JP6712563B2 - Shoulder bath device - Google Patents

Description

The present invention relates to a shoulder bath device that discharges hot water from a nozzle into a bathtub.

It is known that warming the shoulders and the back of the neck improves blood circulation and improves stiffness in the shoulders and coldness. Therefore, conventionally, for example, as described in Patent Document 1, Patent Document 2, and Patent Document 3, hot water is discharged from a nozzle installed in the bathtub toward the inside of the bathtub, and is then applied to the shoulders or neck of the bather. Known is a shoulder bath device.

Utility model registration No. 2563920 JP, 2016-69972, A JP, 2005-226628, A

However, the above technique has the following problems. That is, in the shoulder bath device described in Patent Document 1, Patent Document 2, and Patent Document 3, the nozzle was fixed to the bathtub. Therefore, it is inconvenient for the bather to take a posture by aligning the shoulder and neck with the position where the hot water discharged from the nozzle falls.

The present invention has been made in order to solve the above problems, and in a shoulder bath device that discharges hot water from a nozzle toward the inside of a bathtub, a technique that allows a bather to enjoy the shoulder bath more comfortably is provided. The purpose is to provide.

The present invention has been made to solve the above problems. In one aspect thereof, in a shoulder bath device that discharges hot water from a nozzle into a bathtub, a height adjusting member that adjusts the height of the nozzle, a supply circuit through which the hot water flows, and the nozzle are connected. According to the position of the nozzle whose height is adjusted by the height adjusting member, the hose moves forward and backward in the bathroom.

In the shoulder bath device having this configuration, the nozzle can be installed at any height by the height adjusting member while moving the hose forward and backward into the bathroom. The height-adjusted nozzle discharges the hot water supplied from the supply circuit via the hose. In such a shoulder bath device, the bather can arbitrarily adjust the height of the nozzle according to the position of his/her shoulder or neck. Therefore, according to the above-mentioned shoulder bath device, the bather can comfortably enjoy the shoulder bath in a relaxed posture.

Further, in the shoulder bath device having the above configuration, it is preferable that the height adjusting member is a magnet attached to the nozzle.

In the shoulder bath device having this configuration, since the wall surface of the bathroom includes the metal plate, the nozzle can be easily attached to an arbitrary position with respect to the wall surface of the bathroom by the magnet attached to the nozzle. Therefore, according to the above-mentioned shoulder bath device, the position of the nozzle can be easily adjusted according to the physique of the bather.

Further, in the shoulder bath device having the above-mentioned configuration, the nozzle includes a first nozzle and a second nozzle having different discharge port shapes, and the hose is replaceably attached to the first nozzle and the second nozzle. , Are preferred.

In the shoulder bath device having this configuration, the shape of the hot water discharged from the discharge port of the first nozzle is different from the shape of the hot water discharged from the discharge port of the second nozzle. Therefore, the user can enjoy different types of shoulder bath by simply replacing the first nozzle and the second nozzle with the hose.

Further, in the shoulder bath device having the above configuration, the supply circuit is a circulation circuit that drives a pump to circulate the bath water in the bathtub, the first nozzle is provided with a slit, and the hot water is supplied from the slit. Is discharged in a film shape, and the slit has an average width in the height direction of 0.5 mm or more and 1 mm or less.

In the shoulder bath device having this configuration, hot water is supplied to the first nozzle at a small flow rate of, for example, 8 L to 16 L per minute depending on the performance of the pump installed in the circulation circuit. The first nozzle is formed with a slit. The average value of the width in the height direction of the slit is as narrow as 0.5 mm or more and 1 mm or less. Therefore, in the first nozzle, the hot water supplied to the slit has its flow channel increased by the slit to increase the flow velocity and spread almost uniformly in the slit. Then, the hot water flows substantially evenly toward the discharge port and is discharged in a film shape from the discharge port forward. The film-shaped hot water drops from the discharge port toward the bathtub in an arc. Therefore, according to the above-described shoulder bath device, the average width of the slits of the first nozzle in the height direction is adjusted to 0.5 mm or more and 1 mm or less without separately installing a dedicated pump with a large discharge flow rate. As a result, the film-shaped hot water can be discharged from the first nozzle by using the pump of the existing circulation circuit, so that the device cost can be reduced.

Further, in the shoulder bath device having the above structure, the second nozzle has a tubular shape, and a plurality of discharge holes are formed along the axial direction, and the hot water is formed into a streak shape from each of the plurality of discharge holes. Discharging, the plurality of discharge holes are formed at a position where a discharge hole formed in a central portion in the axial direction of the second nozzle is higher than discharge holes formed in both end portions in the axial direction of the second nozzle. Preferably.

The shoulder hot water device having this configuration discharges hot water in a streak shape from a plurality of discharge holes formed in the cylindrical second nozzle. On the human skeleton, the neck is higher than both shoulders. The second nozzle is provided with a discharge hole formed at a central portion in the axial direction of the second nozzle at a position higher than discharge holes formed at both ends in the axial direction of the second nozzle. That is, the second nozzle is formed with a plurality of ejection holes according to the height of the neck and shoulders of a person. Therefore, according to the above-mentioned shoulder bath device, the streak-shaped hot water discharged from the plurality of discharge holes can be appropriately applied to the shoulder and neck of the bather to suppress the splash of hot water.

Therefore, according to the present invention, in the shoulder bath device that discharges hot water from the nozzle toward the bathtub, the bather can enjoy the shoulder bath more comfortably.

FIG. 1 is a diagram showing a device configuration of a shoulder bath system using a shoulder bath device according to an embodiment of the present invention. It is a figure explaining height adjustment of a nozzle. It is an appearance perspective view which looked at the 1st nozzle from the front side. FIG. 4 is a sectional view taken along line AA of FIG. 3. It is a figure which shows a mode that the hot water is discharged from the 1st nozzle. It is a front view of a 2nd nozzle. It is a top view of the 2nd nozzle. It is a side view of the 2nd nozzle. It is a figure which shows a mode that the hot water is discharged from the 2nd nozzle. It is a figure explaining the nozzle shape used for the flow simulation, and shows the type which has two water supply ports. It is a figure which shows the 1st simulation result regarding the nozzle of type A1. It is a figure which shows the 1st simulation result regarding the nozzle of type A2. It is a figure which shows the 1st simulation result regarding the nozzle of type A3. It is a figure which shows the 1st simulation result regarding the nozzle of type A4. It is a figure which shows the 1st simulation result regarding the nozzle of type A1. It is a figure which shows the 1st simulation result regarding the nozzle of type A2. It is a figure which shows the 1st simulation result regarding the nozzle of type A3. It is a figure which shows the 1st simulation result regarding the nozzle of type A4. It is a figure which shows the 2nd simulation result regarding the nozzle of type A1. It is a figure which shows the 2nd simulation result regarding the nozzle of type A2. It is a figure which shows the 2nd simulation result regarding the nozzle of type A3. It is a figure which shows the 2nd simulation result regarding the nozzle of type A4. It is a figure which shows the 3rd simulation result regarding the nozzle of type B1. It is a figure which shows the 3rd simulation result regarding the nozzle of type B2. It is a figure which shows the 3rd simulation result regarding the nozzle of type B3. It is a figure which shows the 3rd simulation result regarding the nozzle of type B4. It is a figure which shows the 4th simulation result regarding a nozzle of type B1. It is a figure which shows the 4th simulation result regarding a nozzle of type B2. It is a figure which shows the 4th simulation result regarding a nozzle of type B3. It is a figure which shows the 4th simulation result regarding a nozzle of type B4. It is a figure explaining the nozzle shape used for the flow simulation, and shows the type which has one water inlet. It is a figure which shows the 5th simulation result regarding the nozzle of type C1. It is a figure which shows the 5th simulation result regarding a nozzle of type C2. It is a figure which shows the 5th simulation result regarding a nozzle of type C3. It is a figure which shows the 6th simulation result regarding the nozzle of type D1. It is a figure which shows the 6th simulation result regarding the nozzle of type D2. It is a figure which shows the 6th simulation result regarding a nozzle of type D3. It is a modification of the second nozzle. It is a modification of a height adjustment member.

An embodiment of a shoulder bath device according to the present invention will be described below with reference to the drawings. As shown in FIG. 1, the shoulder basin device 8 is incorporated into the shoulder basin system 1.

First, the configuration of the shoulder bath system 1 will be described with reference to FIG. In the shoulder bath system 1, the shoulder bath device 8 is connected to a circulation circuit 19 that circulates the bath water X between the bathtub 2 and the water heater 4. The shoulder bath device 8 is supplied with the bath water X in the bathtub 2 from the circulation circuit 19 and discharges the hot water toward the bathtub 2. In the present specification, the hot water discharged from the shoulder hot water device 8 is also referred to as “shoulder water Y”. Further, “shed bath Y” is called “shed bath Y1” when discharged from the first nozzle 81 described later, and “shed bath Y2” when discharged from the second nozzle 91 described later. There are also cases.

In the circulation circuit 19, the circulation port 3 provided in the bathtub 2 is connected to the water heater 4 via the return pipe 5 and the outward pipe 6, and the bath water X is operated by the operation of the pump 20 provided in the water heater 4. Is circulated between the bathtub 2 and the water heater 4. At this time, the water heater 4 can reheat the bath water X by driving the burner 4a.

Here, the pump 20 has a discharge capability of circulating the bath water X in the circulation circuit 19 at a flow rate at which the burner 4 a can heat the bath water X. Therefore, as the pump 20, a pump having a discharge flow rate of 8 L/min or more and 16 L/min or less is generally selected.

A three-way valve 7 is arranged in the outward pipe 6. The three-way valve 7 has a first port 7a connected to the water heater 4, a second port 7b connected to the circulation port 3, and a third port 7c connected to the shoulder bath device 8.

The shoulder bath system 1 includes a control unit 18. The control means 18 is composed of a well-known microcomputer. The control means 18 is electrically connected to a water heater remote controller 15 that sets the operation of the water heater 4. The water heater remote controller 15 is connected to the operation remote controller 16 via a communication line 17. The water heater remote controller 15 is configured such that the setting of the driving remote controller 16 is automatically reflected in its own device. The water heater remote controller 15 and the operation remote controller 16 include buttons for performing various settings of the water heater 4. This button may be an on/off type analog switch or a digital switch displayed on a liquid crystal touch panel. In this embodiment, the water heater remote controller 15 is installed in the kitchen, and the operation remote controller 16 is installed in the bathroom.

The control means 18 is electrically connected to the three-way valve 7, the burner 4a and the pump 20. When the control means 18 receives an instruction to execute the shoulder bath mode from the operation remote controller 16 via the water heater remote controller 15, the control means 18 activates the shoulder bath control program stored in the storage area to control the operations of the three-way valve 7 and the pump 20. To do. That is, the control means 18 controls the operation of the three-way valve 7 so that the first port 7a is communicated with the third port 7c and the second port 7b is shut off, and the pump 20 is driven, whereby the bath of the bathtub 2 is controlled. The water X is supplied to the shoulder bath device 8, and the shoulder bath Y is discharged from the shoulder bath device 8. At this time, the control means 18 may drive the burner 4a of the water heater 4 to heat the bath water X to a predetermined set temperature by the water heater 4 and then supply it to the shoulder bath device 8.

On the other hand, when the control means 18 receives an instruction to execute the reheating mode from the operation remote controller 16 via the water heater remote controller 15, the control means 18 activates the reheating program stored in the storage area to start the three-way valve 7, the burner 4a, and the pump 20. Control the behavior of. That is, the control means 18 connects the first port 7a to the second port 7b, controls the operation of the three-way valve 7 so as to shut off the third port 7c, and drives the burner 4a and the pump 20 to supply hot water. The bath water X heated in the vessel 4 is supplied to the bathtub 2.

Next, the configuration of the shoulder bath device 8 will be described with reference to FIG. The shoulder bath device 8 includes a first nozzle 81, a hose 82, and a holding member 84. The shoulder bath device 8 is configured so that the height of the first nozzle 81 can be adjusted.

The hose 82 has flexibility and is stored on the back side of the bathtub 2. The end of the hose 82 is drawn out into the bathroom through a through hole 2a formed in the bathtub 2. The first nozzle 81 is detachably connected to the tip of the hose 82. On the other hand, the hose 82 has a rear end communicating with the third port 7c (see FIG. 1) of the three-way valve 7.

The holding member 84 is disposed on the inner wall of the through hole 2a of the bathtub 2 and guides the hose 82 from the back side of the bathtub 2 into the bathroom. Further, the holding member 84 seals between the hose 82 and the inner peripheral surface of the through hole 2a in order to prevent hot water from flowing into the back side of the bathtub 2.

The first nozzle 81 has a first magnet 814 fixed thereto with an adhesive or the like. The wall surface W of the bathroom includes a metal plate. Therefore, the first nozzle 81 can be attached to an arbitrary position with respect to the wall surface W via the first magnet 814.

As shown in FIGS. 5 and 9, a first nozzle 81 and a second nozzle 91 having different discharge port shapes are replaceably attached to the tip of the hose 82.

As shown in FIG. 5, the first nozzle 81 is configured to discharge the hot water supplied from the hose 82 in a film shape.

That is, as shown in FIG. 3, the first nozzle 81 includes a plate-shaped first nozzle body 810. The first nozzle body 810 may be formed of resin so as not to be cold when touched by a person, or may be formed of metal and the surface thereof may be coated with resin or the like.

As shown in FIG. 4, a slit 811 is formed in a rectangular shape in the first nozzle body 810 in parallel with the upper and lower end surfaces having a large area. The slit 811 has one side opening to the front side edge portion in the longitudinal direction of the first nozzle body 810, and the slit opening portion 813 constitutes a discharge port formed in a slender shape along the longitudinal direction of the first nozzle 81. ing. The first nozzle 81 has an inlet 812 for allowing hot water to flow from the hose 82 into the slit 811. The inflow port 812 is provided at the back of the slit 811 located on the opposite side of the slit opening 813, and at the center of the slit 811 in the longitudinal direction. The slit 811 has a uniform thickness W1 in the height direction. The thickness W1 is an example of the width in the height direction. The thickness W1 is set to a size of 0.5 mm or more and 1.0 mm or less.

In such a first nozzle 81, the hot water that has flowed into the slit 811 from the inflow port 812 has its flow channel increased by the slit 811 to increase its flow rate and spread almost uniformly over the entire slit 811. Therefore, as shown in FIG. 5, the hot water discharged from the slit opening 813 has a continuous film shape.

In the first nozzle body 810, the first magnet 814 is integrally attached to the rear side edge portion, which is located on the opposite side of the front side edge portion including the slit opening 813, with an adhesive or the like.

On the other hand, as shown in FIG. 9, the second nozzle 91 is configured to discharge the hot water supplied from the hose 82 in a streak shape.

That is, as shown in FIGS. 6, 7, and 8, the second nozzle 91 includes a tubular second nozzle body 910. As shown in FIG. 6, in the second nozzle body 910, a plurality of discharge holes 913 are formed at equal intervals along the axial direction and communicate with the internal flow passage 911. The second nozzle body 910 forms an ejection port by the plurality of ejection holes 913.

As shown in FIG. 7, the second nozzle 91 is provided with an inflow port 912 for flowing hot water from the hose 82 into the internal flow path 911. The inflow port 912 is formed at the axial center position of the internal flow path 911.

As shown in FIG. 8, the second nozzle body 910 has a flat surface 915 on the side opposite to the ejection holes 913. The second magnet 914 is integrally attached to the flat surface 915 with an adhesive or the like.

Here, as shown in FIG. 6, the plurality of ejection holes 913 are formed in the central ejection hole group 913a, the intermediate ejection hole group 913b, and the end ejection hole group 913c depending on the position formed in the second nozzle 91. being classified. The central discharge hole group 913a is provided in the axial center portion of the internal flow path 911, and is formed at the highest position. The end discharge hole group 913c is provided at both ends of the second nozzle 91, and is formed at the lowest position. The intermediate discharge hole group 913b is provided in the middle of the center discharge hole group 913a and the end discharge hole group 913c, and is located at a height between the center discharge hole group 913a and the end discharge hole group 913c. Has been formed. That is, the height of the position where the discharge hole 913 is formed is changed stepwise.

In such a second nozzle 91, as shown in FIG. 9, the hot water flowing into the internal flow path 911 from the inflow port 912 is discharged in a streak shape from the respective discharge holes 913.

By the way, the pump 20 is used for reheating in an existing bus system, and the discharge flow rate is about 8 L/min or more and 16 L/min or less. In order to discharge the film-shaped hot water from the first nozzle 81 using this pump 20, the inventors changed the shape of the nozzle and performed various simulations. The shape was specified. This simulation will be described.

The inventors performed a first simulation for investigating the relationship between the thickness of the slit and the distribution of the liquid ratio in the space. In this first simulation, the nozzles of type A1, type A2, type A3, and type A4 in which the thickness W1 of the slit 811 is different were analyzed. In each of the nozzles of types A1 to A4, as shown in FIG. 10, inflow ports 812 are provided at two locations. The inner diameter W5 of the inflow port 812 is 23 mm, respectively. In the nozzles of types A1 to A4, the water inlet gap W4 is 150 mm, the longitudinal width W2 of the slit 811 is 300 mm, and the width W3 of the slit 811 in the depth direction is 80 mm. However, in the type A1 nozzle, the thickness W1 of the slit 811 is 0.5 mm. In the nozzle of type A2, the thickness W1 of the slit 811 is 1.0 mm. In the nozzle of type A3, the thickness W1 of the slit 811 is 1.5 mm. In the nozzle of type A4, the thickness W1 of the slit 811 is 2.0 mm. Water is allowed to flow into each inflow port 812 by 6 L/min. That is, in each of the nozzles of types A1 to A4, water flows into the slit 811 at a flow rate almost equal to the discharge flow rate of the pump 20, that is, a flow rate of 12 L/min.

11 to 18 show the first simulation result. 11 to 14 are first simulation results when the nozzles are viewed obliquely. 15 to 18 are first simulation results when the respective nozzles are viewed from above. And FIG. 11 and FIG. 15 are the first simulation results regarding the nozzle of type A1 and correspond to each other. FIG. 12 and FIG. 16 are the first simulation results for the nozzle of type A2 and correspond to each other. FIG. 13 and FIG. 17 are the first simulation results for the nozzle of type A3 and correspond to each other. FIG. 14 and FIG. 18 are the first simulation results for the nozzle of type A4 and correspond to each other.

As shown by M11 in FIG. 11, M21 in FIG. 12, M31 in FIG. 13, and M41 in FIG. 14, in all of the nozzles of types A1 to A4, water spreads over the entire slit 811 at a uniform flow rate. As shown by M12 and M13 in FIG. 11 and M22 and M23 in FIG. 12, the nozzles of type A1 and type A2 have small variations in the flow rate of water discharged from the slit openings 813. Moreover, the interval of the variation is narrow. However, as shown by M32 and M33 in FIG. 13 and M42 and M43 in FIG. 14, the nozzles of type A3 and type A4 have large variations in the flow rate of water discharged from the slit opening 813.

Then, as shown in P11 of FIG. 15 and P21 of FIG. 16, the type A1 and type A2 nozzles discharge water from the entire slit opening 813 toward the front. However, in the nozzles of type A3 and type A4, as shown in P32 of FIG. 17 and P42 of FIG. 18, a portion where water is discharged forward from the slit opening 813, P31 of FIG. 17 and P41 of FIG. As shown in FIG. 5, there is a mixed portion of water that drips directly from the slit opening 813.

Further, the inventors performed a second simulation for examining the flow velocity distribution for the nozzles of types A1 to A4. In this second simulation, the flow velocity of water was analyzed under the same conditions as in the first simulation. 19 to 22 show the results of the second simulation.

In the nozzles of type A1 and type A2, as shown in Q10 and Q11 of FIG. 19 and Q20 and Q21 of FIG. 20, there is a difference between the flow velocity immediately before flowing into the inlet and the flow velocity immediately after flowing into the inlet 812. large. On the other hand, the nozzles of type A3 and type A4 have a flow velocity immediately before flowing into the inflow port and a flow velocity immediately after flowing into the inflow port 812, as indicated by Q30 and Q31 in FIG. 21 and Q40 and Q41 in FIG. The difference is small. That is, in the nozzles of the types A1 and A2, compared with the nozzles of the types A3 and A4, the flow velocity is accelerated by the water flowing into the slit 811 from the inflow port 812.

In the nozzles of type A1 and type A2, as shown in Q12 of FIG. 19 and Q22 of FIG. 20, the flow velocity in the slit 811 is substantially uniform. Therefore, in the nozzles of type A1 and type A2, as shown in Q13 of FIG. 19 and Q23 of FIG. 20, water is discharged from the entire slit opening 813 at substantially the same flow rate.

However, in the nozzles of type A3 and type A4, as shown in Q32, Q33 of FIG. 21 and Q42, Q43 of FIG. 22, the flow velocity in the central portion of the slit 811 and the vicinity of the inner wall is particularly high, and thus in the slit 811. The flow velocity is uneven. In the nozzles of type A3 and type A4, as shown in Q34, Q35 of FIG. 21 and Q44, Q45 of FIG. At the portion where the flow velocity is discharged forward and the flow velocity is slow in the slit 811, water is discharged at a slow flow velocity from the slit opening 813 and flows downwardly. That is, in the type A3 and type A4 nozzles, the water discharged from the slit opening 813 is interrupted, and a continuous film shape is unlikely to occur.

From the first simulation result and the second simulation result, when the bath water X is supplied to the shoulder bath device 8 using the pump 20, it is possible to discharge water in a film shape from the entire slit opening 813 of the slit 811. It has been found that it is preferable to set the thickness W1 of the slit 811 to 1.0 mm or less.

However, if the thickness W1 of the slit 811 is too small, water does not spread uniformly in the slit 811, and the flow velocity fluctuates. In this case, as in the case of the type A3 and type A4 nozzles, the water discharged from the slit opening 813 is interrupted, and a continuous film shape is unlikely to be formed. Therefore, the thickness W1 of the slit is preferably 0.5 mm or more and 1.0 mm or less.

Next, the inventors performed a third simulation for examining the relationship between the chamfering of the slit and the distribution of the liquid ratio in the space. In this third simulation, the nozzles of type B1, type B2, type B3, and type B4 were analyzed. The nozzles of types B1 to B4 are different in the presence and size of the chamfer N shown by the phantom line in FIG. In the nozzles of types B1 to B4, the inner diameter W5 of the inflow ports 812 provided at two locations is 23 mm. In the types B1 to B4, the thickness W1 of the slit 811 is 1.0 mm, the width W2 of the slit 811 in the longitudinal direction is 300 mm, and the width W3 of the slit 811 in the depth direction is 80 mm. However, in the type B1 nozzle, the slit 811 is not chamfered N, and the slit 811 is formed in a rectangular shape. In the nozzles of types B2 to B4, the corners on the far side of the slit 811 opposite to the slit opening 813 are chamfered N. The nozzle of type B2 is chamfered N by 50 mm in the depth direction and 50 mm in the longitudinal direction. The nozzles of types B3 and B4 are chamfered N by 70 mm in the depth direction and 70 mm in the longitudinal direction, respectively. In the nozzles of types B1 to B3, the distance W4 between the inflow ports 812 is 150 mm. In the nozzle of type B4, the distance W4 between the inlets 812 is 100 mm. Water is allowed to flow into each inflow port 812 by 6 L/min. That is, in each of the nozzles of types B1 to B4, water flows into the slit 811 at a flow rate almost equal to the discharge flow rate of the pump 20, that is, a flow rate of 12 L/min.

23 to 26 show the third simulation result. As shown in S11 and S12 of FIG. 23, in the type B1 nozzle, water is evenly spread over the entire slit 811 and is continuously discharged from the slit opening 813 even if chamfering is not performed. Further, as shown in S21 and S22 of FIG. 24, in the type B2 nozzle, water is spread uniformly over the entire slit 811 and is continuously discharged from the slit opening 813, as in the type B1 nozzle. However, when the chamfer N becomes large like the nozzle of type B3 shown in FIG. 25, even if the water uniformly spreads in the slit 811 like S31 in the figure, as shown in S32 in FIG. There is a dripping point. That is, the type B3 nozzle cannot continuously discharge water from the slit opening 813. Further, in the nozzle of type B4 shown in FIG. 26, in order to make it difficult for the water discharged from the inlet 812 to flow to the chamfer N side of the slit 811, the interval W4 of the inlet 812 is made narrower than that of the nozzle of type B3. There is. However, as shown in S42 of FIG. 26, the nozzle of type B4 also has a portion where water drips directly downward from the slit opening 813. That is, the type B4 nozzle cannot continuously discharge water from the slit opening 813.

The inventors also performed a fourth simulation for examining the flow velocity distribution for the nozzles of types B1 to B4. In this fourth simulation, the flow velocity of water was analyzed under the same conditions as in the third simulation. 27 to 30 show the result of the fourth simulation.

As shown at T12 in FIG. 27, the nozzle of type B1 has a substantially uniform flow velocity throughout the slit 811. Then, as shown by T13 in the figure, the nozzle of type B1 has a uniform flow velocity of the water discharged from the slit opening 813.

On the other hand, when chamfering N is performed, as in the case of the nozzle of type B2 shown in FIG. 28, when chamfering N is small, the variation in the flow velocity in the slit 811 is small as indicated by T22 in the figure. Then, as indicated by T23 in the figure, the variation in the flow velocity of the water discharged from the slit opening 813 is small. However, when the chamfer N is large like the type B3 nozzle shown in FIG. 29, as shown by T31 and T32 in the figure, the flow velocity near the inner wall of the slit 811 and near the longitudinal center of the slit 811 increases. The variation of the flow velocity in the slit 811 increases. Therefore, in the nozzle of type B3, as shown by T33 and T34 in the figure, the flow velocity of water discharged from the slit opening 813 has a large variation. Then, in the nozzle of type B3, the water was flowing so as to drip right below in the portion where the flow velocity when discharged from the slit opening 813 was small. In the nozzle of type B4 shown in FIG. 30, the flow velocity also fluctuates within the slit 811 as indicated by T41 and T42 in the figure. Therefore, the flow velocity of water discharged from the slit opening 813 also varies as indicated by T43 and T44 in the figure. Therefore, also in the nozzle of type B4, as shown in T43 in the figure, similarly to type B3, a portion where water flows so as to drip directly downward from the slit opening 813 occurred.

From the third simulation result and the fourth simulation result, when the bath water X is supplied to the shoulder bath device 8 using the pump 20, it is possible to discharge water in a film shape from the entire slit opening 813 of the slit 811. It was found that the slit 811 does not need to be chamfered N and may have a rectangular shape.

Next, the inventors performed a fifth simulation in which the slit thickness W1 was fixed to 1.0 mm and the relationship between the width W3 in the depth direction of the slit and the distribution of the liquid ratio in the space was examined. In this fifth simulation, the nozzles of type C1, type C2, and type C3 were analyzed. In the types C1 to C3, as shown in FIG. 31, an inflow port 812 having an inner diameter W5 of 23 mm is provided on the inner side of the longitudinal center of the slit 811. In the types C1 to C3, the slit 811 has a thickness W1 of 1.0 mm and the slit 811 has a longitudinal width W2 of 300 mm. Types C1 to C3 differ in the width W3 of the slit 811 in the depth direction. That is, in the nozzle of type C1, the width W3 of the slit 811 in the depth direction is set to 80 mm. In the nozzle of type C2, the width W3 of the slit 811 in the depth direction is 100 mm. In the nozzle of type C3, the width W3 of the slit 811 in the depth direction is 120 mm. In addition, it was decided that water would flow into the inflow port 812 by 14 L/min. That is, water flows into the slits 811 of types C1 to B3 at a flow rate almost equal to the discharge flow rate of the pump 20. 32 to 34 show a fifth simulation result.

In the nozzles of the types C1 to C3 shown in FIGS. 32 to 34, water spreads evenly over the entire slit 811 even if the depth width W3 is different. Therefore, it was found that the width W3 of the depth of the slit 811 has a small influence on discharging water in a continuous film shape from the slit opening 813. Further, it was found from the first simulation result and the fifth simulation result that water can be discharged in a continuous film shape even if the inflow port 812 is reduced from two locations to one location.

Next, the inventors performed a sixth simulation for investigating the relationship between the inflow amount of the fluid and the distribution of the liquid ratio in the space. In this sixth simulation, nozzles of the same shape are used, and the nozzles are classified into type D1, type D2, and type D3 according to the inflow amount of water. In each of the nozzles of types D1 to D3, the thickness W1 of the slit 811 is set to 1.5 mm. In the nozzles of types D1 to D3, the width W2 of the slit 811 in the longitudinal direction is 300 mm and the width W3 of the slit 811 in the depth direction is 85 mm. Further, in each of the nozzles of types D1 to D3, one inflow port 812 having an inner diameter W5 of 23 mm is provided on the inner side of the longitudinal center of the slit 811. In the type D1 nozzle, water flows into the inflow port 812 by 14 L/min. In the nozzle of type D2, water flows into the inflow port 812 by 16 L/min. In the nozzle of type D3, water flows into the inflow port 812 by 18 L/min. 35 to 37 show the sixth simulation result.

As shown by U11 and U12 in FIG. 35, in the nozzle of type D1, the water is not uniformly dispersed in the slit 811, and the flow is uneven. That is, even if the water inflow rate is the same at 14 L/min, if the thickness W1 of the slit 811 increases from 1.0 mm to 1.5 mm, the water flow rate distribution in the slit 811 becomes uneven, and the slit opening portion The flow rate of water discharged from 813 also varies. In this case, the water in the low flow rate portion is drawn to the high flow rate side, and it becomes difficult to apply the water evenly to the entire shoulder or neck of the bather.

Therefore, in the type D2 and type D3 nozzles, the inflow amount of water is increased more than that in the type D1 nozzle. In this case, the nozzles of type D2 of FIG. 36 and the nozzles of type D3 of FIG. 37 were such that water was dispersed uniformly in the slit 811 as indicated by U21 and U31 in the figure. However, in the nozzles of type D2 and type D3, the proportion of water discharged from the slit opening 813 varies, as indicated by U22, U23 in FIG. 36 and U32, U33 in FIG. That is, the type D2 and type D3 nozzles cannot discharge water in a continuous film form from the slit openings 813.

From the sixth simulation result, it was found that when the thickness W1 of the slit 811 exceeds 1.0 mm, water cannot be discharged in a film shape from the slit opening 813 even if the flow rate is increased. That is, it has been found that when the thickness W1 of the slit 811 is larger than 1.0 mm, the existing pump 20 cannot discharge hot water in a continuous film shape.

Next, the operation of the shoulder bath device 8 will be described. A bather attaches the 1st nozzle 81 to the front-end|tip part of the hose 82, for example. Then, the bather operates the buttons on the driving remote controller 16, selects the shoulder bath mode, and inputs a start instruction. Then, the control means 18 causes the first port 7a of the three-way valve 7 to communicate with the third port 7c and drives the pump 20. As a result, the bath water X in the bathtub 2 flows from the return pipe 5 to the water heater 4, the outward pipe 6, the three-way valve 7, and the first nozzle 81 of the shoulder bath device 8. In the shoulder bath device 8, the bath water X is supplied from the hose 82 to the first nozzle 81, and the film-shaped shoulder bath Y1 is discharged from the slit opening 813.

On the other hand, the bather, after attaching the second nozzle 91 to the tip of the hose 82, operates the button on the operation remote controller 16 to select the shoulder bath mode and inputs the start instruction. Is supplied to the shoulder bath device 8 via the circulation circuit 19. In the shoulder bath device 8, the bath water X is supplied to the second nozzle 91 from the hose 82, and the streak-shaped shoulder bath Y2 is discharged from the plurality of discharge holes 913.

As described above, in the shoulder bath device 8, while circulating the bath water X between the bathtub 2, the circulation circuit 19 and the shoulder bath device 8, the shoulder bath Y1 or the shoulder bath Y2 is discharged from the first nozzle 81 or the second nozzle 91. Is discharged, the bath water X in the bathtub 2 can be used to warm the shoulders and neck. That is, since the shoulder bath device 8 circulates the bath water X, wasteful hot water is not used and the energy saving effect is high. Further, since the shoulder water bath device 8 uses the existing pump 20 to supply the bath water X to the first nozzle 81 or the second nozzle 91 of the shoulder water bath device 8, a dedicated pump having a larger discharge flow rate than the pump 20 (for example, In comparison with the case of using a pump having a discharge flow rate of 30 L/min), the equipment cost can be suppressed. Furthermore, even when bathing the lower half of the body, the shoulder water Y1 discharged from the first nozzle 81 or the shoulder water Y2 discharged from the second nozzle 91 can be applied to the entire neck and shoulders. You can prevent the upper body from getting cold by using the bath water X.

Here, in the shoulder bath device 8, the first nozzle 81 or the second nozzle 91 is detachably attached to the wall surface W via the first magnet 814 or the second magnet 914. Therefore, the bather can easily adjust the height of the first nozzle 81 or the second nozzle 91 according to his/her posture. Therefore, the bather can apply the shoulder bath Y to the entire neck or shoulder in his/her favorite posture, and can obtain a high relaxing effect.

Then, the bather can easily enjoy different types of shoulder bath by replacing the first nozzle 81 and the second nozzle 91 with the tip of the hose 82.

That is, the first nozzle 81 discharges hot water in a continuous film shape from the slit opening 813 of the slit 811. In this case, the warm water gently hits the bather's shoulders and neck. Therefore, by using the first nozzle 81, the bather is warmed from the core of the body to promote blood circulation.

On the other hand, the second nozzle 91 discharges the hot water in a streak shape from the plurality of discharge holes 913. The muscle-shaped shoulder water Y2 has a larger flow rate per unit area than the membrane-shaped shoulder water Y1 and has a large impact when it hits the body. Therefore, when the second nozzle 91 is used, the streak-shaped shoulder water Y2 hits the bather's neck and shoulders with an appropriate impact feeling. Therefore, the bather can obtain not only the effect of warming the neck and shoulders but also the effect of massage.

Moreover, since the first nozzle 81 and the second nozzle 91 are removably attached to the wall surface W via the first magnet 814 and the second magnet 914, for example, the bather can change the first nozzle 81 and the second nozzle 91 according to his/her physical constitution. The height at which the first nozzle 81 and the second nozzle 91 are installed can be easily adjusted. Further, when using the second nozzle 91, the bather can increase the feeling of hitting the shoulder bath Y2 that hits the neck or shoulder as the second nozzle 91 is placed at a higher position. Therefore, by adjusting the height of the second nozzle 91, the bather can easily adjust the strength of impact of the shoulder bath Y2 according to his/her preference.

By the way, the shoulder bath device 8 discharges the hot water of the bathtub 2 circulating in the circulation circuit 19 from the first nozzle 81 or the second nozzle 91. The bath water X normally circulates in the circulation circuit 19 at a small flow rate of 8 L to 16 L per minute. Therefore, when using the shoulder bath device 8, the bath water X is supplied to the slit 811 of the first nozzle 81 at a small flow rate of 8 L to 16 L per minute. In the first nozzle 81, the average value of the thickness W1 of the slit 811 is as small as 0.5 mm or more and 1.0 mm or less. Therefore, the bath water X supplied from the inflow port 812 to the slit 811 spreads over the entire slit 811 at a substantially uniform flow rate due to its own pressure. Since the thickness W1 of the slit 811 is small, the flow rate of the bath water X is reduced when flowing into the slit 811 from the inflow port 812, and the flow velocity is accelerated. The bath water X has a substantially uniform flow velocity in the slit 811, and flows toward the slit opening 813. Therefore, the first nozzle 81 discharges the membrane-shaped shoulder water Y1 from the slit opening 813 even when the bath water X is used as the shoulder water Y by using the existing circulation circuit 19 and the existing pump 20. You can The shoulder bath Y1 is discharged forward from the slit opening 813 and falls into the bathtub 2 in a circular arc. Therefore, the bather is not limited to the posture in which the shoulder or the neck approaches the slit opening 813 of the first nozzle 81, and applies the film-shaped shoulder bath Y1 to the entire neck or the shoulder in a relaxed posture. You can

On the other hand, in the second nozzle 91, the ejection holes 913 provided in the central portion in the longitudinal direction of the second nozzle 91 are provided at a position higher than the ejection holes 913 provided in both ends of the second nozzle 91. Human skeleton, neck is higher than both shoulders. Therefore, the second nozzle 91 is provided at the highest position of the central discharge hole group 913a formed at the longitudinal center of the second nozzle 91, and the intermediate discharge hole groups 913b on both sides of the central discharge hole group 913a. Are provided at the next highest position, and the end discharge hole group 913c outside the intermediate discharge hole group 913b is provided at the lowest position. As a result, the second nozzle 91 makes it easier to apply the streak-shaped shoulder water Y2 discharged from the plurality of discharge holes 913 to the bather's shoulder or neck. Further, since the position of the discharge hole 913 is formed so as to match the skeleton of the human, it is possible to suppress a problem such as a part of the streak-shaped hot water hitting the head of the bather, and it is possible to suppress the splash of hot water.

The present invention is not limited to the above-described embodiment, but can be applied in various ways.

For example, the plurality of ejection holes 913 may be formed at the same height. Mostly, by providing a height difference at the position where the plurality of ejection holes 913 are formed, splash of hot water can be prevented. When the height differences are provided in the plurality of ejection holes 913, for example, as shown in FIG. 38, the second nozzle 91 has a plurality of ejection holes 913, and the ejection hole 913 located at the center of the second nozzle 91 in the longitudinal direction. It may be formed so as to draw an arc so that it is at the highest position and the discharge holes 913 located at both ends are at the lowest position.

For example, as shown in FIG. 39, the first nozzle 81 is fixed to the poles 111 and 112 installed along the height direction with screws 113 or the like, and the first nozzle 81 is placed at an arbitrary position with respect to the poles 111 and 112. It may be fixed in place. The second nozzle 91 may be fixed similarly to this. However, by fixing the first and second nozzles 81 and 91 with the first and second magnets 814 and 914, the number of parts of the shoulder bath device 8 can be reduced and the cost can be reduced. Further, cleaning of the bathroom and the first and second nozzles 81 and 91 is also simplified.

For example, the shoulder bath device 8 may be connected to a hot water supply circuit that supplies hot water to discharge hot water from the first nozzle 81 or the second nozzle 91. Of course, the shoulder bath device 8 can improve energy saving by connecting to the circulation circuit 19 and circulating the bath water X.

For example, as the nozzle, only one of the first nozzle 81 and the second nozzle 91 may be attached to the hose 82. Further, the types of nozzles attached to the hose 82 are not limited to the two types of the first nozzle 81 and the second nozzle 91, and may be three or more types.

For example, the hose 82 is drawn from the through hole 2a of the bathtub 2, but may be drawn from the wall surface W of the bathroom. Further, the hose 82 may be provided so as to be expandable and contractible like a bellows.

For example, the magnet may be fixed to a jig with an adhesive or the like, and the first nozzle 81 and the second nozzle 91 may be detachably attached to the jig. That is, the jig including the magnet may be shared by the first nozzle 81 and the second nozzle 91.

For example, the second nozzle body 910 may be rectangular.

For example, the first nozzle 81 may be provided with a plurality of inflow ports 812. In this case, in order to allow water to flow through the slit 811 at a uniform flow rate and flow rate, the plurality of inlets 812 are preferably formed symmetrically with the center of the slit 811 in the longitudinal direction sandwiched therebetween. Then, in this case, it is preferable that the water flows into each of the inflow ports 812 at the same flow rate. However, it is preferable that the distance between the inflow ports 812 at both ends and the inner wall of the slit 811 be at least half the interval at which the plurality of inflow ports 812 are provided. That is, for example, when the longitudinal width W2 of the slit 811 is 300 mm and the inflow ports 812 are provided at two locations, the interval between the inflow ports 812 is 150 mm or less, and the inflow port 812 and the inner wall of the slit 811 are separated from each other. The interval between them is preferably 75 mm or more. When the inflow ports 812 at both ends are formed at positions close to the inner wall of the slit 811, the water flowing into the inflow port 812 is attracted to the inner wall side of the slit 811, and the flow rate and the flow velocity in the slit 811 become uneven. This is because it becomes difficult to discharge water in a continuous film shape from the slit opening 813 of 811. However, by providing one inflow port 812, the flow rate and flow velocity of the hot water flowing through the slit 811 can be easily controlled, and the manufacturing cost of the first nozzle 81 can be reduced. The same applies to the second nozzle 91.

8 Shoulder Bath Device 81 First Nozzle 82 Hose 91 Second Nozzle 811 Slit 813 Slit Opening 814 First Magnet 913 Discharge Hole 914 Second Magnet

Claims (3)

In the shoulder bath device that discharges hot water from the nozzle into the bathtub,
A height adjusting member for adjusting the height of the nozzle,
A hose which connects the supply circuit through which the hot water flows and the nozzle, and which moves forwards and backwards into the bathroom according to the position of the nozzle whose height is adjusted via the height adjusting member. that,
The nozzle includes a first nozzle and a second nozzle having different ejection port shapes,
The first nozzle and the second nozzle are replaceably attached to the hose,
The second nozzle has a tubular shape and a plurality of discharge holes are formed along the axial direction, and the hot water is discharged in a streak shape from each of the plurality of discharge holes.
The plurality of discharge holes are formed such that the discharge holes formed at the center of the second nozzle in the axial direction are higher than the discharge holes formed at both ends of the second nozzle in the axial direction. br/> a shoulder bath device. The shoulder bath device according to claim 1,
The shoulder bath device, wherein the height adjusting member is a magnet attached to the nozzle. In the shoulder bath device according to claim 1 or 2 ,
The supply circuit is a circulation circuit that drives a pump to circulate bath water in the bathtub.
A slit is formed in the first nozzle, and the hot water is discharged in a film shape from the slit.
The slit has an average width in the height direction of 0.5 mm or more and 1 mm or less,
A shoulder bath device.

Images