 20 of the present embodiment may be connected to either one of the hot water pipe and the water pipe, and a conventional socket may be connected to either one of the hot water pipe and the water pipe. Even if the socket unit 20 of the present embodiment is connected to only one of the hot water pipe and the water pipe, the socket body 40 of the socket unit 20 of the present embodiment is based on the conventional socket. By adjusting the position, the faucet body 12 can be easily attached to a suitable position.

-In the present embodiment, the positions of the pair of socket bodies 40 are adjusted so that the virtual straight line connecting the ends of the bag nut 60b on the faucet body 12 side is parallel to the wall surface 11. However, it is not limited to this aspect. For example, the positions of the pair of socket bodies 40 may be adjusted so that the virtual straight line connecting the ends of the bag nut 60b on the faucet body 12 side has a predetermined angle with respect to the wall surface 11. Good.

11 ... Wall surface, 12 ... Faucet body, 13 ... Piping, 30 ... Joint, 40 ... Socket body, 50 ... Stopper member, 60 ... Connection part.

Claims (5)

A crank-type socket unit for connecting the faucet body and the piping on the wall surface.
A tubular joint that is screwed into the wall pipe and
It is provided with a connection portion connected to the faucet body, and has a socket body assembled so as to be integrally rotatable with respect to the joint and slidable in the axial direction of the joint.
A socket unit characterized in that a stopper member for restricting the movement of the socket body to at least one of the wall surface side and the faucet body side at an arbitrary position is attached to the joint. The socket unit according to claim 1, wherein the stopper member regulates the movement of the socket body to the wall surface side at an arbitrary position. A thread groove is formed on the outer circumference of the joint.
The socket unit according to claim 1 or 2, wherein the stopper member is attached in a state of being screwed into the screw groove. The faucet body and a pair of socket units connected to the faucet body are provided.
A faucet in which at least one of the pair of socket units is the socket unit according to any one of claims 1 to 3. It is a method of constructing a faucet that connects a faucet to a hot water pipe and a water pipe on the wall surface.
The faucet has a faucet body and a pair of socket units.
The socket unit includes a tubular joint, a socket body that is integrally rotatable with respect to the joint and slidably movable in the axial direction of the joint, and the socket that is attached to the joint and is attached to the wall surface side. It has a stopper member that regulates the movement of the main body at an arbitrary position,
The socket body comprises a connection that is connected to the faucet body.
After each joint in the pair of socket units is screwed into the hot water pipe and the water pipe and connected,
After sliding the socket body of the pair of socket units whose connection portion of the socket body is farther from the wall surface to the wall surface side,
A method for constructing a faucet, which comprises arranging the stopper member at a position for restricting the slide movement of the socket body to the wall surface side.