JP7022536B2 - Nozzle device - Google Patents

Description

The present invention relates to a nozzle and a nozzle device for ejecting a liquid into a bathtub.

Nozzle devices used in so-called jet baths mix air with water supplied by a circulation pump or eject it into a bathtub without mixing air. Further, a nozzle device that generates a spot jet having a small area of contact with the human body or a wide jet having a relatively large area is used according to the preference of the user.

For example, Patent Document 1 discloses a nozzle device including a unit body having a fine bubble nozzle and a jet nozzle integrally, a nozzle switching valve, and an operation handle. The unit body is formed so that the upstream ends of the fine bubble nozzle and the jet nozzle communicate with each other in the liquid introduction chamber. The nozzle device ejects liquid from the other nozzle whose end is not closed by closing one end of each nozzle with a nozzle switching valve.

Further, Patent Document 2 discloses a nozzle provided with a tubular portion, a central wall, and a peripheral opening forming portion. The tubular portion forms a flow path for the liquid, one end opening toward the inside of the bathtub. The central wall closes the central portion of the opening at one end of the tubular portion. The peripheral opening forming portion forms a peripheral opening as a spout which is formed around the central wall and opens from the inside of the tubular portion toward the inside of the bathtub. This nozzle ejects a liquid from the ejection port in a direction inclined with respect to the axis of the tubular portion, and generates a wide jet.

Japanese Unexamined Patent Publication No. 2014-033808 Japanese Unexamined Patent Publication No. 2017-074283

In the nozzle device described in Patent Document 1, since the valve rotation shaft is arranged on the central axis of the operation handle which is circular when viewed from the inside of the bathtub, the nozzle ejection port is provided on the central axis. However, the placement of the spout is restricted. In the nozzle described in Patent Document 2, the arrangement restriction of the spout is suppressed, and the inflow port where the liquid flows into the tubular portion and the center position of the spout for ejecting the liquid are substantially on the axis of the tubular portion. It is considered that there is little bias in the liquid ejected from the spout. However, there is a problem that when the spout and the inflow port are relatively displaced in the direction orthogonal to the axis due to their arrangement, the flow rate ejected from the spout is biased.

The present invention has been made in view of such circumstances, and an object of the present invention is a nozzle and a nozzle capable of suppressing a bias in the flow rate ejected from an outlet whose position is displaced with respect to the inlet. To provide the equipment.

The nozzle according to the present invention includes a flow path through which a liquid flows, a spout provided on one end side of the flow path, and a liquid inlet provided on the other end side of the flow path. In a nozzle attached to the wall surface of a bathtub and ejecting a liquid from the spout into the bathtub, the spout ejects the liquid with the direction intersecting the wall surface of the bathtub as the center direction, and the inlet is toward the center. In one direction orthogonal to the above, the center position between both ends in the one direction is deviated from the spout, and a shielding portion that blocks the flow of liquid is opposed to the inflow port in a part of the flow path. It is characterized by being provided.

According to the present invention, the nozzle can suppress the deviation of the flow rate ejected from the ejection port that is displaced with respect to the inlet.

It is a perspective view which shows the appearance of the nozzle apparatus which includes the nozzle which concerns on embodiment of this invention. It is a vertical sectional view of a nozzle device. It is a vertical sectional view which enlarged the nozzle part. It is a side view of the outer tubular member seen from the inside of a bathtub. It is a side view of the inner tubular member seen from the outside of a bathtub. It is a schematic diagram for demonstrating the positional relationship between the 2nd ejection port and the 2nd inflow port in the 2nd nozzle. It is a vertical sectional view of the nozzle device for demonstrating the use state which ejects from a 1st nozzle. It is a vertical sectional view of the nozzle device for demonstrating the use state which ejects from a 2nd nozzle. It is a schematic diagram for demonstrating the positional relationship between the 2nd ejection port and the 2nd inflow port in the 2nd nozzle which concerns on a modification. It is a schematic diagram for demonstrating the positional relationship between the 2nd ejection port and the 2nd inflow port in the 2nd nozzle which concerns on another modification. It is an enlarged vertical sectional view of the nozzle part which concerns on still another modification. (I) It is a vertical sectional view of the nozzle device for demonstrating the use state.

Hereinafter, the present invention will be described with reference to FIGS. 1 to 12 based on a preferred embodiment. The same or equivalent components and members shown in the drawings shall be designated by the same reference numerals, and duplicate description thereof will be omitted as appropriate. Further, the dimensions of the members in each drawing are shown in an appropriately enlarged or reduced size for easy understanding. In addition, some of the members that are not important for explaining the embodiment in each drawing are omitted and displayed.

(Embodiment)
FIG. 1 is a perspective view showing the appearance of a nozzle device 100 including a nozzle (second nozzle 22) according to an embodiment of the present invention. The nozzle device 100 includes a main body portion 1, a nozzle portion 2, a cover member 3, a switching portion 4, and the like. In the nozzle device 100, the nozzle portion 2 and the cover member 3 are attached to the main body portion 1 arranged on the outside of the bathtub from the inside of the bathtub. The main body 1 is provided with a supply port 12a and a discharge port 13a connected to a circulation pump (not shown) by piping. The nozzle device 100 made the hot water in the bathtub sucked from the suction port 31 formed in the cover member 3 flow through the discharge port 13a to the circulation pump, and was supplied from the circulation pump to the main body 1 through the supply port 12a. Hot water is ejected from the nozzle portion 2 into the bathtub. The nozzle portion 2 is attached to the bathtub wall surface together with the main body portion 1, and ejects hot water in a direction (orthogonal direction) intersecting the bathtub wall surface.

The nozzle portion 2 is provided with a first nozzle 21 and a second nozzle 22. The nozzle portion 2 has an inner tubular member 25, and a first ejection port 21a of the first nozzle 21 and a second ejection port 22a of the second nozzle 22 are provided on the end surface of the inner tubular member 25 seen from the inside of the bathtub. There is. The first spout 21a and the second spout 22a face the inside of the bathtub. The inner tubular member 25 has an operating member 23 protruding toward the inside of the bathtub in all directions, and the user can hang a finger on the operating member 23 to rotate the inner tubular member 25. The inner tubular member 25 has a switching portion 4 (see FIG. 3) for switching the jet flow at the end portion on the main body portion 1 side. The nozzle device 100 makes it possible to switch the nozzle for supplying the liquid by the switching unit 4 to the first nozzle 21 or the second nozzle 22 by rotating the inner tubular member 25.

The second nozzle 22 corresponds to the nozzle in the claimed invention, and has a plurality of second ejection ports 22a. The plurality of second jets 22a generate jets inclined in the radial direction from the central axis of the nozzle portion 2, but the angles of inclination are almost the same, and the central direction in which the liquid is ejected is on the wall surface of the bathtub. The directions intersect and are almost orthogonal. As will be described later, the positions of the second ejection port 22a and the inlet of the hot water to the second nozzle 22 are misaligned, but each of the second nozzles 22 is provided with a shielding portion provided in a part of the flow path of the second nozzle 22. 2 The bias of the flow rate ejected from the ejection port 22a is suppressed.

FIG. 2 is a vertical cross-sectional view of the nozzle device 100, and FIG. 3 is an enlarged vertical cross-sectional view of the nozzle portion 2. The main body portion 1 has a body portion 11, an internal tubular portion 14, and a fixing member 15. The body portion 11 has a cylindrical shape and has a flange 11a at one end on the bathtub 9 side. Inside the body portion 11, an internal tubular portion 14 is formed coaxially. The inner tubular portion 14 has one end on the bathtub 9 side open and the other end continuous with the supply portion 12. In the supply unit 12, the pipe from the circulation pump is connected to the supply port 12a at the end. A hot water supply flow path 17 is formed inside the inner tubular portion 14.

Further, the discharge flow path 18 is formed inside the body portion 11 and outside the inner tubular portion 14. The discharge flow path 18 communicates with the discharge unit 13. A pipe to the circulation pump is connected to the discharge port 13a at the end of the discharge unit 13. In FIG. 2, the flow path 16 is connected to the internal tubular portion 14. The flow path 16 is used to take in air when external air is taken in and air bubbles are mixed in the jet stream. In the present embodiment, the case where the open end of the flow path 16 is closed and bubbles are not mixed in the jet will be described. However, when bubbles are mixed in the jet, the open end of the flow path 16 is closed. It may be opened and an ejector may be provided in the internal tubular portion 14.

The fixing member 15 has a cylindrical shape with both ends open, and has a flange 15a at one end. The fixing member 15 has a male screw formed on the outer peripheral surface of the other end portion, and the other end portion is inserted so as to fit the outer peripheral surface into the through hole provided in the bathtub and rotated in one direction around the central axis. It is screwed into a female screw formed on the inner surface of the body portion 11. A packing for watertight sealing is sandwiched between the flange 15a and the inner surface of the bathtub 9. Further, it is preferable to sandwich a packing for watertight sealing between the flange 11a of the body portion 11 and the outer surface of the bathtub 9. A part of the discharge flow path 18 is formed inside the fixing member 15 and outside the outer tubular member 24 of the nozzle portion 2 described later. Further, the flange 15a of the fixing member 15 is provided with an annular protrusion 15b that protrudes toward the inside of the bathtub 9. The nozzle portion 2 including the second nozzle 22 is incorporated in the main body portion 1, attached to the bathtub wall surface 9a together with the main body portion 1, and ejects hot water in a direction (orthogonal direction) intersecting the bathtub wall surface 9a.

The nozzle portion 2 has an outer tubular member 24, an inner tubular member 25, and a nozzle head 26, and forms a first nozzle 21 and a second nozzle 22. The outer tubular member 24 is a circular tubular member whose inner side of the bathtub 9 is tapered in diameter, and the cylindrical base portion 24a on the main body portion 1 side is coaxial with the inner tubular portion 14 inside the inner tubular portion 14 of the main body portion 1. It is fitted on top. The inside of the base 24a is a part of the supply flow path 17. An annular packing is arranged on the outer periphery of the base portion 24a, and the supply flow path 17 and the discharge flow path 18 are watertightly sealed so as not to communicate with each other.

The axially intermediate portion 24b of the outer tubular member 24 forms a step whose radial dimension is slightly larger than that of the base portion 24a, and is continuous with the base portion 24a. An inner bottom surface 24g is formed in the middle portion 24b, and the end surface of the end portion 25a of the inner tubular member 25, which will be described later, faces the inner bottom surface 24g with contact or a slight gap. The switching portion 4 is configured by the middle portion 24b, the inner bottom surface 24g, and the end portion 25a. The tip portion 24c of the outer tubular member 24 is formed in a conical cylinder shape whose diameter increases toward the inside of the bathtub 9 from the middle portion 24b. Further, a flange portion 24d is continuously formed on the tip portion 24c.

The flange portion 24d has an annular portion 24e folded back from the outer peripheral edge in one direction of the main body portion, and the annular portion 24e engages with the protrusion portion 15b of the fixing member 15. The annular portion 24e is provided with a plurality of through holes penetrating inside and outside, and the inside of the bathtub 9 and the discharge flow path 18 communicate with each other through the through holes. In the outer tubular member 24, a screw is inserted into a through hole (not shown) provided in the flange portion 24d or the like, and a screw is fastened to a screw hole (not shown) provided in the protrusion 15b of the fixing member 15 to fasten the fixing member 15. It is fixed to.

The outer tubular member 24 has a reduced diameter portion 24f that projects inward from the inner end portion of the bathtub 9 to the middle portion 24b in the base portion 24a, and the outlet 17a of the supply flow path 17 is formed at an eccentric position. Will be done. FIG. 4 is a side view of the outer tubular member 24 as seen from the inside of the bathtub 9. The inner diameter of the outlet 17a is about half or slightly smaller than the inner diameter of the middle portion 24b, and the outlet 17a is brought closer to one place on the outer periphery of the inner bottom surface 24g of the middle part 24b, and the middle part 24b is moved from that one place. It is formed in a circular shape, an oval shape, an elliptical shape, or the like over the central axis of.

The inner tubular member 25 is formed in a conical cylinder shape whose diameter increases toward the inside of the bathtub 9. The end 25a on the main body 1 side, the middle portion 24b of the outer tubular member 24, and the inner bottom surface 24g of the inner tubular member 25 have a first nozzle 21 or a second nozzle that supplies hot water from the outlet 17a of the supply flow path 17. A switching unit 4 for switching to the nozzle 22 is configured. The tip portion 25b of the inner tubular member 25 is folded back in a C-shaped cross section over the entire circumference, and a brim-shaped peripheral edge portion 25c is formed. The peripheral edge portion 25c is in contact with the outer tubular member 24 and is prevented from coming off by the pressing member 27, but is not fixed. Therefore, the inner tubular member 25 is rotatable around the central axis of the outer tubular member 24. The pressing member 27 is provided with a rotation stopper so as not to rotate with the inner tubular member 25.

The first nozzle 21 is composed of an inner tubular member 25 and a nozzle head 26, and forms a first flow path 21b inside the inner tubular member 25 and the nozzle head 26. The second nozzle 22 is composed of a tip portion 24c of the outer tubular member 24 and an inner tubular member 25, is inside the tip portion 24c of the outer tubular member 24, and is a second flow path outside the inner tubular member 25. It forms 22b. The second flow path 22b corresponds to the flow path in the claimed invention.

The first flow path 21b is provided with a circular first ejection port 21a at the tip of the nozzle head 26, which is one end of the flow path. The nozzle head 26 is formed in a tubular shape in which the outer peripheral surface of the base portion swells in a spherical shape, and the base portion is brought into contact with a seat surface provided in the middle of the inner tubular member 25 to prevent the nozzle head 26 from coming off. The nozzle head 26 can be tilted in any direction within a certain angle range. The first jet 21a is provided at the center of the end face of the nozzle device 100 as seen from the inside of the bathtub 9, that is, at the center of the end faces of the nozzle portion 2 facing the inside of the bathtub 9 and the cover member 3, and goes straight. A spot jet with high characteristics and suppressed spread is ejected into the bathtub 9.

The second flow path 22b is provided with a second ejection port 22a at the tip end portion 25b of the inner tubular member 25 which is one end of the flow path. The second spout 22a has an arcuate shape, and is provided at four locations at substantially equal intervals on the circumference of the tip portion 25b facing the inside of the bathtub 9 of the inner tubular member 25. The shape of each second spout 22a is the same. The second spout 22a is provided around the first spout 21a on the end surface of the nozzle device 100 viewed from the inside of the bathtub 9, that is, the end faces of the nozzle portion 2 and the cover member 3 facing the inside of the bathtub 9. .. The second jet 22a generates a jet inclined in a direction extending in the radial direction from the central axis of the nozzle portion 2, that is, the central axis of the outer tubular member 24, and is used as a spot jet ejected from the first jet 21a. A wide jet, which is wider than the other, is ejected into the bathtub 9. The second spout 22a corresponds to the spout in the claimed invention.

FIG. 5 is a side view of the inner tubular member 25 seen from the outside of the bathtub 9. The end portion 25a of the inner tubular member 25 is a circular tube, the inside forms a part of the first flow path 21b, and the end surface of the end portion 25a which is the other end of the first flow path 21b on the main body 1 side. The inner peripheral edge of the water is the first inflow port 21c. The end face of the end portion 25a is in contact with or faces the inner bottom surface 24g of the middle portion 24b of the outer tubular member 24 with a slight gap. The inner diameter of the first inflow port 21c is about half or slightly smaller than the inner diameter of the inner bottom surface 24g, and is moved toward one place on the outer circumference of the inner bottom surface 24g and has a circular shape from that one place to the center. , Oval or elliptical. The first nozzle 21 corresponds to the other nozzle in the claimed invention, and the first inflow port 21c corresponds to the inflow port of the other nozzle in the claimed invention.

The second inflow port 22c provided at the other end of the second flow path 22b of the second nozzle 22 is a region outside the outer peripheral edge of the end face of the end portion 25a and surrounded by the outflow port 17a of the supply flow path 17. (The area surrounded by the alternate long and short dash line shown in FIG. 5). The second inlet 22c corresponds to the inlet in the claimed invention.

By rotating the inner tubular member 25 around the central axis of the outer tubular member 24 and directing the first inflow port 21c to the outflow port 17a of the supply flow path 17, the hot water from the supply flow path 17 becomes the first flow. It flows through the road 21b and is ejected from the first ejection port 21a. Further, by rotating the inner tubular member 25 around the central axis of the outer tubular member 24 and communicating the outlet 17a of the supply flow path 17 with the second flow path 22b, the hot water from the supply flow path 17 becomes the first. It flows through the two flow paths 22b and is ejected from the second ejection port 22a. In this way, the switching unit 4 passes the hot water from the outlet 17a of the supply flow path 17 to the first flow path 21b or the second flow path 22b by rotating the end portion 25a with respect to the intermediate portion 24b. It can be switched to flow.

The inner tubular member 25 has an end portion 25a that can rotate in both directions around the central axis of the outer tubular member 24, but at least rotates in a direction opposite to the direction in which the fixing member 15 is rotated when the fixing member 15 is fixed to the main body portion 1. Any structure is acceptable. In this reverse rotation, the inner tubular member 25 can rotate with a torque sufficiently smaller than the tightening torque of the fixing member 15 because the friction generated between the inner tubular member 25 and the outer tubular member 24 is small.

The end portion 25a of the inner tubular member 25 is formed with a shielding portion 25d that projects radially from the peripheral side portion and blocks the flow of hot water in a part of the second flow path 22b. The shielding portion 25d has a plate shape and is provided so as to extend to the opposite side of the first inflow port 21c with the central axis of the outer tubular member 24 interposed therebetween, and the outflow port 17a of the supply flow path 17 is provided as a second flow path. In a state of communicating with 22b, it faces the second inflow port 22c. The shielding portion 25d blocks the hot water flowing into the second flow path 22b from the second inflow port 22c, and diffuses the hot water from the shielding portion 25d in the circumferential direction. The shielding portion 25d is provided at a position closer to the second inflow port 22c in the second flow path 22b in the central axis direction, but may be provided at a position closer to the second spout 22a.

FIG. 6 is a schematic diagram for explaining the positional relationship between the second ejection port 22a and the second inlet 22c in the second nozzle 22. FIG. 6 corresponds to a side view of the inner tubular member 25 seen from the inside of the bathtub. As described above, the second ejection port 22a is provided at four locations, and generates a jet stream inclined in a radial direction from the central axis of the nozzle portion 2, that is, the central axis of the outer tubular member 24. The upper and lower second spouts 22a generate jets in the directions of inclining upward and downward, respectively, and the second spouts 22a located in the left and right generate jets in the directions of inclining to the left and right, respectively. do. Since the inclination angle from the central axis of the nozzle portion 2 in the direction in which each second ejection port 22a ejects hot water is substantially the same, the central direction in which the hot water is ejected intersects the bathtub wall surface 9a and is approximately orthogonal to each other (the direction in which the hot water is ejected is approximately orthogonal to each other. In FIG. 7, the direction is orthogonal to the paper surface).

Taking the direction P which is the vertical direction as one direction orthogonal to the central direction in which hot water is ejected from the second inlet 22a, both ends of the direction P of the second inlet 22c are orthogonal to the direction P, and the upper end and the lower end are formed. It is on a straight line L1 and a straight line L2 passing through. The center position between both ends in the direction P of the second inflow port 22c is on a straight line L3 that bisects the distance between the straight line L1 and the straight line L2.

Further, both ends of the direction P of the second ejection port 22a are on a straight line M1 passing through the upper end of the upper second ejection port 22a and on a straight line M2 passing through the lower end of the lower second ejection port 22a. The straight line M1 and the straight line M2 are orthogonal to the direction P. The center position between both ends in the direction P of the second ejection port 22a is on the straight line M3 that bisects the distance between the straight line M1 and the straight line M2.

Therefore, in the direction P orthogonal to the center direction in which hot water is ejected from the second ejection port 22a, the center position between both ends of the second inlet 22c in the P direction is deviated from the center position of the second ejection port 22a. It has become.

Further, the distance between both ends in the direction P of the second ejection port 22a, that is, the distance between the straight line M1 and the straight line M2 is the distance between both ends in the direction P of the second inlet 22c, that is, the distance between the straight line L1 and the straight line L2. Greater than.

In such a positional relationship, the lower second outlet 22a near the second inlet 22c ejects a larger flow rate than the upper second outlet 22a, and the flow rate tends to be biased. Become. The shielding portion 25d is provided to suppress such a bias in the flow rate. The shielding portion 25d functions so that the hot water that has flowed into the second flow path 22b from the second inflow port 22c diffuses into the second flow path 22b.

Returning to FIG. 2, the cover member 3 has a cylindrical shape having a bottom portion 3a on one end side. The bottom portion 3a is open to a region of the nozzle portion 2 in which the first spout 21a and the second spout 22a are arranged. The peripheral side portion 3b covers the peripheral portions of the outer tubular member 24 and the inner tubular member 25. The cover member 3 has a suction port 31 on the peripheral side portion 3b (see FIG. 1), and allows hot water in the bathtub to flow to the discharge flow path 18. Regarding the cover member 3, the end surface of the cover member 3 facing the inside of the bathtub 9 described above refers to the outer surface of the bottom portion 3a facing the inside of the bathtub 9.

Next, the operation of the nozzle device 100 will be described. FIG. 7 is a vertical cross-sectional view of the nozzle device 100 for explaining the usage state of ejecting from the first nozzle 21. In FIG. 7, the switching unit 4 is in a state in which the first inlet 21c of the end portion 25a of the inner tubular member 25 faces the outlet 17a of the supply flow path 17, and is a nozzle device as shown by an arrow. Hot water flows through the inside of 100. The hot water discharged from the circulation pump is supplied to the supply flow path 17 in the internal tubular portion 14 of the main body portion 1, and is supplied from the outflow port 17a to the first flow path 21b of the first nozzle 21 through the first inflow port 21c. It passes through and is ejected from the first ejection port 21a.

The first nozzle 21 ejects a spot jet that has high straightness and suppresses expansion into the bathtub 9. The user can receive a strong water pressure on the body in a narrow range by the spot jet from the first nozzle 21. Further, the user can adjust the part of the body that receives the spot jet by inclining the nozzle head 26 provided with the first nozzle 21 in an arbitrary direction within a certain angle range.

FIG. 8 is a vertical cross-sectional view of the nozzle device 100 for explaining the usage state of ejecting from the second nozzle 22. The inner tubular member 25 is rotatable around the central axis of the outer tubular member 24, and the user can hang a finger on the operation member 23 to rotate the inner tubular member 25. In FIG. 8, the switching portion 4 is in a state where the inner tubular member 25 is rotated so that the outlet 17a of the supply flow path 17 communicates with the second flow path 22b, and as shown by the arrow, the nozzle device Hot water flows through the inside of 100. The hot water discharged from the circulation pump is supplied to the supply flow path 17 in the internal tubular portion 14 of the main body 1, and is supplied from the outflow port 17a to the second flow path 22b of the second nozzle 22 through the second inflow port 22c. It passes through and is ejected from the second ejection port 22a.

The second nozzle 22 ejects a wide jet into the bathtub 9, which is wider than the spot jet ejected from the first jet 21a. The user can receive a water pressure weaker than that of the spot jet in a wide range by the wide jet from the second nozzle 22. The user can switch between a spot jet with a small spread and a wide jet with a spread according to his / her preference, and the convenience is improved.

The first flow path 21b may be provided so as to extend toward the inside of the bathtub 9 with respect to the first inflow port 21c provided at the end portion 25a of the inner tubular member 25. Therefore, the first ejection port 21a is not limited to the central portion of the end surface of the nozzle device 100 viewed from the inside of the bathtub 9, that is, the central portion of the end surface of the nozzle portion 2 facing the inside of the bathtub 9 and the cover member 3. Since it can be arranged in an area other than the area shielded by the cover member 3, it is possible to suppress the limitation of the arrangement of the nozzle ejection port.

Similarly, the second flow path 22b may be provided so as to extend toward the inside of the bathtub 9 with respect to the second inflow port 22c provided at the end portion 25a of the inner tubular member 25. Therefore, the second ejection port 22a is the end surface of the nozzle device 100 seen from the inside of the bathtub 9, that is, the end surface of the nozzle portion 2 and the cover member 3 facing the inside of the bathtub 9, other than the region shielded by the cover member 3. Since it can be arranged in the area, it is possible to suppress the limitation of the arrangement of the nozzle ejection port.

In the second inflow port 22c, in the direction P (see FIG. 6) orthogonal to the center direction in which hot water is ejected from the second spout 22a, the center position between both ends in the P direction is from the center position of the second spout 22a. It is in a misaligned state. Further, the distance between both ends in the direction P of the second ejection port 22a, that is, the distance between the straight line M1 and the straight line M2 is the distance between both ends in the direction P of the second inlet 22c, that is, the distance between the straight line L1 and the straight line L2. Greater than.

In such a positional relationship, the flow rate ejected at each second ejection port 22a tends to be biased. The shielding portion 25d has the effect of diffusing the flow of hot water in the second flow path 22b, and the bias of the flow rate ejected from each second ejection port 22a is suppressed.

The four second spouts 22a have the same shape. By making the shapes of the second spouts 22a different from each other and making each area different, there is a possibility that the deviation of the flow rate to be ejected can be suppressed. However, when each shape of the second ejection port 22a is not the same, if the flow rate is made uniform, the water pressure and the area received by the user's body will change depending on the location, which gives the user a sense of discomfort. In addition, if the shapes of the second spout 22a are not the same, the user and the construction worker may feel uncomfortable in appearance, and may be suspicious that the product is defective or that the mounting direction is incorrect. There is a concern that it will end up. By making the shapes of the four second spouts 22a the same, it is possible to make it difficult for the user and the construction worker to feel a sense of discomfort.

In the present embodiment, the first spout 21a is provided at the center of the end surface of the nozzle device 100 seen from the inside of the bathtub 9, and the second spout 22a is provided around the first spout 21a. Therefore, it is possible to suppress the deviation between the central axis of the spot jet ejected from the first ejection port 21a and the central axis of the wide jet ejected from the second ejection port 22a. The central axis of the spot jet ejected from the first ejection port 21a can be adjusted by inclining the nozzle head 26.

When the user rotates the inner tubular member 25, the outer tubular member 24 receives torque in the rotated direction due to the friction between the inner tubular member 25 and the outer tubular member 24. Since the outer tubular member 24 is fixed to the fixing member 15, the torque received by the outer tubular member 24 is transmitted to the fixing member 15. In the present embodiment, the inner tubular member 25 can rotate in both directions, but the fixing member 15 is loosened and the fixing member is loosened by allowing the inner tubular member 25 to rotate with a torque sufficiently smaller than the tightening torque of the fixing member 15. It is possible to prevent excessive tightening of 15.

Further, when the inner tubular member 25 is rotated only in one direction, it may be configured to rotate only in the direction opposite to the direction in which the fixing member 15 is tightened. By allowing the inner tubular member 25 to rotate with a torque sufficiently smaller than the tightening torque of the fixing member 15, it is possible to prevent the fixing member 15 from loosening.

Next, the features of the nozzle device 100 of the embodiment will be described.
The second nozzle 22 (nozzle) of the embodiment of the present invention has a second flow path 22b (passage flow path) through which hot water, which is a liquid, flows, and a second injection provided on one end side of the second flow path 22b. It includes an outlet 22a and a second inlet 22c, which is an inlet for hot water provided on the other end side of the second flow path 22b. The second nozzle 22 is attached to the bathtub wall surface 9a, and hot water is ejected from the second ejection port 22a into the bathtub 9. The second spout 22a ejects hot water with the direction intersecting the bathtub wall surface 9a as the center direction. The center position between both ends of the second inflow port 22c is deviated from the second spout 22a in one direction orthogonal to the center direction. A shielding portion 25d that blocks the flow of the liquid is provided in a part of the second flow path 22b so as to face the second inflow port 22c. As a result, the flow of hot water in the second flow path 22b is diffused in the second nozzle 22, so that the deviation of the flow rate ejected from the second ejection port 22a can be suppressed.

Further, the distance between both ends of the second inlet 22a in the one direction is larger than the distance between both ends of the second inlet 22c in the one direction. As a result, the flow rate is more likely to be biased, but the second nozzle 22 is ejected from the second ejection port 22a because the flow of hot water in the second flow path 22b is diffused by the shielding portion 25d. It is possible to suppress the bias of the flow rate.

Further, the second nozzle 22 is provided at a position where the shielding portion 25d is closer to the second inflow port 22c. As a result, the second nozzle 22 tends to diffuse the flow of hot water in the second flow path 22b, so that the effect of suppressing the deviation of the flow rate ejected from the second ejection port 22a is enhanced.

Further, the nozzle device 100 includes a second nozzle 22, a supply flow path 17, and a switching unit 4. The supply flow path 17 supplies the liquid to the second nozzle 22. The switching unit 4 switches the flow path by facing the first inflow port 21c of the first nozzle 21, which is another nozzle, with the outflow port 17a of hot water provided in the supply flow path 17. As a result, the nozzle device 100 can suppress the limitation of the arrangement of the first ejection port 21a and the second ejection port 22a on the end surface seen from the inside of the bathtub 9.

(Modification example)
9 (a) and 9 (b) are schematic views for explaining the positional relationship between the second ejection port 22a and the second inflow port 22c in the second nozzle 22 according to the modified example. 9 (a) and 9 (b) correspond to FIG. The second nozzle 22 according to the modified example shown in FIG. 9A is provided at a position where the second nozzle 22a is moved by 45 ° in the circumferential direction from the above-described embodiment. Further, the second nozzle 22 according to the modified example shown in FIG. 9B has three second ejection ports 22a, and is on the circumference of the tip portion 25b facing the inside of the bathtub 9 of the inner tubular member 25. It is provided at three places at approximately equal intervals.

Also in the second nozzle 22 according to these modifications, the second inflow port 22c has a second center position between both ends in the P direction in the direction P orthogonal to the center direction in which hot water is ejected from the second ejection port 22a. It is in a state of being deviated from the center position of the spout 22a. Further, the distance between both ends in the direction P of the second inlet 22a is larger than the distance between both ends in the direction P of the second inlet 22c.

Since the second nozzle 22 diffuses the flow of hot water in the flow path by providing the shielding portion 25d in the second flow path 22b, the flow rate of the hot water ejected from each second ejection port 22a is uneven. It can be suppressed.

10 (a) and 10 (b) are schematic views for explaining the positional relationship between the second ejection port 22a and the second inflow port 22c in the second nozzle 22 according to another modification. 10 (a) and 10 (b) correspond to FIG. In the second nozzle 22 according to another modification shown in FIG. 10A, the second nozzle 22a is provided in an annular shape. Further, in the second nozzle 22 according to another modification shown in FIG. 10B, the second nozzle 22a is annular, but it is interrupted at one point on the circumference, and is linear as a whole. ing.

Also in the second nozzle 22 according to these other modifications, the second inlet 22c has the center position between both ends in the P direction in the direction P orthogonal to the center direction in which hot water is ejected from the second ejection port 22a. It is in a state of being deviated from the center position of the second ejection port 22a. Further, the distance between both ends in the direction P of the second inlet 22a is larger than the distance between both ends in the direction P of the second inlet 22c.

Since the second nozzle 22 diffuses the flow of hot water in the flow path by providing the shielding portion 25d in the second flow path 22b, the flow rate of the hot water ejected from each second ejection port 22a is uneven. It can be suppressed.

FIG. 11 is a vertical sectional view of the nozzle device 100 according to still another modification. In this nozzle device 100, the inner diameter of the outlet 17a of the supply flow path 17 is about half or larger than the inner diameter of the middle portion 24b. The outlet 17a is formed in a circular shape, an oval shape, an elliptical shape, or the like, which is close to one place on the inner peripheral surface of the middle part 24b and includes the central axis of the middle part 24b from the one place. Further, the inner diameter of the first inflow port 21c of the first nozzle 21 is about half or larger than the inner diameter of the inner bottom surface 24g. The first inflow port 21c is formed in a circular shape, an oval shape, an elliptical shape, or the like from the one location to the center of the inner bottom surface 24g.

When the first inflow port 21c faces the outflow port 17a in the switching unit 4, the hot water from the supply flow path 17 flows exclusively to the first nozzle 21, and the spot jet from the first spout 21a flows into the bathtub 9. It is ejected inside.

FIG. 12 is a vertical sectional view of the nozzle device 100 for explaining one usage state. The nozzle device 100 is in a state in which the inner tubular member 25 is rotated by 180 ° in the switching portion 4 from the state shown in FIG. 11 so that the outlet 17a of the supply flow path 17 communicates with the second flow path 22b. .. In this state, a part of the first inflow port 21c faces the outflow port 17a, and the hot water from the supply flow path 17 flows to both the second nozzle 22 and the first nozzle 21.

The nozzle device 100 ejects a wide jet from the second jet 22a and a spot jet with a weak water pressure from the first jet 21a into the bathtub 9. As a result, when the wide jet is ejected from the nozzle device 100, the jet can be generated from the first jet 21a also in the central axis direction of the wide jet ejected from the second jet 22a. Also in this case, by providing the shielding portion 25d in the second flow path 22b, the flow of hot water in the flow path is diffused by the shielding portion 25d, so that the deviation of the flow rate ejected from each second ejection port 22a is suppressed. be able to.

Further, the nozzle device 100 of the embodiment and each modification has the following features 1 to 6. An object of the present invention is to provide a nozzle device 100 capable of switching nozzles to eject a liquid and suppressing restrictions on the arrangement of outlets of each nozzle facing the bathtub.
[Item 1]
A nozzle device 100 that ejects hot water, which is a liquid, into the bathtub 9.
A nozzle (second nozzle 22) in which a flow path (second flow path 22b) through which a liquid flows is formed and an outlet (second ejection port 22a) is provided on one end side of the flow path.
A supply channel 17 that supplies liquid to the nozzle,
Another flow path (first flow path 21b) through which the liquid flows is formed, and the ejection port (first ejection port 21a) is formed on one end side of the other passing path and the inlet (first outlet) is formed on the other end side. With another nozzle (first nozzle 21) provided with an inflow port 21c),
A switching unit 4 for switching the flow path by facing the inlet of the other nozzle to the liquid outlet 17a provided in the supply flow path 17.
A nozzle device 100 comprising. As a result, the nozzle device 100 suppresses the limitation of the arrangement of the ejection port (first ejection port 21a) of the other nozzle and the ejection port (second ejection port 22a) of the nozzle on the end surface seen from the inside of the bathtub 9. be able to.
[Item 2]
The nozzle device 100 according to item 1, wherein the nozzle generates a jet flow that is wider than the other nozzles. As a result, the nozzle device 100 can switch between a spot jet with a small spread and a wide jet with a spread according to the user's preference, and the convenience is improved.
[Item 3]
The spouts of the other nozzles are arranged in the center of the end face seen from the inside of the bathtub 9.
The nozzle device 100 according to item 1 or 2, wherein the nozzle outlet is arranged around the nozzle of the other nozzle. As a result, the nozzle device 100 has a central axis of a spot jet ejected from the ejection port (first ejection port 21a) of the other nozzle and a wide jet ejected from the ejection port (second ejection port 22a) of the nozzle. It is possible to suppress the deviation from the central axis.
[Item 4]
Item 1 characterized in that a part of the inlet of the other nozzle faces the outlet 17a in a state where the liquid is supplied from the supply channel 17 to the passage by the switching unit 4. The nozzle device 100 according to any one of 3 to 3. As a result, when a wide jet is ejected from the nozzle device 100, the jet of the other nozzle (first) is also directed in the central axis direction of the wide jet ejected from the jet of the nozzle (second jet 22a). A jet can be generated from the spout 21a).
[Item 5]
The main body 1 to which the supply flow path 17 is formed and arranged outside the bathtub 9 and
A cylindrical shape in which the outer peripheral surface is fitted into the through hole provided in the bathtub 9, is inserted from the inside of the bathtub 9 and rotated in one direction around the central axis to be screwed into the main body 1. A fixing member 15 for fixing the main body 1 to the bathtub 9 is provided.
The switching unit 4 is characterized in that the inlet of the other nozzle can be rotated at least in the direction opposite to the one direction on the circumference having a center on the central axis, and faces the outlet 17a. The nozzle device 100 according to any one of items 1 to 4. As a result, the nozzle device 100 can prevent the fixing member 15 from loosening.
[Item 6]
The nozzle device 100 according to item 5, wherein the switching unit 4 is capable of rotating the inlet of the other nozzle in the same direction as the one direction. As a result, the nozzle device 100 can prevent the fixing member 15 from being excessively tightened.

The above description has been made based on the embodiment of the present invention. It will be appreciated by those skilled in the art that these embodiments are exemplary and that various modifications and modifications are possible within the claims of the invention and that such modifications and modifications are also within the claims of the present invention. It is about to be done. Therefore, the descriptions and drawings herein should be treated as exemplary rather than limiting.

17 Supply channel, 17a outlet, 21 Nozzle 1 (other nozzle),
21c 1st inlet (inlet of other nozzles), 22 2nd nozzle (nozzle),
22a 2nd spout (spout), 22b 2nd flow path (passage),
22c 2nd inlet (inlet), 25d shield, 100 nozzle device.

Claims (3)

It has a flow path through which liquid flows, a spout provided on one end side of the flow path, and a liquid inlet provided on the other end side of the flow path, and is attached to the wall surface of the bathtub to eject the jet. In a nozzle device including a nozzle for ejecting a liquid from an outlet into a bathtub and a supply flow path for supplying the liquid to the nozzle .
A plurality of the spouts are provided, and the liquid is ejected with the direction intersecting the bathtub wall surface as the center direction.
In one direction orthogonal to the center direction of the inflow port, the center position between both ends of the one direction is deviated from the center position of the distribution of the plurality of the spouts.
A shielding portion that blocks the flow of liquid is provided in a part of the flow path so as to face the inflow port .
A nozzle device characterized in that the outlet of the liquid provided in the supply flow path is provided with a switching unit for switching the flow path by facing the inlet and outlet of another nozzle. A claim characterized in that the diameter of the smallest circle containing the plurality of spouts is larger than the distance between both ends of the inlet in one direction, centered on the central position of the distribution of the plurality of spouts. Item 1. The nozzle device according to Item 1. The nozzle device according to claim 1 or 2, wherein the shielding portion is provided at a position closer to the inflow port.

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