JP7433921B2 - water discharging device - Google Patents

Description

The present disclosure relates to a water discharging device.

2. Description of the Related Art Conventionally, water discharging devices are known in which shower water is discharged from an arm. For example, in the water discharging device described in Patent Document 1 below, arms are connected to both left and right sides of a mixing faucet. Each arm is provided with a water spout. The water spouts are arranged at regular intervals in the longitudinal direction of the arm. Water generated in the mixing faucet is supplied to the arm and is spouted from the spout.

Japanese Patent Application Publication No. 2015-52357

In the water spouting device configured as above, all the spouts are fixed to the arm, so it is not possible to change the position or direction of some of the spouts provided on the arm. could not.

The present disclosure has been completed based on the above circumstances, and provides a water spouting device that can change the position and direction of some water spouts provided on an arm with respect to other water spouts. The purpose is to

The water spouting device of the present disclosure includes an arm having a main body and a movable part that moves relative to the main body, and a water spout is provided in each of the main body and the movable part. It is something.

A perspective view showing a water discharging device Front view showing the water discharging device A partially enlarged front view showing the lower end of the water discharging device with the mirror surface removed. FIG. 4 is a cross-sectional view showing the lower end of the water discharging device with the mirror surface removed, and corresponds to the cross-section at the AA position in FIG. 3. Partially enlarged perspective view showing the connection between the housing and the arm FIG. 5 is a partially enlarged cross-sectional view showing the connecting portion between the casing and the arm, and corresponds to the cross-section at the DD position in FIG. 4. Partially enlarged sectional view showing the connection between the main body of the arm and the movable part Front view showing the first nozzle 9 is a cross-sectional view showing the first nozzle, which corresponds to the cross-section at the CC position in FIG. 8. 7 is a cross-sectional view showing how the movable part moves relative to the main body, and corresponds to the cross-section at the BB position in FIG. 7.

<Embodiment>
The water discharging device M is a shower device fixed to a mounting wall W of a bathroom. Hereinafter, for each component, the upper side (the positive side of the Z axis in Figure 1) when the water discharging device M is attached to the mounting wall W of the bathroom is referred to as the upper side, and the lower side (the negative side of the Z axis in Figure 1) is referred to as the upper side. On the lower side, when looking at the water discharging device M from the front, the left side (the negative side of the Y axis in Figure 1) is the left side, the right side (the positive side of the Y axis in Figure 1) is the right side, and the inside of the bathroom (X in Figure 1). The positive side of the axis) will be referred to as the front side, and the side opposite to the inside of the bathroom (the negative side of the X axis in FIG. 1) will be referred to as the rear side.

The water discharging device M includes a housing 10 and a pair of first arms 50F and second arms 50S. The water discharging device M includes a faucet connection portion 10A (see FIGS. 2 and 3). A water supply hose extending from a faucet body (not shown) is connected to the faucet connection portion 10A. The faucet body has a flow rate adjustment function and a temperature adjustment function. The faucet main body switches between water spouting from a faucet (not shown) and water spouting from a shower (hand shower and body shower described later). The water discharging device M includes a hand shower connection portion 10B to which a shower hose extending from a hand shower (not shown) is connected.

The water discharging device M is provided with an operation unit 11 that switches between a hand shower and a shower from the first and second arms 50F, 50S (referred to as a body shower). The operating portion 11 protrudes downward from the lower surface of the water discharging device M (see FIG. 2). By manually operating the operating unit 11, a hand shower and a body shower can be switched. Specifically, by pushing the operating portion 11 downward, the hand shower is switched to the body shower. By pulling up the operating part 11, the body shower is switched to a hand shower. When the faucet main body is turned off while the body shower is switched to the body shower state, or when the faucet main body is switched from the shower to faucet water discharging, the operation unit 11 automatically returns to its original state (water discharging from the hand shower). Return.

The housing 10 is fixed to a mounting wall W. The first arm 50F is provided on the left side of the housing 10. The second arm 50S is provided on the right side of the housing 10. The first arm 50F is rotatable about the imaginary first rotation axis Z1 with respect to the housing 10. The second arm 50S is rotatable about the imaginary second rotation axis Z2 with respect to the housing 10. As shown in FIG. 3, the first and second arms 50F, 50S are rotated to be in a retracted state (indicated by a two-dot chain line in FIGS. 1 and 2) and a drawn-out state (indicated by a solid line in FIGS. 1 and 2). ).

The first and second arms 50F and 50S in the stored state are arranged along the left side and right side of the housing 10. Arm receivers 12 are provided on the left and right side surfaces of the housing 10, with which the first and second arms 50F and 50S in the stored state come into contact (see FIG. 1). The first and second arms 50F, 50S are prevented from contacting the mounting wall W by contacting the arm receiving portion 12. A receiving groove portion 51 into which the arm receiving portion 12 fits is formed in the first and second arms 50F, 50S.

The first and second arms 50F, 50S in the drawn out state are arranged at arbitrary positions extending from the mounting wall W. The first and second arms 50F, 50S can each rotate independently. By adjusting the rotation angles of the first and second arms 50F, 50S, the user can use the body shower in a standing position or in a sitting position. As shown in FIG. 2, the distance in the left-right direction between the tips of the first and second arms 50F, 50S in the pulled out state and the virtual plane P perpendicular to the mounting wall W at the center position in the left-right direction of the housing 10 is It is larger than the distance in the left-right direction between the tips of the first and second arms 50F, 50S and the virtual plane P in the state. In the pulled out state, the first and second arms 50F, 50S are spaced apart in the left-right direction compared to the first and second arms 50F, 50S in the stored state.

A mirror surface section 13 is provided on the front surface of the housing 10. The mirror surface portion 13 is held by a base member made of synthetic resin (for example, ABS resin).

As shown in FIG. 3, the first and second rotation axes Z1 and Z2 are provided at the lower ends of the first and second arms 50F and 50S in the stored state. The first and second rotation axes Z1 and Z2 are arranged horizontally in a state where the water discharging device M is attached to the mounting wall W. The first and second rotation axes Z1 and Z2 are arranged at the same height position when the water discharging device M is attached to the mounting wall W.

The first and second rotation axes Z1 and Z2 are inclined with respect to the mounting wall W when the water discharging device M is attached to the mounting wall W, as shown in FIG. As for the first and second rotation axes Z1 and Z2, the center side in the left-right direction of the housing 10 is located in front of the end side in the left-right direction. The first and second rotation axes Z1 and Z2 intersect at the center position of the housing 10 in the left-right direction.

As shown in FIG. 4, the left and right side surfaces of the housing 10 are provided with inclined portions 10S that are inclined along the rotation loci of the first and second arms 50F and 50S. The inclined portion 10S is formed in the front region of the side surface of the housing 10. The first and second arms 50F, 50S are connected to the housing 10 within the inclined portion 10S.

When the water discharging device M is attached to the mounting wall W, a clearance S is secured between the first and second arms 50F, 50S and the mounting wall W, as shown in FIG. This clearance S allows the first and second arms 50F, 50S to rotate approximately 180 degrees without contacting the mounting wall W. The clearance S is larger than the minimum size necessary for rotation of the first and second arms 50F, 50S. The size of the clearance S is such that a finger is not caught between the first and second arms 50F, 50S and the mounting wall W. The thickness dimension (dimension in the front-rear direction) of the casing 10 is such that the clearance S can be secured.

As shown in FIGS. 3 and 4, the lower end of the housing 10 is provided with a frame 15 to which first and second arms 50F and 50S are rotatably connected. The frame 15 is made of metal (for example, SUS304). The frame 15 includes a main frame 16, a subframe 17, and an arm fixing frame 18.

The main frame 16 is located on the rear side of the housing 10. The main frame 16 has a wall shape that spans the entire width of the housing 10 in the left-right direction. The subframe 17 and the arm fixing frame 18 are provided at both left and right ends of the main frame 16. The subframe 17 is fixed to the front surface of the main frame 16 by welding. The arm fixing frame 18 is fixed to the front surface of the subframe 17 with screws.

As shown in FIG. 5, the arm fixing frame 18 integrally includes a pair of left and right side portions 18A, an upper surface portion 18B, and a rear surface portion 18C. The upper surface portion 18B connects the upper ends of the pair of left and right side portions 18A. The rear surface portion 18C connects the rear ends of the pair of left and right side portions 18A. The rear surface portion 18C runs along the front surface of the subframe 17.

The upper surface portion 18B of the arm fixed frame 18 is provided with a frame-side spring locking portion 19 to which end portions of first and second torsion springs 39F and 39S, which will be described later, are locked. The frame-side spring locking portion 19 is formed by cutting out a portion of the upper surface portion 18B.

As shown in FIG. 6, the left and right side portions 18A of the arm fixing frame 18 are formed with a first penetration portion 21 and a second penetration portion 22 that penetrate in the left-right direction. The first penetrating portion 21 is formed in the side surface portion 18A located on the center side (left side in FIG. 6) of the housing 10 in the left-right direction. The second penetrating portion 22 is formed in the side surface portion 18A located on the end side (the right side in FIG. 6) of the housing 10 in the left-right direction. The first penetrating portion 21 and the second penetrating portion 22 have a generally circular shape. The first penetrating portion 21 and the second penetrating portion 22 are coaxially formed.

As shown in FIG. 6, a protrusion 23 protrudes from the periphery of the first penetrating portion 21. As shown in FIG. The protrusion 23 fits into a notched groove 31C formed in the first and second arm holding members 31F and 31S, which will be described later, and prevents the first and second arm holding members 31F and 31S from rotating. The second penetrating portion 22 is one size larger than the first penetrating portion 21 . Arm end housings 52 provided at the ends of first and second arms 50F and 50S, which will be described later, fit into the second penetration portion 22.

As shown in FIG. 3, the frame 15 holds a switching valve 24, a residual water discharge valve 25, an internal pipe 26, and first and second work sections 30F and 30S. The switching valve 24 is fixed to the center portion of the frame 15 in the left-right direction. The switching valve 24 switches between a hand shower and a body shower by operating the operating section 11.

The internal pipe 26 includes a water supply pipe 26A, a hand shower pipe 26B, a body shower pipe 26C, and a branch pipe 26D. A faucet connection portion 10A is provided at one end of the water supply pipe 26A. The other end of the water supply pipe 26A is connected to the switching valve 24. A hand shower connection portion 10B is provided at one end of the hand shower piping 26B. The other end of the hand shower pipe 26B is connected to the switching valve 24. The water supply pipe 26A and the hand shower pipe 26B are arranged in a space formed between the main frame 16 and the subframe 17, as shown in FIG. One end of the body shower pipe 26C is connected to the switching valve 24, and the other end is connected to the branch pipe 26D. The branch pipe 26D branches water supplied from the body shower pipe 26C to the water passage R of the first and second arms 50F and 50S. Water in this specification refers not only to cold water but also to liquid water at any temperature.

The residual water discharge valve 25 is provided in the branch pipe 26D. The residual water discharge valve 25 discharges the residual water in the water passages R of the first and second arms 50F, 50S. The residual water discharge valve 25 is fixed to the center portion of the frame 15 in the left-right direction.

When the first arm 50F rotates, the first work section 30F performs work on the first arm 50F in the rotational direction. The second work unit 30S performs work on the second arm 50S in the rotational direction when the second arm 50S rotates. As shown in FIG. 4, the first and second work sections 30F and 30S are provided one each for the first and second arms 50F and 50S. The first and second work sections 30F, 30S are arranged between the first and second arms 50F, 50S. The first work section 30F includes a first arm holding member 31F, a first braking mechanism 32F, and a first elastic member 33F. The second work section 30S includes a second arm holding member 31S, a second braking mechanism 32S, and a second elastic member 33S.

The first and second arm holding members 31F and 31S are fixed to the frame 15, as shown in FIG. FIG. 6 shows only the second arm holding member 31S. The first arm holding member 31F rotatably holds the first arm 50F. The second arm holding member 31S rotatably holds the second arm 50S. The first and second arm holding members 31F, 31S are made of metal (for example, C3604). The first and second arm holding members 31F, 31S have a shaft portion 31A and a flange portion 31B. The shaft portion 31A has a cylindrical shape. The inside of the shaft portion 31A is a through hole that is open at both ends in the axial direction. The shaft portion 31A passes through the first penetration portion 21 and the second penetration portion 22 of the arm fixing frame 18.

A spring guide 34 and a bush 35 are attached to the outer peripheral surface of the shaft portion 31A. The spring guide 34 and the bush 35 are made of synthetic resin (for example, POM). A notch groove 31C is formed at the end of the shaft portion 31A. The notch groove 31C extends from the end surface of the shaft portion 31A in a direction along the axis of the shaft portion 31A. A protrusion 23 provided in the first penetrating portion 21 is engaged with the notch groove 31C. The flange portion 31B is provided at the end of the shaft portion 31A. The flange portion 31B has an annular shape. The flange portion 31B is accommodated in the component accommodating portion 53 of the arm end housing 52 provided at each end of the first and second arms 50F, 50S, and is locked to the step portion 54.

Arm end housing 52 is fixed to each end of the first and second arms 50F, 50S. The arm end housing 52 rotates together with the first and second arms 50F, 50S. The arm end housing 52 is made of metal (for example, C3604). The arm end housing 52 has a cylindrical shape. Inside the arm end housing 52 is a component storage section 53 that accommodates components constituting either the first or second work section 30F or 30S. A cross section of the component accommodating portion 53 perpendicular to the axis of the arm end housing 52 has a circular shape. Both ends of the component accommodating portion 53 in the axial direction are open. The axis of the arm end housing 52 fixed to the first arm 50F coincides with the first rotation axis Z1. The axis of the arm end housing 52 fixed to the second arm 50S coincides with the second rotation axis Z2.

The arm end housing 52 has an arm-side fitting portion 55 that fits into either the first or second arm 50F or 50S, and a frame-side fitting portion 56 that fits into the frame 15. A lock nut 57 is fixed to the opening of the arm side fitting part 55. The lock nut 57 is made of metal (for example, C3604). The center of the lock nut 57 is open.

The frame side fitting portion 56 protrudes from the outer surfaces of the first and second arms 50F, 50S. The frame side fitting portion 56 fits into the second penetration portion 22 of the arm fixing frame 18 . The frame side fitting portion 56 rotates with respect to the arm fixed frame 18.

As shown in FIG. 5, the frame side fitting portion 56 is provided with an arm side spring locking portion 58 that locks end portions of first and second torsion springs 39F and 39S, which will be described later. The arm-side spring locking portion 58 is a hole that passes through a protrusion 59 provided on the frame-side fitting portion 56. The protruding piece 59 is arranged inside the arm fixing frame 18. The arm-side spring locking portion 58 passes through the arm-end housing 52 in a direction parallel to the axis.

The first braking mechanism 32F applies a certain resistance force to the rotation of the first arm 50F, as shown in FIGS. 4 to 6. The second braking mechanism 32S applies a constant resistance force to the rotation of the second arm 50S. The second braking mechanism 32S has the same configuration as the first braking mechanism 32F, so illustration is omitted. The first braking mechanism 32F is provided between the first arm 50F and the first arm holding member 31F (see FIG. 6). The second braking mechanism 32S is provided between the second arm 50S and the second arm holding member 31S. The first and second braking mechanisms 32F, 32S include a force generating member 36, a pressing member 37, and a sliding member 38. The force generating member 36, the pressing member 37, and the sliding member 38 are housed in a component housing portion 53 of the arm end housing 52.

The force generating member 36 generates elastic force in the extending direction of the first and second rotating shafts Z1 and Z2. The force generating member 36 is a plurality of disc springs. The disc spring is made of metal (for example, SUS304). The plurality of disc springs are stacked along the axis of the arm end housing 52. One end of the disc spring contacts the inner surface of the lock nut 57. The other end of the disc spring contacts the pressing member 37.

The pressing member 37 is pressed by the force generating member 36 toward the first and second arm holding members 31F and 31S. The pressing member 37 is a plate material having an annular shape. The pressing member 37 is made of metal (for example, SUS304).

The sliding member 38 is arranged between the pressing member 37 and the first and second arm holding members 31F and 31S. The sliding member 38 is an annular plate (washer). The sliding member 38 is made of synthetic resin (for example, POM). The sliding member 38 rubs against the pressing member 37 and the flange portion 31B. Frictional force is generated when the sliding member 38 rubs against the pressing member 37 and the flange portion 31B. Due to this frictional force, the first and second braking mechanisms 32F and 32S perform negative work in the direction of rotation when the first and second arms 50F and 50S rotate. Work in this application is a physical quantity expressed in units of joules.

The first elastic member 33F includes a first torsion spring 39F. The second elastic member 33S includes a second torsion spring 39S. The first and second torsion springs 39F and 39S generate torque depending on the twist angle. The twist angles of the first and second torsion springs 39F, 39S are determined by the rotation angles of the first and second arms 50F, 50S. The direction of the torque generated by the first and second torsion springs 39F and 39S is such that the potential energy of the first and second arms 50F and 50S is increased. When the first and second arms 50F, 50S are moved from the stored body to the drawn-out state, the first and second torsion springs 39F, 39S perform negative work. When the first and second arms 50F, 50S are moved from the drawer-like body to the stored state, the first and second torsion springs 39F, 39S perform positive work. The first and second torsion springs 39F and 39S are made of metal (for example, SUS304). The first and second torsion springs 39F and 39S are fitted on the outside of the spring guide 34. The first and second torsion springs 39F and 39S are arranged inside the arm fixing frame 18. One ends of the first and second torsion springs 39F and 39S are locked to the frame-side spring locking portion 19. The other ends of the first and second torsion springs 39F and 39S are locked to an arm-side spring locking portion 58.

As shown in FIG. 6, in the first and second working parts 30F and 30S, water passages R are formed which flow water to the water spouts 60 of the first and second arms 50F and 50S. The water passage R is formed of a highly flexible braided hose or the like. The water passage R passes through an insertion hole 41 formed in the first and second working portions 30F, 30S. The insertion hole 41 is formed by an opening in the lock nut 57, an opening in the force generating member 36, an opening in the pressing member 37, an opening in the sliding member 38, and a through hole in any one of the first and second arm holding members 31F and 31S. It is configured. The first and second rotating shafts Z1 and Z2 pass through the water passage R. The first and second rotation axes Z1 and Z2 coincide with the axis of the insertion hole 41.

The first and second arms 50F, 50S are rod-shaped. As shown in FIG. 4, the cross-sectional shape of each of the first and second arms 50F, 50S perpendicular to the longitudinal direction is such that the dimension in the front-rear direction is larger than the dimension in the left-right direction. As shown in FIG. 2, each of the first and second arms 50F, 50S is provided with a plurality of water spouts 60. The spout 60 spouts a body shower toward the user's body.

In the stored state, the water spout 60 (referred to as the upper water spout 60A) located at the uppermost side of the first and second arms 50F, 50S sprays water onto the user's neck and shoulders. In the stored state, the water spout 60 (referred to as the lower water spout 60B) located at the lowest side of the first and second arms 50F, 50S sprays shower water onto the user's legs. In the stored state, three water spouts 60 (referred to as intermediate water spouts 60C) located in the vertically intermediate portions of the first and second arms 50F, 50S spray water onto the user's arms and body.

As shown in FIG. 2, the water spout 60 is provided on the front surfaces of the first and second arms 50F and 50S in the stored state. A portion of the front surface of the first and second arms 50F, 50S where the water spout 60 is arranged (referred to as a water spout surface 61) is inclined with respect to the mounting wall W, as shown in FIG. The water spouting surface 61 faces toward the center of the water spouting device M in the left-right direction. In the pulled out state, the spout 60 faces downward. Five water spouts 60 are arranged at approximately equal intervals in the length direction of each of the first and second arms 50F, 50S. As a result, the body shower sprays water evenly over the user's body.

Each water spout 60 is formed at the tip of a nozzle 62, as shown in FIG. The nozzle 62 is held in a nozzle case 63. The nozzle case 63 has a cylindrical shape and forms a part of the water passage R. The nozzle 62 held in the nozzle case 63 is fixed by a fixing cap 64.

As shown in FIG. 7, the nozzle 62 includes a first nozzle 70 that forms an upper end water spout 60A and a lower end water spout 60B, and a second nozzle 65 that forms an intermediate water spout 60C. The first nozzle 70 is a narrow-angle nozzle that ejects shower water (referred to as first shower water 70C) in a narrow range. The first nozzle 70 is held movably relative to the first and second arms 50F and 50S so that the direction of the tip can be changed. The second nozzle 65 is a wide-angle nozzle that discharges shower water (referred to as second shower water 65C) over a wide range. The second nozzle 65 is fixed to the first and second arms 50F, 50S so that the direction of the tip does not change. The water spouting area of the first shower water spout 70C and the water spouting area of the second shower water spout 65C have a circular shape in a plane orthogonal to the axis of each nozzle 70, 65 when water is spouted with each nozzle 70, 65 facing vertically downward. Eggplant.

As shown in FIG. 7, the second nozzle 65 includes a second nozzle tubular portion 65A and a second nozzle swirler 65B. The second nozzle tubular portion 65A forms a water flow path along the axis and jets water from its tip. The second nozzle swirler 65B is arranged inside the second nozzle tubular portion 65A. The second nozzle swirler 65B generates a swirling flow. The second nozzle swirler 65B is inclined at an angle of 60° with respect to the axis of the second nozzle tubular portion 65A. This improves the diffusivity of the second nozzle 65. The second nozzle 65 sprays shower water over a wide area of the user's arms and body.

As shown in FIG. 9, the first nozzle 70 includes a first nozzle tubular portion 71 and a first nozzle swirler 72. The first nozzle tubular portion 71 forms a water flow path along the axis and jets water from its tip. The first nozzle tubular portion 71 has a swirler housing portion 73 that accommodates the first nozzle swirler 72 . The inner diameter of the waller housing portion 73 is constant. The waller housing portion 73 is provided on the upstream side of the first nozzle tubular portion 71 .

The first nozzle swirler 72 generates a swirling flow toward the downstream side. The first nozzle swirler 72 is inclined at an angle smaller than the angle of the second nozzle swirler 65B. Specifically, the first nozzle swirler 72 is inclined at an angle of 40° with respect to the axis of the first nozzle tubular portion 71. This improves the straightness of the first nozzle 70.

The first nozzle tubular part 71 is provided with a downstream pipe part 74 that forms a flow path in a non-circular cross-sectional shape. The downstream pipe portion 74 is located on the downstream side of the Waller housing portion 73 in the first nozzle tubular portion 71 . A constricted portion 75 is provided between the downstream pipe portion 74 and the Waller housing portion 73, the inner diameter of which decreases toward the downstream side.

The inner peripheral surface of the downstream pipe portion 74 has an uneven shape. When the downstream pipe portion 74 is viewed from the tip side, as shown in FIG. 8, it has a spur gear-like shape. The downstream pipe portion 74 includes six grooves 76 extending along the axis. The six grooves 76 are arranged in a circumferential direction centered on the axis. The six grooves 76 are arranged at equal intervals in the circumferential direction. The six grooves 76 are arranged at positions that are rotationally symmetrical about the axis. The depth dimensions (dimensions in the direction perpendicular to the axis) of the six grooves 76 are the same. As shown in FIG. 9, the bottom surface 77 of the groove 76 is inclined such that the depth of the groove 76 increases toward the tip (downstream side) of the first nozzle 70.

The portion located between the grooves 76 on the inner circumferential surface of the downstream pipe portion 74 is a curved surface 78 having an arc shape, as shown in FIG. The curved surface 78 is a circular arc centered on the axis of the first nozzle tubular portion 71 . The inner diameter of the curved surface 78 is smaller than the inner diameter of the Waller housing portion 73. The curved surface 78 is inclined so that the inner diameter increases toward the tip (downstream side) of the first nozzle 70.

The swirling flow formed by the first nozzle swirler 72 collides with the inner circumferential surface of the downstream pipe portion 74 to cause turbulence. This increases the particle size of the first shower water 70C discharged from the first nozzle 70. As shown in FIG. 7, the range of the first shower water 70C discharged from the first nozzle 70 is smaller than the range of the second shower water 65C discharged from the second nozzle 65. The user's neck and legs feel irritated by the first shower water 70C from the first nozzle 70.

The rear end portion 70A of the first nozzle 70 has a spherical shape, as shown in FIG. The rear end portion 70A of the first nozzle 70 slides on the curved surface 63A of the nozzle case 63, as shown in FIG. The tip 70B of the first nozzle 70 protrudes from the outer surfaces of the first and second arms 50F, 50S. The direction of the tip of the first nozzle 70 can be changed by moving the first nozzle 70 by picking the tip 70B of the first nozzle 70 by hand.

As shown in FIG. 1, the first and second arms 50F, 50S have a main body 50A and a movable part 50B that moves relative to the main body 50A. The movable portion 50B is provided at the tips of the first and second arms 50F, 50S. The main body portion 50A is rotatably connected to the housing 10 around first and second rotation axes Z1 and Z2. A water spout 60 is provided in each of the main body portion 50A and the movable portion 50B. The main body portion 50A is provided with an intermediate spout 60C and a lower end spout 60B. The movable part 50B is provided with an upper end water spout 60A.

As shown in FIG. 7, the movable portion 50B rotates with respect to the main body portion 50A around an imaginary rotation axis (referred to as a third rotation axis Z3). The third rotation axis Z3 extends in the same direction as the longitudinal direction of the first and second arms 50F, 50S.

The connecting part 80 between the movable part 50B and the main body part 50A has a moving side cylinder part 81 and a main body side cylinder part 82 that fit into each other. The movable cylinder part 81 is provided integrally with the movable part 50B. The main body side cylindrical portion 82 is provided integrally with the main body portion 50A.

The fitting portion of the movable side cylinder part 81 and the main body side cylinder part 82 has an arcuate surface on which the movable part 50B slides when moving. The movable side cylinder part 81 is fitted on the outside of the main body side cylinder part 82 . In the fitted state, the moving side cylinder part 81 and the main body side cylinder part 82 are coaxial. The axes of the arcuate surface of the movable side cylindrical portion 81 and the arcuate surface of the main body side cylindrical portion 82 coincide with the third rotation axis Z3.

As shown in FIG. 7, a load adjustment member 83 is provided at the connecting portion 80 between the movable portion 50B and the main body portion 50A. The load adjustment member 83 is an O-ring disposed between the outer circumferential surface of the main body side cylindrical portion 82 and the inner circumferential surface of the movable side cylindrical portion 81. The load adjustment member 83 provides a sense of moderation (resistance) when moving the movable portion 50B.

As shown in FIG. 10, a rotation limiter 84 that limits the rotation range of the movable portion 50B to within a predetermined range α is provided in the connecting portion 80 between the movable portion 50B and the main body portion 50A. The movable part 50B rotates between an initial position and a movement position. The initial position is a position where the upper end spout 60A, the intermediate spout 60C, and the lower end spout 60B are arranged in the same direction. The moving position is a position where the upper end spout 60A is arranged in a different direction from the intermediate spout 60C and the lower end spout 60B.

The rotation restricting portion 84 has a convex portion 84A provided on the outer circumferential surface of the main body side cylindrical portion 82 and a recessed portion 84B provided on the inner circumferential surface of the movable side cylindrical portion 81. The protrusion 84A fits into the recess 84B. The rotation range of the movable portion 50B is limited by the end surface of the recessed portion 84B in the circumferential direction coming into contact with the convex portion 84A. The predetermined rotation range α is a range of 60 degrees centered on the third rotation axis Z3. By rotating the movable part 50B, the upper end spout 60A faces inward by a maximum of 60 degrees compared to the intermediate spout 60C and the lower end spout 60B.

As shown in FIG. 7, an end surface 85 of the movable portion 50B is provided at the lower end of the movable side cylinder portion 81 when the first and second arms 50F, 50S are in the stored state. An end surface 85 of the movable portion 50B protrudes from the outer circumferential surface of the movable cylinder portion 81 in a direction orthogonal to the third rotation axis Z3. The end surface 85 of the movable portion 50B constitutes the outer surface of the movable portion 50B.

An end surface 86 of the main body portion 50A is provided at the vertically intermediate portion of the main body side cylinder portion 82 when the first and second arms 50F, 50S are in the stored state. An end surface 86 of the main body portion 50A protrudes from the outer circumferential surface of the main body side cylinder portion 82 in a direction perpendicular to the third rotation axis Z3. The end surface 86 of the main body 50A constitutes the outer surface of the main body 50A.

The end surface 85 of the movable portion 50B and the end surface 86 of the main body portion 50A come into sliding contact with each other when the movable portion 50B moves. Since the main body side cylindrical portion 82 and the movable side cylindrical portion 81 come into contact over a wide surface when the movable portion 50B moves, durability can be ensured.

A connecting pipe 87 that forms a water passage R through which water flows to the upper end water outlet 60A is arranged inside the connecting part 80 between the movable part 50B and the main body part 50A. The connecting pipe 87 is connected to the nozzle case 63 of the movable part 50B and the nozzle case 63 of the main body part 50A. The third rotating shaft Z3 passes through the connecting pipe 87. The connecting pipe 87 is a member separate from the main body side cylinder part 82 and the moving side cylinder part 81. This can prevent the force associated with the rotation of the movable portion 50B from acting on the connecting pipe 87.

An example of how to use the water discharging device M will be explained. The first and second arms 50F and 50S of the water discharging device M are in a stored state before use. First, the user operates the faucet main body to switch to spouting water from the shower. As a result, the hand shower starts discharging water. The user operates the faucet body to adjust the temperature and flow rate of the hand shower.

Next, the user grips the first and second arms 50F, 50S while sitting facing the water spouting device M, and rotates the first and second arms 50F, 50S of the water spouting device M to an arbitrary position. let At this time, negative work by the first and second braking mechanisms 32F, 32S and the first and second elastic members 33F, 33S generates resistance to the rotation of the first and second arms 50F, 50S. When the user releases his/her hands from the first and second arms 50F, 50S after adjusting the positions of the first and second arms 50F, 50S according to the pulled-out state, the first and second arms 50F, 50S will release their hands. It will stop at the position you released it from. The resistance force of the first braking mechanism 32F, the torque of the first elastic member 36F, and the weight of the first arm 50F are balanced, and the resistance force of the second braking mechanism 32S, the torque of the second elastic member 36S, and the second This is because the weight of the arm 50S is balanced. The first and second arms 50F, 50S rotate diagonally. This allows the distance between the first and second arms 50F, 50S in the left-right direction to be wider than the shoulder width of an adult male. The first and second arms 50F, 50S can be rotated at different angles.

Next, the user presses the operating section 11 to switch the hand shower to the body shower. The hand shower stops discharging water, and the body shower starts discharging water.

Next, the user adjusts the direction of the movable part 50B. The movable part 50B is rotated with respect to the main body part 50A, and the upper end spout 60A is oriented to suit the user's body. By rotating the movable part 50B, the user can direct the first shower water spout 70C from the upper water spout 60A to the desired area (neck/shoulder). Rotating only the movable part 50B is easier than rotating the entire first and second arms 50F and 50S.

Next, the user pinches and moves the tip 70B of the first nozzle 70 with his/her hand to adjust the orientations of the upper end spout 60A and the lower end spout 60B, respectively. Since the first shower water 70C of the first nozzle 70 travels in a straight line, by moving the first nozzle 70, the first shower water 70C can be applied to a targeted location. Since the first shower water 70C from the first nozzle 70 has a large particle size, it hits the body without getting cold. The first shower water spout 70C from the lower water spout 60B improves the feeling of warming the user's legs. Since the first shower water 70C from the first nozzle 70 has a large particle size, the user can feel an irritating sensation where it hits. The user's neck can feel irritated by the first shower water spout 70C from the upper water spout 60A.

The user operates the body shower by operating the operation unit 11 to switch to a hand shower, operating the faucet body to stop the water, or operating the faucet body to switch to water spouting from the faucet. finish.

Thereafter, the user returns the first and second arms 50F, 50S to the stored state. When the first and second arms 50F, 50S are rotated to the stored state, the receiving groove portions 51 of the first and second arms 50F, 50S fit into the arm receiving portions 12 of the housing 10. At this time, since the clearance S between the first and second arms 50F, 50S and the mounting wall W is large, it is possible to prevent fingers from being caught between the first and second arms 50F, 50S and the mounting wall W. It will be done. When returning the first and second arms 50F, 50S to the stored state, when the movable part 50B is in the movement position, the movable part 50B contacts the housing 10 and is returned to the initial position. As a result, the first and second arms 50F, 50S are returned to the stored state.

The operation and effects of the embodiment configured as described above will be explained. The water discharging device M includes first and second arms 50F, 50S, and first and second work sections 30F, 30S. The first and second arms 50F, 50S have a water spout 60 and rotate about imaginary first and second rotation axes Z1, Z2. When the first and second arms 50F, 50S rotate, the first and second work units 30F, 30S perform work in the rotational direction on the first and second arms 50F, 50S. A water passageway R through which water flows to the water spout 60 is formed in the first and second working parts 30F and 30S. According to this configuration, the water discharging device M can be made more compact than when the work section 30 and the water passage R are provided at separate locations.

The water discharging device M includes first and second arms 50F, 50S, and first and second work sections 30F, 30S. When the first arm 50F rotates, the first work section 30F performs work on the first arm 50F in the rotational direction. The second work unit 30S performs work on the second arm 50S in the rotational direction when the second arm 50S rotates. The first and second work sections 30F, 30S are arranged between the first and second arms 50F, 50S. According to this configuration, the first and second working parts 30F, 30S can be made more compact than the case where the first and second working parts 30F, 30S protrude to both outsides of the first and second arms 50F, 50S.

The first and second rotation axes Z1 and Z2 are inclined with respect to the mounting wall W in a state where they are attached to the mounting wall W. According to this configuration, the first and second arms 50F and 50S can be displaced within a plane diagonally intersecting the mounting wall W.

The first and second rotation axes Z1 and Z2 have an intersecting positional relationship. According to this configuration, the first and second arms 50F, 50S can be displaced along non-parallel planes.

When attached to the mounting wall W, the positions of the tips of the first and second arms 50F, 50S projected onto a horizontal plane change as the first and second arms 50F, 50S rotate. According to this configuration, by rotating the first and second arms 50F, 50S, the horizontal positions of the tips of the first and second arms 50F, 50S can be changed.

When attached to the mounting wall W, the first and second rotation axes Z1 and Z2 correspond to the first and second arms 50F and 50S when the first and second arms 50F and 50S are arranged along the mounting wall W, respectively. It is provided at the lower end of 50S. According to this configuration, the first and second arms 50F, 50S rotate about their lower ends as rotation axes. When using the first and second arms 50F, 50S by rotating them until they protrude diagonally upward from the mounting wall W, the first and second arms 50F, 50S The amount of rotation of the first and second arms 50F, 50S can be reduced compared to the case where the upper end portion is a rotating shaft.

The first and second arms 50F, 50S have a main body 50A and a movable part 50B that moves relative to the main body 50A. A water spout 60 is provided in each of the main body portion 50A and the movable portion 50B. According to this configuration, by moving the movable part 50B, the position and direction of the water spout 60A of the movable part 50B can be changed with respect to the water spouts 60B and 60C of the main body part 50A.

The movable portion 50B rotates relative to the main body portion 50A around a virtual third rotation axis Z3. According to this configuration, by rotating the movable part 50B, the position and direction of the water spout 60A of the movable part 50B can be changed with respect to the water spouts 60B and 60C of the main body part 50A.

The third rotation axis Z3 extends in the same direction as the longitudinal direction of the first and second arms 50F, 50S. According to this configuration, the position and direction of the upper water outlet 60A can be changed along a plane orthogonal to the longitudinal direction of the first and second arms 50F, 50S.

The third rotating shaft Z3 of the movable part 50B passes through a water passage R that flows to the upper water spout 60A provided in the movable part 50B. According to this configuration, the structures of the first and second arms 50F and 50S can be made more compact than in the case where the water passage R and the third rotating shaft Z3 are spaced apart.

The rotation range α of the movable part 50B is limited within a predetermined range. By limiting the rotation range to the extent that the first and second arms 50F, 50S can be brought into the retracted state while the movable part 50B remains in a moved state, the movable part 50B can be placed in a prescribed position with respect to the main body part 50A. The first and second arms 50F, 50S can be placed in the stored state without returning to the original state.

The upper end water spout 60A provided in the movable part 50B is formed at the tip of the first nozzle 70. The first nozzle 70 is held movably relative to the movable part 50B so that the direction of the tip can be changed. According to this configuration, since the direction of the upper end water outlet 60A can be changed by moving the first nozzle 70, the direction and position of the upper end water outlet 60A can be changed more finely.

The main body portion 50A is rotatably connected to the housing 10 around virtual first and second rotation axes Z1 and Z2. According to this configuration, by rotating the main body 50A with respect to the housing 10, the positions and orientations of the water spouts 60B and 60C of the main body 50A can be changed.

The first nozzle 70 includes a first nozzle tubular portion 71 , a first nozzle swirler 72 , and a downstream pipe portion 74 . The first nozzle tubular portion 71 forms a water flow path along the axis and jets water from its tip. The first nozzle whirler 72 is arranged inside the first nozzle tubular part 71 and generates a swirling flow toward the downstream side. The downstream pipe portion 74 is provided in the first nozzle tubular portion 71 on the downstream side of the first nozzle swirler 72 . The downstream pipe portion 74 has a non-circular cross-sectional shape perpendicular to the axis of the flow path. According to this configuration, the swirling flow is disturbed in the downstream pipe portion 74, so that the particle size of the ejected water can be increased.

The downstream pipe portion 74 includes a plurality of grooves 76 extending along the axis. According to this configuration, the swirling flow can be disturbed by the grooves 76.

The first nozzle 70 is held movably relative to the first and second arms 50F and 50S so that the direction of the tip can be changed. According to this configuration, the directions of the upper end water spout 60A and the lower end water spout 60B can be changed by moving the first nozzle 70, so the direction and position of the water spout can be changed more precisely.

<Other embodiments>
The present disclosure is not limited to the embodiments described above and illustrated in the drawings, and, for example, the following embodiments are also included within the technical scope of the present disclosure.
(1) In the above embodiment, the first and second rotating shafts Z1 and Z2 are located within the water passage R. However, the present invention is not limited to this, and the first and second rotating shafts may be located outside the water passage.
(2) In the embodiment described above, the first and second rotation axes Z1 and Z2 have an intersecting positional relationship. However, the present invention is not limited to this, and the first and second rotating shafts may have a twisted positional relationship. The torsional positional relationship between the first and second rotation axes allows the two arms to be displaced along non-parallel planes.
(3) In the embodiment described above, when attached to the mounting wall W, the first and second rotation axes Z1 and Z2 are parallel to the horizontal plane. However, the present invention is not limited to this, and the first and second rotation axes may be inclined with respect to the horizontal plane when attached to the mounting wall. According to such a configuration, the arm can be displaced within a plane diagonally intersecting the horizontal plane.
(4) The above embodiment includes the first and second arms 50F and 50S. The present invention is not limited to this, and may include only one arm.
(5) In the above embodiment, the distance between the tips of the first and second arms 50F, 50S increases as the first and second arms 50F, 50S rotate. However, the present invention is not limited to this, and the distance between the tips of the two arms does not have to increase as the arms rotate.
(6) In the above embodiment, the third rotation axis Z3 of the movable part 50B extends in the same direction as the longitudinal direction of the first and second arms 50F and 50S. However, the present invention is not limited to this, and the third rotation axis may extend in a direction perpendicular to the longitudinal direction of the arm. According to such a configuration, the movable part can be bent with respect to the main body part about the third rotation axis.
(7) In the above embodiment, the rotation range α of the movable part 50B is limited to within a range of 60 degrees. The rotation range of the movable part is not limited to this, and can be changed as appropriate. The rotation range of the movable part does not necessarily have to be limited within a predetermined range.
(8) In the embodiment described above, the downstream pipe portion 74 of the first nozzle 70 is provided with a plurality of grooves 76. However, the present invention is not limited to this, and the downstream pipe portion of the first nozzle may include at least one groove.
(9) In the above embodiment, the second nozzle 65 is fixed to the first and second arms 50F, 50S, and the first nozzle 70 is movable to the first and second arms 50F, 50S. The present invention is not limited to this, and the fixation and movability of the nozzle can be changed as appropriate.
(10) In the above embodiment, the third rotation axis Z3 of the movable portion 50B extends in the same direction as the longitudinal direction of the first and second arms 50F, 50S. However, the present invention is not limited to this, and the third rotation axis may extend in a direction intersecting the longitudinal direction of the arm.
(11) The force generating member 36 may be configured to generate force using, for example, magnetic force.
(12) The first and second elastic members 33F and 33S may be made of rubber, for example. By twisting cylindrical rubber, it can perform the same function as a torsion spring.

α...Rotation range of the movable part, M...Water discharging device, R...Water passage, W...Mounting wall, Z1...First rotation axis, Z2...Second rotation axis, Z3...Third rotation axis, 10...Housing, 50F , 50S... Arm, 30F, 30S... Work part, 31F, 31S... Arm holding member, 32F, 32S... Braking mechanism, 33F, 33S... Elastic member, 36... Force generating member, 37... Pressing member, 38... Sliding member , 39F, 39S...Torsion spring, 50A...Main body, 50B...Movable part, 60...Water outlet, 60A...Upper end water outlet, 70...First nozzle, 71...Tubular part for first nozzle, 72...For first nozzle Waller, 74...downstream pipe section, 76...groove

Claims (4)

An arm having a main body and a movable part that moves relative to the main body,
A water spout is provided in each of the main body portion and the movable portion,
The movable part rotates with respect to the main body part around a virtual rotation axis,
In the water discharging device, the rotation range of the movable part is limited within a predetermined range. The water spouting device according to claim 1, wherein a rotation shaft of the movable portion passes through a water passage that flows to a water spout provided in the movable portion . The water spout provided in the movable part is formed at the tip of the nozzle,
The water discharging device according to any one of claims 1 to 2 , wherein the nozzle is held movably relative to the movable part so that the direction of the tip can be changed . Equipped with a housing that is fixed to the mounting wall,
The water discharging device according to any one of claims 1 to 3 , wherein the main body portion is rotatably connected to the housing around an imaginary rotation axis .

Images