JP6821145B2 - Bathtub device - Google Patents

Description

The present invention relates to a bathtub device, and more particularly to a bathtub device provided in a bathtub for storing hot water.

Conventionally, for example, as described in Patent Document 1, bathtub water is pumped from a water inlet located inside the bathtub by one pump, and is discharged from an upper spout and a lower spout. A water discharge device that circulates bathtub water is known.
In such a water discharge device, bathtub water is guided from a water supply port to a common headrace via a water supply channel and one pump, and this common headrace is branched into an upper headrace and a lower headrace. The upper spout is designed to change the bathtub water supplied from the upper headrace into band-shaped water and spout water, and the lower spout is designed to bubble-inject the bathtub water supplied from the lower headrace. There is.

Japanese Unexamined Patent Publication No. 2016-7344

However, in the above-mentioned water spouting device, a low-speed large-flow rate of water is spouted from the upper spout to the user's shoulder, and a high-speed small-flow rate is spouted from the lower spout to the user's waist. In this case, the pressure loss of the flow path on the lower spout side where the high-speed small flow rate is discharged is much larger than the pressure loss of the flow path on the upper spout side where the low-speed large flow rate is discharged. Therefore, when water is discharged from both spouts at the same time, the supply of bathtub water to both spouts is greatly biased, and the spout flow rate on the upper spout side increases, while the spout flow rate on the lower spout side becomes insufficient. There is a problem that the massage effect due to the high-speed and small flow rate of water is very weak.
For this reason, conventionally, the water discharge from the upper spout that discharges a low-speed large flow rate and the water discharge from the lower spout that discharges a high-speed small flow rate are switched so as to perform only one of them without simultaneously performing the water discharge. As a result, it was prevented that the discharge water flow rate on the lower spout side was insufficient and the water discharge with a weak massage effect was performed.

Therefore, in the present invention, in the hot water supplied from the common pump, the flow velocity of the hot water discharged from the first spouting section is higher than the flow velocity of the hot water discharged from the second spouting section. It is an object of the present invention to provide a bathtub device capable of simultaneously spouting water from the second spouting unit.

In order to achieve the above object, the present invention is a tub device provided in a tub for storing hot water, which is a pump that sucks the hot water in the tub and supplies the hot water to the downstream flow path of the pump on the downstream side. A first flow path branched from the downstream flow path of the pump, a second flow path branched from the downstream flow path of the pump, and a first discharge water that discharges hot water supplied from the first flow path into the bathtub. A unit, a second water discharge unit that discharges hot water supplied from the second flow path into the bathtub, a control unit that controls a pump, and a jet pump unit are provided, and the spout of the second water discharge unit is a second. The opening is formed larger than the spout of the 1 spout, and the horizontal length of the spout of the second spout is formed to be longer than the length of the spout in the vertical direction. The pump unit is a jet pump water storage unit in which hot water is stored, and an injection unit formed so that its own flow path diameter is smaller than the flow path diameter of its own upstream side flow path. The flow path on the downstream side of the jet pump water storage section is provided with an injection section that induces a jet pump action by accelerating the hot water supplied to the second flow path and injecting it into the jet pump water storage section. The flow path diameter of the flow path on the downstream side is formed to be larger than the flow path diameter of the injection portion. Further, the jet pump unit is provided on the second flow path, and the hot water supplied from the pump is the first. It is characterized in that water is discharged from the first water discharge unit and the second water discharge unit at the same time so that the flow velocity of the hot water discharged from the water discharge unit is higher than the flow velocity of the hot water discharged from the second water discharge unit.
In the present invention configured as described above, by providing the jet pump unit on the second flow path, the pressure loss of the flow path from the first flow path to the first water discharge portion and the pressure loss from the second flow path to the second water discharge portion are obtained. Since the difference between the pressure loss of the flow path leading to the portion and the pressure loss can be made relatively small, the hot water supplied from the common pump is supplied to either the first flow path or the second flow path with a large bias. The flow velocity of the hot water discharged from the first spouting section is higher than the flow velocity of the hot water discharged from the second spouting section so that the hot water supplied from the common pump can be suppressed. And the second spouting unit can spout water at the same time.

In the present invention, preferably, the jet pump unit further includes a bathtub water communication flow path portion formed between the jet pump water storage unit and the bathtub and for introducing hot water from the bathtub into the jet pump water storage unit. ..
In the present invention configured as described above, the hot water of the bathtub is jet-pumped from the bathtub water communication flow path without separately providing a dedicated water supply source for supplying hot water to the jet pump water storage portion of the jet pump unit. It can be introduced into the water storage section, and the overall structure of the bathtub device can be simplified. In addition, since the jet pump water storage section of the jet pump unit is not separately provided with a dedicated water supply source for supplying hot water from outside the bathtub, the flow rate of hot water discharged from the first spouting section by the jet pump unit is larger than that of the hot water discharged from the first spouting section. Even when a large flow rate is discharged from the second water discharge portion into the bathtub, it is possible to prevent the water level in the bathtub, that is, the amount of water from increasing.

In the present invention, preferably, the communication flow path inlet portion of the bathtub water communication flow path portion is formed independently of the pump flow path inlet portion of the pump upstream side flow path that sucks the hot water in the bathtub into the pump. Has been done.
In the present invention configured in this way, the flow of hot water flowing from the bathtub into the communication flow path inlet and the flow of hot water flowing into the pump flow path inlet from the bathtub are independent of the inlet. The flow can be less likely to affect each other, and the hot water flowing from the communication flow path inlet to the bathtub communication section is prevented from being sucked into the pump flow path inlet by the pump. It is possible to stably supply hot water to the jet pump unit.

In the present invention, preferably, the bathtub forms a single inlet flow path portion, and the communication flow path inlet portion and the pump flow path inlet portion are connected to the inlet flow path portion, and further, the inlet flow path is further connected. The flow path cross-sectional area of the portion is formed so as to be larger than the sum of the flow path cross-sectional area of the communication flow path inlet portion and the flow path cross-sectional area of the pump flow path inlet portion.
In the present invention configured as described above, the flow path cross-sectional area of the inlet flow path portion is larger than the sum of the flow path cross-sectional area of the communication flow path inlet portion and the flow path cross-sectional area of the pump flow path inlet portion. The flow of hot water flowing from the bathtub into the communication flow path inlet and the flow of hot water flowing into the pump flow path inlet from the bathtub are branched in the inlet flow path. Since they are formed relatively stably in an independent state, the flows can be less likely to affect each other. Therefore, it is possible to more reliably prevent the hot water flowing toward the bathtub communication portion from being sucked by the pump, and the hot water can be stably supplied by the jet pump unit.
Further, on the bathtub side, one inlet flow path portion can be formed without forming two openings of the communication flow path inlet portion and the pump flow path inlet portion, so that the inlet flow path portion is connected to the bathtub. By reducing the sealing portion between the bathtub and the inlet flow path, the manufacturing work and management work can be reduced, and the risk of water leakage can also be reduced. it can.

In the present invention, preferably, the jet pump unit further includes an opening degree adjusting mechanism capable of adjusting the opening area of the communication flow path inlet portion of the bathtub water communication flow path portion.
In the present invention configured in this way, the flow velocity of the hot water discharged from the first spouting portion is higher than the flow velocity of the hot water discharged from the second spouting portion of the hot water supplied from the common pump. , In a bathing device that can discharge water from the first water discharge part and the second water discharge part at the same time, the setting of the pump and / or the pump itself so as to change the flow velocity and the flow rate of the hot water discharged from the first water discharge part. The flow velocity and flow rate of the hot water discharged from the second water discharge unit can be changed with a relatively simple configuration by the opening degree adjusting mechanism without making any changes.

In the present invention, preferably, the second water discharge unit is a space near the shoulder of the user who sits in the bathtub and bathes the bathtub water supplied from the pump from a position near the upper end of the bathtub above the water surface in the bathtub. It is arranged above the first water spouting portion in order to spout water toward.
In the present invention configured as described above, the flow velocity of the hot water discharged from the first spouting portion is higher than the flow velocity of the hot water discharged from the second spouting portion of the hot water supplied from the common pump. , The second water spouting portion arranged above the first spouting portion can spout water to the upper part of the user's body above the first water spouting portion, for example, the neck and shoulders.

According to the bathtub device of the present invention, the flow velocity of the hot water discharged from the first spouting portion is higher than the flow velocity of the hot water discharged from the second spouting portion of the hot water supplied from the common pump. Water can be discharged from the 1 water discharge unit and the 2 water discharge unit at the same time.

It is a schematic perspective view which shows the bathtub apparatus by one Embodiment of this invention. It is a top view which shows the bathtub apparatus by one Embodiment of this invention. FIG. 5 is a schematic cross-sectional view schematically showing an internal structure of a bathtub device as viewed along lines III-III of FIG. 2 while a user is sitting in the bathtub of the bathtub device according to the embodiment of the present invention. It is a perspective view which shows the jet pump unit of the bathtub apparatus and the spout of a water discharge part by one Embodiment of this invention. It is sectional drawing of the jet pump unit and the spout of a spout part seen along the line III-III of FIG. It is a figure explaining the jet pump operation in the jet pump unit of the bathtub apparatus by one Embodiment of this invention. It is a perspective view which shows the state which the water discharge operation is performed only from a water discharge part with the user sitting in the bathtub of the bathtub apparatus according to one Embodiment of this invention. The internal structure of the bathtub device as viewed along the lines III-III of FIG. 2 while the user is sitting in the bathtub of the bathtub device according to the embodiment of the present invention is schematically shown, and only from the blow water discharge portion. It is a schematic cross-sectional view explaining how the water spouting operation is performed. The internal structure of the bathtub device as viewed along the lines III-III of FIG. 2 while the user is sitting in the bathtub of the bathtub device according to the embodiment of the present invention is schematically shown. It is schematic cross-sectional view explaining how the water discharge operation performed at the same time from a section is performed. It is sectional drawing of the bathtub seen along the X-ray line of FIG. A state in which the opening degree adjusting mechanism of the jet pump unit of the bathtub device according to the embodiment of the present invention is provided in the vicinity of the communication flow path inlet portion, and the opening degree adjusting mechanism is adjusted to an open state in which the communication flow path inlet portion is opened. It is a schematic cross-sectional view which shows. The opening degree adjusting mechanism of the jet pump unit of the bathtub device according to the embodiment of the present invention is provided so as to cover a part of the communication flow path inlet portion, and the opening degree adjusting mechanism covers a part of the communication flow path inlet portion. It is a schematic cross-sectional view which shows the state which is adjusted to the closed state. It is a top view which shows the installation position of the pump in the bathtub apparatus by one Embodiment of this invention. It is a side view which shows the installation position of the pump in the bathtub apparatus by one Embodiment of this invention.

Hereinafter, a bathtub device according to an embodiment of the present invention will be described with reference to the accompanying drawings.
FIG. 1 is a schematic perspective view showing a bathtub device according to an embodiment of the present invention, FIG. 2 is a plan view showing a bathtub device according to an embodiment of the present invention, and FIG. 3 is a plan view showing a bathtub device according to an embodiment of the present invention. FIG. 4 is a schematic cross-sectional view schematically showing the internal structure of the bathing device as viewed along the lines III-III of FIG. 2 with the user sitting in the bathtub of the device, and FIG. 4 is an embodiment of the present invention. It is a perspective view which shows the jet pump unit and the spout of a water discharge part of a bathtub device by a form, and FIG. 5 is a cross-sectional view of the jet pump unit and a spout of a water spout part seen along the line III-III of FIG. ..

As shown in FIGS. 1 and 2, the bathtub device 1 according to the embodiment of the present invention is a bathtub device provided in a bathhouse, a bathroom, a bathroom, or the like in a facility or home.
The bathtub device 1 according to the embodiment of the present invention is a bathtub device 1 provided in a bathtub 2 for storing hot water (bathtub water).
The bathtub device 1 according to an embodiment of the present invention has a pump 4 that sucks hot water in the bathtub 2 and supplies it to the downstream side, and discharges hot water supplied from the pump 4 into the bathtub 2 from the vicinity of the upper end of the bathtub 2. The water discharge unit 6 (second water discharge unit), the control unit 8 that controls the pump 4, the jet pump unit 10 provided on the injection unit side flow path 32 between the pump 4 and the water discharge unit 6, and the bathtub 2. The circulation flow path 14 from the bathtub communication port 12 formed on the vertical wall to the water discharge part 6 or the blow water discharge part 16 described later, and the hot water supplied from the pump 4 are supplied from the vicinity of the center in the vertical direction of the bathtub 2 into the bathtub 2. The blow water discharge unit 16 (first water discharge unit) and the flow path on the downstream side of the pump 4 in the circulation flow path 14 are divided into a flow path on the jet pump unit 10 side and a flow path on the blow water discharge unit 16 side. A switching valve 18 for switching is provided. The bathtub device 1 may include a bathtub 2 for storing hot water (bathtub water).
Here, the hot water stored in the bathtub 2 is the bathtub water stored in the bathtub 2, and the term "hot water" used in the present invention is temperature-controlled in a water supply device of a bathtub device, a water supply device of an external facility, or the like. Not only hot water, which is a mixture of hot water and water, but also water that has already been temperature-controlled from an external water supply, and water from a water supply source is heated to an appropriate temperature and the temperature is adjusted by newly mixing water. It is used to include no hot water. "Hot water" can also be expressed as "water" with different temperatures. For example, hot water is hot water having a temperature of 40 degrees or the like set by the user in the operation unit 38.

In the present embodiment, the bathtub 2 is, for example, a relatively small size square bathtub 2 in which an adult user (bathing person) bathes alone, but the bathtub 2 has such a size and Not only the shape but also a bathtub of a relatively large size that can be accommodated by a plurality of people in a facility or the like may be used, and further, it has other shapes such as a polygonal shape, a round shape, and a curved shape. You may. Further, the bathtub 2 can be used not only as a bathtub for a normal bath but also as a bathtub for a half-body bath and a bathtub used for medical purposes such as massage. When the bathtub 2 is a standard bathtub for an adult user (bathing person) to take a bath by himself, for example, a unit bath for home use, the user's back and head come closer to the short side. Assuming that the user sits down and takes a bath in this way, the water discharge portion 6 is arranged on the short side. The bathtub 2 depends on the size of the user's body, but for example, the user is sitting, the upper body is tilted to the back side, the upper body is tilted to the back side, or the bathtub 2 is lying down. It is a bathtub that allows you to take a bath while lying down with your upper body tilted greatly toward your back and close to your back.
The bathtub 2 is connected to the bottom 2a where the buttocks or feet of the bathing user are in contact, the vertical wall 2b which is often in contact with the back of the bathing user, and the upper part of the vertical wall 2b, and the bathtub 2 is connected. It is provided with an upper end portion 2c forming the upper surface of the above.
The upper end portion 2c is formed at a height position relatively close to the upper body of the bathing user (bather) H, for example, the head, neck, or shoulder. For example, the upper end 2c can be relaxed by placing the back of the head of the user H on the upper end 2c while the bathing user H is sitting with the buttocks on the bottom 2a. It is formed at a high position. The upper end portion 2c may be formed as a substantially flat surface, or may be formed as a curved surface so as to easily match the curved shape of the head or neck.

The bathtub 2 is supplied with hot water that is not temperature-controlled from a water heater or the like based on the operation of the operation unit 38 of the user H, and / or is not temperature-controlled from a water supply source. A water supply device (not shown) is provided so that the water to be supplied and / or the hot water whose temperature is adjusted by adjusting the mixing ratio of these hot water and water can be supplied into the bathtub 2.

A casing 20 is attached to the outside of the bathtub 2. By attaching the casing to the bathtub 2, it is possible to maintain the aesthetic sense of the entire bathtub device 1 and protect the internal electrical parts and the like. The pump 4, the jet pump unit 10, each flow path, and the like, which will be described later, need to be arranged in a very limited space between the casing 20 (or the wall surface W of the bathroom) and the bathtub 2.

The pump 4 can suck the hot water in the bathtub 2 and supply it to the downstream side. The pump 4 is a pump having a function of applying pressure to the sucked hot water and pumping it. The pump 4 sucks the hot water in the bathtub 2 and pumps the hot water downstream as the impeller (not shown) directly connected to the electrically driven electric motor (not shown) rotates. The pump 4 is provided outside the bathtub 2 and inside the casing 20 (or inside the wall surface). In the space between the casing 20 (or the wall surface W) and the bathtub 2, the pump 4, each flow path, the jet pump unit 10, and the like are arranged, so that the installation position and size (size) of the pump 4 are arranged. ), There are many restrictions, and it is difficult to easily increase the size of the pump 4. Further, since the upper region of the space between the bathtub 2 and the casing 20 (or the wall surface W) is often relatively narrow, if the pump 4 is to be enlarged, the pump 4 is used. It is necessary to install it in the lower part, which causes a problem of residual water remaining in the pump after use (residual water that is relatively cold cold water).

As shown by an arrow F7 in FIG. 3, the water discharge unit 6 in the present embodiment discharges hot water from the vicinity of the upper end portion 2c of the bathtub 2 into the bathtub 2. The water discharge portion 6 is arranged near the upper end portion 2c of the bathtub 2. The water discharge unit 6 is arranged above the blow water discharge unit 16. The water discharge portion 6 is arranged above the central portion in the vertical direction of the vertical wall 2b, for example, is arranged on the upper end portion 2c of the central portion. The water discharge unit 6 is the water surface of a predetermined water level of hot water stored in the bathtub 2, for example, the water surface of a preset water supply water level for bathing WL0 (see FIG. 3) under normal use conditions, or the physical body of the bathtub 2. It is located above the water level of the target full water level WL1. Therefore, the water discharge unit 6 forms an aerial water discharge unit that discharges hot water into the air (in the atmosphere). More specifically, the water discharge unit 6 directs the bathtub water toward the space near the shoulder of the user H in the state of sitting and bathing from a position above the water surface of the normal water supply water level WL0 in the bathtub 2. Water is discharged into the bathtub 2 from the vicinity of the upper end portion 2c of the bathtub 2 so as to discharge water. Further, the water discharge portion 6 is arranged at a height position above the upper end portion 2c of the bathtub 2 or at a height position within 200 mm downward from the upper end portion 2c. The water discharge portion 6 may be arranged at a height position above the headrest provided at the upper end portion 2c of the bathtub 2 or at a height position within 200 mm downward from the upper end portion thereof.

As shown in FIG. 4, in the present embodiment, the water spouting portion 6 forms a wide spouting port 22 which is relatively long in the lateral direction. The water spouting unit 6 spouts hot water like a waterfall from the spout 22 formed so as to spread in the left-right direction (horizontal direction with respect to the height direction) with respect to the center of the bathtub 2 toward the front side (inside the bathtub 2). Spout water. Specifically, such a water spouting portion 6 is formed so that the length l of the spouting port 22 in the left-right direction is larger than the height h of the spouting port 22 in the vertical direction of the water spouting portion 6. The lateral length l of the spout 22 is formed to be approximately the average shoulder width of an adult. For example, the length l of the spout 22 in the left-right direction is formed to be half the length of the short side of the bathtub 2 or two-thirds the length of the short side of the bathtub 2. You may. Further, for example, the length l of the spout 22 in the left-right direction can be formed to have a length in the range of 300 mm to 500 mm.

As shown in FIGS. 4 and 5, the water spouting portion 6 forms a spouting port 22 that opens laterally toward the front side (inside the bathtub 2). The spout 22 forms a rectangular spout 22 that extends substantially parallel to the upper surface of the bathtub 2. Further, in the water discharge portion 6, the bottom surface 22a of the flow path in the water discharge portion connected to the water discharge port 22 is formed to be substantially flat. Therefore, as shown in FIG. 7, the hot water discharged laterally flows downward in a parabola in the air as a stream of stable band-shaped (water film-like) flowing water having a substantially constant width and thickness.

The upper surface 6a of the water discharge portion 6 has a relaxed posture in which the user H puts his head (for example, the back of his head) on the upper surface 6a of the water discharge portion (for example, the head of his body is placed on the upper surface of the water discharge portion 6 and his back is on the vertical wall). A curved surface that gently descends toward the inside of the bathtub 2 is formed so that the user can take a relatively comfortable posture (as if he / she is sitting on the bottom 2a). The water discharge portion upper surface 6a can function as a headrest that supports the head of the user H. When the user H puts his head on the upper surface 6a of the water discharge portion and takes a relaxed posture, the hot water discharged from the water discharge portion 6 hits the neck and shoulders. Further, when the user H puts his head on the upper surface 6a of the water discharge portion and takes a relaxed posture, the hot water discharged from the water discharge portion 6 spreads from the shoulder to the front side (chest side) of the user H. And / or flows from the shoulder to the back side (back side) of the user H. Therefore, hot water can warm not only the neck and shoulders but also the chest, abdomen, back and waist. For example, the water discharge state in which a part of the hot water discharged from the water discharge unit 6 is discharged toward the user's shoulder as described above is defined as the shoulder water discharge state.

The circulation flow path 14 is connected to the inlet flow path 24 (inlet flow path portion) extending from the tub communication port portion 12 and the inlet flow path 24, and is relatively obliquely upward from the inlet flow path 24 toward the tub communication portion 42. A communication flow path 26 extending over a short distance, a pump upstream side flow path 28 connected to the inlet flow path 24 and extending downward from the inlet flow path 24 toward the pump 4, and a switching valve connected to the downstream side of the pump 4. The pump downstream side flow path 30 extending to 18, the injection part side flow path 32 (second flow path) branched from the pump downstream side flow path 30 and extending from the switching valve 18 toward the jet pump unit, and the bath communication part 42. Bath water introduction flow path 34 (second flow path) extending from the water discharge section 6 to the blow water discharge section side flow path branched from the pump downstream side flow path 30 and extending from the switching valve 18 toward the blow water discharge section 16. 36 (first flow path) and.

The control unit 8 is connected to an operation unit 38 operated by the user H. Further, the control unit 8 is electrically connected to the pump 4, the switching valve 18, the operating unit 38, the air introduction switching valve 58, the pressure sensor 40, etc., and can transmit and receive electrical signals to and from each other. The part can be operated electrically. The control unit 8 is attached to the wall surface W in the bathroom. Further, the operation unit 38 is an operation unit such as an operation panel capable of performing an operation desired by the user H, and is attached to a wall surface W in the bathroom. Information that the user H has operated the operation unit 38 is sent to the control unit 8 by an electric signal. Such a control unit 8 and an operation unit 38 can also be provided on a wall surface or the like outside the bathroom. The control unit 8 includes a storage device (not shown) such as a memory and an arithmetic unit (not shown) that can appropriately control the bathtub device 1.

When the control unit 8 determines that the water level in the bathtub 2 is equal to or lower than the predetermined water level WL2 at which air may be introduced from the bathtub communication port 12, the pump 4 is controlled so as not to operate. The predetermined water level WL2 is, for example, the water level at the height of the upper end of the bathtub communication port 12. When the water level in the bathtub 2 is WL2 or less and a relatively large amount of air is introduced into the bathtub communication part 42 from the bathtub communication port 12 without limitation, the temperature of the hot water discharged from the water discharge part 6 decreases. When it is determined that the water level in the bathtub 2 is WL2 or less, the pump 4 is not operated because it causes the flow of hot water to crack.
Further, when the control unit 8 determines that the water level in the bathtub 2 is the water level equal to or lower than the water level WL3 at the height of the blow water discharge unit 16, high-speed blow water discharge from the blow water discharge unit 16 is performed in water. Therefore, the pump 4 is controlled so as not to operate (see FIG. 8).

In the inlet flow path 24, a pressure sensor 40 for detecting water pressure is provided. The water pressure detected by the pressure sensor 40 is transmitted to the control unit 8, and the control unit 8 can determine the water level (water amount) of the hot water in the bathtub 2 from the water pressure detected by the pressure sensor 40. The pressure sensor 40 is not limited to the inlet flow path 24, and may be attached to other positions such as the communication flow path 26 and the pump upstream side flow path 28 that receive water pressure according to the water level in the bathtub 2. In still another embodiment, the water level (water amount) of the hot water in the bathtub 2 may be measured by the water level sensor instead of the pressure sensor 40. Further, in still another embodiment, the arrangement of the pressure sensor 40 is omitted, and the load of the electric motor of the pump 4 (fluctuation of the amount of current flowing through the electric motor according to the load) is measured to obtain hot water in the bathtub 2. The water level (amount of water) may be measured. The fluctuation of the amount of current flowing through the electric motor is measured by a current sensor or the like, and the measurement information is sent from the current sensor to the control unit 8.

The blow water discharge portion 16 is provided at a height position near the center of the vertical wall 2b of the bathtub 2 in the vertical direction. In the present embodiment, the blow water discharge unit 16 is provided with two blow water discharge units 16 on the vertical wall 2b on the water discharge unit 6 side of the bathtub 2. The number of blow water discharge portions 16 is not limited to two, but may be one, and may be three or more. For example, the two blow water discharge portions 16 are arranged at symmetrical positions shifted to the left and right sides with respect to the bathtub communication port portion 12 in the left-right direction (left-right direction toward the vertical wall 2b) of the bathtub 2.
The blow water discharge portion 16 is formed so that the diameter of the flow path inside the blow water discharge portion 16 is narrower than the diameter of the blow water discharge portion side flow path 36 on the upstream side of the blow water discharge portion 16. The blow water discharge unit 16 is attached to the vertical wall 2b of the bathtub 2 in a horizontal direction (for example, in a horizontal direction close to horizontal), and a high-speed blow water discharge is discharged sideways from the blow water discharge unit 16. The blow water discharge unit 16 is connected to the blow water discharge unit side flow path 36 on the downstream side of the pump 4, and directly ejects the water flow pumped from the pump 4. Therefore, the blow water discharge unit 16 forms a relatively small flow rate and a high speed water discharge flow according to the amount of water sent out by pumping.

The blow water discharge unit 16 is arranged at a height position near the center of the vertical wall 2b of the bathtub 2 in the vertical direction, that is, at a height position corresponding to the waist and back of a general user H, and is a blow water discharge unit. When the blow water spouted from 16 toward the user H collides with the waist and back of the user H, the waist and back of the user H can be pressed and the effect of massage can be achieved. The blow water discharge unit 16 is capable of performing blow water discharge when the control unit 8 determines that the blow water discharge unit 16 is below the water surface of the bathtub 2, and the underwater water discharge unit that discharges water in water is provided. It is configured. In this way, the blow water discharge unit 16 discharges water into the hot water of the bathtub 2 to cause the water flow to act on the user H, so that the relatively cold residual water in the pump 4 or the like during the previous use is discharged from the blow water discharge unit 16. Even in such a case, since the blow water is mixed with the hot water of the bathtub 2 and collides with the user H, there is less possibility that the user H feels the interval of cold water.

The blow water discharge unit 16 also functions as a stirring water discharge unit that discharges hot water having a flow rate higher than the flow rate of the hot water discharged from the water discharge unit 6 to stir the bathtub water stored in the bathtub 2. Since the blow water discharge unit 16 performs high-speed blow water discharge into the water, the hot water in the bathtub can be strongly agitated. The blow water discharge unit 16 is arranged in a region near the vertical wall 2b of the bathtub 2 to which the communication flow path 26 of the bathtub water communication flow path portion 47 is connected. The blow water discharge portion 16 is arranged on the vertical wall 2b on the upper side of the bathtub water communication flow path portion 47 in the vicinity of the bathtub communication port portion 12. In this way, the blow water discharge portion 16 and the bathtub communication port portion 12 communicating with the communication flow path 26 are arranged relatively close to each other along the same vertical wall 2b. Therefore, the effect of stirring the hot water by the water discharged from the blow water discharge unit 16 can be efficiently generated in the vicinity region of the bathtub communication port 12, and the hot water having a relatively high temperature can be supplied to the bathtub water communication flow path portion 47 and the bathtub communication portion. It can be supplied to 42.

The switching valve 18 can selectively open and close both or one of the injection section side flow path 32 and the blow water discharge section side flow path 36. Therefore, the switching valve 18 supplies the hot water supplied from the pump downstream flow path 30 on the downstream side of the pump 4 to both or one of the injection section side flow path 32 and the blow water discharge section side flow path 36. It can be selectively supplied. At the same time, when the injection section side flow path 32 and the blow water discharge section side flow path 36 are open, the switching valve 18 can freely change the flow rate distribution ratio. The switching valve 18 is electrically connected to the control unit 8 and can be electrically opened and closed by receiving the operation of the operation unit 38 of the user H. Therefore, the user H can selectively execute water discharge from the water discharge unit 6 via the jet pump unit 10 and / or one of the water discharge unit 16 from the blow water discharge unit 16.

Next, the jet pump unit 10 will be described with reference to FIGS. 3 to 6, 13 and 14.
FIG. 6 is a diagram for explaining the jet pump operation in the jet pump unit of the bathtub device according to the embodiment of the present invention, and FIG. 13 is a top view showing the installation position of the pump in the bathtub device according to the embodiment of the present invention. , FIG. 14 is a side view showing a pump installation position in a bathtub device according to an embodiment of the present invention.

The jet pump unit 10 passes through a jet pump water storage unit 41 in which hot water drawn by the jet pump action is stored, and a bathtub communication unit 42 arranged on the downstream side of the pump 4 and supplied from the pump 4. A jet nozzle 44 (injection unit) that injects air into the bathtub, an air introduction port 45 that is arranged on the water discharge direction side of the jet nozzle 44 and introduces air into the flow of hot water injected from the jet nozzle 44, and a bathtub communication unit 42. Bathtub water communication flow path section 47 formed between the bathtub water introduction section 46 extending to the downstream side of the bathtub water and the jet pump water storage section 41 and the bathtub 2 and introducing the bathtub water of the bathtub 2 into the jet pump water storage section 41. And have.
Since the jet pump unit 10 can be formed by a relatively simple structure and a relatively small structure even when a large flow rate is to be supplied to the water discharge unit 6, the casing in the bathroom and the bathtub 2 are combined. It can be placed in a small space constrained between them.

In the present embodiment, the jet pump water storage unit 41 is a bathtub communication unit 42 that communicates with the bathtub 2 and allows the hot water of the bathtub 2 to flow in. The jet pump water storage unit 41 may form a storage unit by communicating with a water supply source or a water supply device other than the bathtub 2 and inflowing hot water supplied from the water supply source or the like. That is, the storage unit may be formed so that the jet pump water storage unit 41 is not supplied with hot water from the bathtub 2 and hot water is supplied to the jet pump unit 10 from another external water supply source or the like.

The bathtub communication portion 42 forms a box-shaped water storage chamber and is connected to the downstream end of the communication flow path 26. The bathtub communication portion 42 is arranged in a region near the back side of the bathtub communication port portion 12 formed on the vertical wall 2b of the bathtub 2 and the back side of the vertical wall 2b. The bathtub communication portion 42 is arranged in a relatively narrow area between the vertical wall 2b and the wall surface W. Further, the bathtub communication portion 42 is provided at the end of the communication flow path 26 extending straight to the back side of the bathtub communication port portion 12, and is arranged so that the distance from the bathtub communication port portion 12 to the bathtub communication portion 42 is as short as possible. Has been done. The bathtub communication portion 42 communicates with the bathtub 2 and allows hot water from the bathtub 2 to flow in. Further, a jet nozzle 44 is attached so as to penetrate the bottom surface 42a of the bathtub communication portion 42, and an opening is formed in the upper surface 42b of the bathtub communication portion 42 facing the jet nozzle 44, and the bathtub water introduction portion 46 is formed from this opening. Extends upward. The bathtub communication portion 42 is communicated with a water storage area (a bathing area of the user H) in the bathtub 2 via an inlet flow path 24 and a communication flow path 26 extending from the bathtub communication port portion 12. Therefore, when hot water is stored in the bathtub 2, the hot water also flows into the bathtub communication portion 42 and is stored. In a state where hot water is not ejected from the jet nozzle 44, the hot water can move back and forth between the bathtub communication portion 42 and the water storage area in the bathtub 2. The temperature of the hot water in the bathtub communication portion 42 and the water storage area in the bathtub 2 is almost the same.

The bathtub communication portion 42 and the bathtub water communication flow path portion 47, which will be described later, are arranged at a height position equal to or less than the intermediate height position h1 between the bottom portion 2a and the upper end portion 2c of the bathtub 2. That is, the bathtub communication portion 42 and the bathtub water communication flow path portion 47, which will be described later, are arranged at a height position between the intermediate height position h1 and the bottom portion 2a of the bathtub 2. Therefore, the bather should take a half-body bath so that the bathtub water stored in the bathtub 2 is stored in a water storage amount lower than, for example, the intermediate height position h1 or the intermediate height position h1. Even in such a state of use, the bathtub communication section 42 and the bathtub water communication flow path section 47 are filled with hot water, and the hot water in the bathtub is supplied from the water discharge section 6 to the bather's shoulder or the like by using the jet pump unit 10. Can be spouted.

As shown in FIGS. 3 and 9, the jet pump unit 10 is arranged on the back side (wall surface W side) of the bathtub communication port 12 at the center in the left-right direction on the side where the water discharge portion 6 of the bathtub 2 is arranged. Has been done. The jet pump unit 10 is formed so that the height position of the jet nozzle 44 and the bathtub communication portion 42 is lower than the intermediate height position h1. Further, the jet pump unit 10 is formed so that the bathtub water introduction portion 46 extends from the vicinity of the upper end portion 2c of the bathtub 2 to a position lower than the intermediate height position h1. By configuring the jet pump unit 10 so that the jet nozzle 44 and the bathtub communication portion 42 are intentionally arranged at a low position in this way, even when the amount of hot water stored in the bathtub 2 is small, that is, the water storage level is low. Water can be discharged from the water discharge unit 6.
In this way, the jet pump unit 10 is arranged at the lower center in the left-right direction of the bathtub 2, but as shown in FIG. 13, the pump 4 is located in the left-right direction on the side where the water discharge portion 6 of the bathtub 2 is arranged. It can be placed near the lateral end outside the center. As shown in FIG. 14, the pump 4 is arranged at the lower side of the bathtub 2 and inside the casing 20. In this way, the pump 4 can be arranged on the side side of the bathtub 2, and the hot water flowing into the flow path 28 on the upstream side of the pump from the bathtub communication port 12 is placed in the pump 4 arranged on the side side of the bathtub 2. The hot water that is guided and pumped from the pump 4 flows through the pump downstream side flow path 30 to the jet pump unit 10 arranged in the center or the blow water discharge part side flow path 36 near the center.

In the state where the hot water is stored, the hot water has the property that the relatively hot water easily moves upward, and the relatively cold water easily moves downward. Here, since the bathtub communication portion 42 is arranged at a position higher than the bathtub communication port portion 12, the relatively hot hot water among the hot water moves to the bathtub communication portion 42 at a position higher than the bathtub communication port portion 12. It is easy to make it difficult for the temperature of the hot water in the bathtub communication portion 42 to cool, and it is possible to easily maintain the temperature of the hot water that is relatively warm.

The jet nozzle 44 injects hot water through the bathtub communication portion 42 and toward the bathtub water introduction portion 46 to induce a jet pump action. The jet nozzle 44 is formed so that the diameter of the flow path inside the jet nozzle 44 is narrower than the diameter of the injection portion side flow path 32 on the upstream side of the jet nozzle 44. Therefore, the hot water pumped by the pump 4 is further accelerated in the jet nozzle 44, and is ejected from the jet nozzle 44 as a high-speed flow of hot water. The jet nozzle 44 is directed toward the bathtub communication portion 42 and the bathtub water introduction portion 46. Therefore, the jet nozzle 44 is capable of injecting a high-speed jet having a linear directivity toward the inside of the bathtub communication portion 42 and the bathtub water introduction portion 46. The high-speed jet jet ejected from the outlet opening of the jet nozzle 44 gradually increases its flow rate and gradually decreases its flow velocity by drawing in the hot water in the bathtub communication portion 42.
Since the jet pump unit 10 injects hot water from the jet nozzle 44 having a narrowed flow path diameter and flows it into the bathtub water introduction section 46 through the bathtub communication section 42, a pressure loss of a predetermined size is generated. The magnitude of this pressure loss can be made relatively close to the magnitude of the pressure loss when hot water is discharged from the blow water discharge unit 16, and the resistance of the flow path passing through the jet pump unit 10 and the blow water discharge unit 16 By making the resistance of the flow path leading to the above relatively close, it is possible to adjust the flow rate and the flow velocity while allowing hot water to flow to both flow paths at the same time.

As shown in FIG. 5, the air inlet portion 45 is arranged on the front side (downstream side of the jet nozzle 44) of the jet nozzle 44 in the water discharge direction. The air introduction port 45 is arranged in the vicinity of the downstream side of the jet nozzle 44, and is formed so that air is drawn into the bathtub water injected by the jet pump action of the bathtub water jetted from the jet nozzle 44. The air introduction port 45 is attached so as to penetrate from the outside of the bathtub communication section 42 to the inside of the bathtub communication section 42, and forms an air introduction port 45 extending into the bathtub communication section 42. The air introduction port 45 forms a circular tubular internal flow path, and air is introduced into the internal flow path.

The air introduction port 45 is an inlet portion 46a of the bathtub water introduction portion 46 extending from the jet nozzle 44 and the bathtub communication portion 42 toward the water discharge portion 6 in the injection direction of the jet nozzle 44 (vertical direction in the present embodiment). It is placed between and. More specifically, the air inlet portion 45 is arranged closer to the jet nozzle 44 side than the midpoint between the tip 44a forming the outlet opening of the jet nozzle 44 and the inlet portion 46a. .. In other words, the air introduction port 45 is arranged so that the distance between the air introduction port 45 and the tip 44a of the jet nozzle 44 is shorter than the distance between the air introduction port 45 and the inlet 46a. Has been done. As described above, the air inlet portion 45 is located upstream of the inlet portion 46a of the bathtub water introduction portion 46 in the injection direction of the jet nozzle 44, and the jet nozzle 44 having a high flow velocity of the bathtub water injected from the jet nozzle 44. It is arranged in the region near the tip 44a of the.

The air introduction port 45 may be arranged closer to the inlet 46a than the midpoint between the tip 44a of the jet nozzle 44 and the inlet 46a. In this case, the flow rate of the jet flow ejected from the jet nozzle 44 is increased by drawing in the hot water in the bathtub communication portion 42, but the flow velocity decreases as the flow rate increases, so that air The amount of air introduced into the hot water from the introduction port 45 can be suppressed to a relatively low amount.

The air introduction port 45 extends from the side of the jet nozzle 44 to the vicinity of the front surface of the jet nozzle 44 in the lateral direction (left-right direction in the present embodiment) with respect to the injection direction of the jet nozzle 44. More specifically, the air inlet portion 45 extends laterally from the side surface 42c with respect to the bottom surface 42a of the bathtub communication portion 42 provided with the jet nozzle 44, and the extension region C of the outlet opening of the jet nozzle 44. It is formed so as to extend to the vicinity. The extension area C is defined as a virtual area when the outlet opening of the jet nozzle 44 is linearly extended toward the downstream side. The air inlet portion 45 extends from the side surface 42c to the vicinity of the front surface of the jet nozzle 44 in the injection direction. The air inlet portion 45 extends between the side surface 42c and the central axis of the jet nozzle 44 in the bathtub communication portion 42. Therefore, the air introduction port 45 extends from the side surface 42c to the front front of the jet nozzle 44 so as to be orthogonal to the jet nozzle 44. In this way, the air inlet portion 45 extends in the lateral direction with respect to the injection direction of the jet nozzle 44 to a region inside the side surface 42c and near the front surface in the injection direction where the flow velocity of the bathtub water injected from the jet nozzle 44 is high. ing.

The tip opening 45a at the tip of the air introduction port 45 is arranged at a position slightly closer to the side surface 42c than the front of the tip of the jet nozzle 44. The tip opening 45a is formed as an oblique opening such that the opening on the downstream side (bathtub water introduction portion 46 side) is larger than the opening on the upstream side (jet nozzle 44 side). Due to the high-speed flow of hot water from the jet nozzle 44 as shown by the arrow F4, negative pressure is generated by the action of the jet pump, and air is drawn (sucked) from the tip opening 45a of the air introduction port 45 and is contained in the hot water. Fine (fine) air bubbles are mixed in.

An air introduction pipe 56 is connected to the air introduction port 45, and an air introduction switching valve 58 capable of opening and closing the air introduction path is provided on the air introduction pipe 56. At the other end of the air introduction pipe 56, an air opening (not shown) for taking in air from the bathroom is formed. In the present embodiment, since the air is sucked into the hot water by the negative pressure due to the jet pump action, the device such as the air pump for sending the air to the air introduction pipe 56 can be omitted. The control unit 8 electrically controls the opening and closing of the air introduction switching valve 58. That is, the execution and stop (on / off) of the air supply can be switched by opening and closing the air introduction switching valve 58. When the user H supplies air, the water is discharged from the water discharge unit 6 provided near the upper end of the bathtub 2, for example, by mixing air into the water discharged from the shoulder bath, so that the water discharge hits the bather. It is possible to soften the spouting stimulus (feeling of hitting spouting water). Further, when the user H stops or stops the air supply, the air is not mixed in, and the water discharge stimulus (feeling of the water discharge) when the water discharge hits the bather can be strengthened. In this way, the amount of minute air bubbles introduced into the hot water from the air introduction port 45 is controlled by the control unit 8. It is also possible to omit the air introduction switching valve 58 so that air can be introduced naturally. Further, according to the pulsation mode of the control unit 8, the air introduction switching valve 58 is automatically turned on / off periodically or alternately according to other conditions, and the amount of air mixed in the water discharged from the water discharge unit 6 is automatically adjusted. The stimulus given to the user H by the spouting water can be changed according to a predetermined condition. For example, such a pulsation mode can enhance the water discharge stimulation effect and the massage effect of the shoulder bath. The air introduction system such as the air introduction port 45 and the air introduction switching valve 58 may be omitted so that the bathtub device 1 is not mixed with fine air.

The bathtub water introduction unit 46 forms at least a part of the bathtub water introduction flow path 34. The bathtub water introduction portion 46 extending from the bathtub communication portion 42 toward the water discharge portion 6 forms a flow path extending linearly on an extension line in the direction of the opening of the jet nozzle 44. The bathtub water introduction portion 46 forms a circular tubular flow path that extends linearly upward from the upper surface of the bathtub communication portion 42. The flow path diameter of the bathtub water introduction portion 46 is formed to be larger than the flow path diameter of the jet nozzle 44. Therefore, the flow path cross-sectional area of the bathtub water introduction portion 46 is also formed to be larger than the flow path cross-sectional area of the jet nozzle 44. Therefore, the bathtub water introduction unit 46 is formed in a size capable of introducing a flow rate of hot water that is larger than the flow rate of the hot water jetted from the jet nozzle 44. The jet nozzle 44, the bathtub communication portion 42, and the bathtub water introduction portion 46 form a linear flow path extending in one direction, and form a high-speed flow along the direction of the high-speed jet jet ejected from the jet nozzle 44. can do.

The bathtub water introduction flow path 34 forms a development portion 48 that spreads in the left-right direction at the upper portion thereof, and the hot water that spreads in the left-right direction in the development portion 48 is discharged from the water discharge portion 6 in the lateral direction (for example, in a lateral direction close to horizontal). ) Can be spouted. The unfolding portion 48 forms a flow path in which the cross-sectional area of the flow path gradually increases above. The downstream side of the bathtub water introduction flow path 34 is connected to the water discharge portion 6.

Next, the bathtub water communication flow path portion 47, the pump upstream side flow path 28, the opening degree adjusting mechanism 54, and the like will be described with reference to FIGS. 10 to 12.
FIG. 10 is a cross-sectional view of the bathtub as viewed along the line III-III of FIG. 2, and FIG. 11 shows the opening degree adjusting mechanism of the jet pump unit of the bathtub device according to the embodiment of the present invention of the communication flow path inlet portion. FIG. 12 is a schematic cross-sectional view showing a state in which an opening degree adjusting mechanism is provided in the vicinity and is adjusted to an open state in which the communication flow path inlet portion is opened. FIG. 12 is a view of a jet pump unit of a bathtub device according to an embodiment of the present invention. Schematic cross-sectional view showing a state in which an opening degree adjusting mechanism is provided so as to cover a part of the communication flow path inlet portion and the opening degree adjusting mechanism is adjusted to a closed state so as to cover a part of the communication flow path inlet portion. Is.

The bathtub water communication flow path portion 47 includes a communication flow path 26 between the bathtub communication section 42 and the bathtub 2, and a communication flow path inlet portion 50 forming the inlet portion on the bathtub 2 side. Since the bathtub water communication flow path portion 47 is provided, the bathtub water of the bathtub 2 can be used in the bathtub without separately providing a dedicated water supply source or the like for supplying hot water to the jet pump water storage portion 41 of the jet pump unit 10. It can be introduced from the water communication flow path portion 47 to the jet pump water storage portion 41, and the entire structure of the bathtub device 1 can be simplified and formed. Further, since the jet pump water storage unit 41 of the jet pump unit 10 is not separately provided with a dedicated water supply source or the like for supplying hot water from the outside of the bathtub 2, water is discharged from the blow water discharge unit 16 by the jet pump unit 10. Even when a flow rate larger than the flow rate of the bathtub water is discharged from the water discharge unit 6 into the bathtub 2, it is possible to prevent the water level in the bathtub 2, that is, the amount of water from increasing by receiving additional water supply from the outside. it can.

The communication flow path inlet portion 50 is formed so as to connect to the inlet flow path 24 and is opened in the inlet flow path 24. The communication flow path inlet portion 50 is formed so as to open toward the inner area A (bathing area of the bather) of the inlet flow path 24 and the bathtub 2. As shown in FIG. 10, when the inside of the inlet flow path 24 (the back side of the inlet flow path 24) is viewed from the internal region A of the bathtub 2, the communication flow path inlet portion 50 is on the back side of the bathtub communication port portion 12. Moreover, a circular opening is formed in the upper part of the vertical wall 24a in the inlet flow path in the inlet flow path 24. The cross-sectional area of the flow path of the communication flow path inlet portion 50 is formed to be larger than the cross-sectional area of the flow path of the bathtub water introduction portion 46.

Here, the communication flow path inlet portion 50 is formed independently of the pump flow path inlet portion 52 of the pump upstream side flow path 28 that sucks the bathtub water in the bathtub 2 into the pump 4. The pump flow path inlet portion 52 forms a circular opening behind the bathtub communication port portion 12 and below the inlet flow path inner vertical wall 24a in the inlet flow path 24. The communication flow path inlet portion 50 forms a circular opening having a radius larger than that of the pump flow path inlet portion 52. Therefore, the flow path cross-sectional area of the communication flow path inlet portion 50 is formed to be larger than the flow path cross-sectional area of the pump flow path inlet portion 52. In the vertical wall 24a in the inlet flow path, the communication flow path inlet portion 50 and the pump flow path inlet portion 52 are separated from each other by a predetermined distance by the vertical wall 24a in the inlet flow path, and the communication flow path inlet portion 50 and the pump flow are separated from each other. The road entrance portion 52 and the road entrance portion 52 are arranged separately and independently. The pump flow path inlet portion 52 is formed so as to be connected to the inlet flow path 24, and is opened in the inlet flow path 24. The pump flow path inlet portion 52 is formed so as to open toward the inner region A (bath area of the bather) of the inlet flow path 24 and the bathtub 2. Since the communication flow path inlet portion 50 and the pump flow path inlet portion 52 are opened in parallel in the same direction, the flow of hot water toward the respective introduction ports is parallel to the respective introduction ports. It is possible to prevent the inflowing flows from interfering with each other or affecting each other.

As shown in FIG. 10, the inlet flow path 24 has a flow path cross-sectional area larger than the sum (total) of the flow path cross-sectional area of the communication flow path inlet portion 50 and the flow path cross-sectional area of the pump flow path inlet portion 52. It is formed to have. The inlet flow path 24 has a flow path cross-sectional area larger than the total (total) of the flow path cross-sectional area of the communication flow path inlet portion 50 and the flow path cross-sectional area of the pump flow path inlet portion 52. When the hot water that has flowed into the inlet flow path 24 from the portion 12 goes toward the communication flow path inlet portion 50 and the pump flow path inlet portion 52, respectively, it will flow in parallel toward the respective introduction ports. It is possible to prevent the flows from interfering with each other, and prevent the hot water flowing from the communication flow path inlet 50 toward the bath communication channel 42 from being affected by the suction of the pump 4 toward the pump flow path inlet 52 side. It is possible to stably supply the expected amount of hot water to the jet pump unit 10.

As shown in FIG. 10, the inlet flow path 24 has a communication flow path inlet portion 50 and a pump flow path inlet portion 52 formed therein, and a bathtub communication port portion 12 is formed as a single opening on the bathtub 2 side. doing. Therefore, when the bather sees from the bathtub 2 side, only a single bathtub communication port 12 can be seen. In this way, without directly forming the two openings of the communication flow path inlet portion 50 and the pump flow path inlet portion 52 on the vertical wall 2b of the bathtub 2, only one bathtub communication port portion 12, that is, the inlet flow path 24 Therefore, it is possible to reduce the processing work for connecting the inlet flow path 24 to the bathtub 2, and further reduce the sealing portion between the bathtub 2 and the inlet flow path 24 to reduce the seal. The manufacturing work and the seal management work can be reduced, and the risk of water leakage can also be reduced.

As shown in FIGS. 11 and 12, the jet pump unit 10 further includes an opening degree adjusting mechanism 54 capable of adjusting the opening area of the communication flow path inlet portion 50 of the bathtub water communication flow path portion 47. .. The opening degree adjusting mechanism 54 is provided in the vicinity of the communication flow path inlet portion 50. The opening degree adjusting mechanism 54 includes a shutter mechanism capable of adjusting the opening area of the communication flow path inlet portion 50. The opening degree adjusting mechanism 54 is formed so that the user of the bathtub device 1 can manually adjust the opening area of the flow path of the communication flow path inlet portion 50 from inside the bathtub 2. More specifically, the position of the opening degree adjusting mechanism 54 can be manually changed from the bathtub communication port 12 side by a simple operation of the user H's fingers or the like. The opening area of the communication flow path inlet portion 50 may be adjusted by an electric mechanism.

As shown in FIG. 11, when the opening degree adjusting mechanism 54 is adjusted to open the communication flow path inlet portion 50, the communication flow path inlet portion 50 passes through the communication flow path inlet portion 50 from the inlet flow path 24. A flow of hot water F21 flowing toward the bathtub communication portion 42 and a flow F22 of hot water flowing from the inlet flow path 24 through the pump flow path inlet portion 52 to the pump 4 are formed. Since the opening degree adjusting mechanism 54 is in an open state in which the communication flow path inlet portion 50 is not narrowed, the flow rate and / or the flow velocity flow F21 according to the diameter of the communication flow path inlet portion 50 is directed toward the bathtub communication portion 42. It will be formed.

As shown in FIG. 12, when the opening degree adjusting mechanism 54 is positioned in a closed state so as to cover all or part of the communication flow path inlet portion 50, hot water flowing into the communication flow path inlet portion 50. Since the flow rate and / or the flow velocity of the water is limited, the flow rate of the hot water supplied to the bathtub communication portion 42 is limited, and the flow rate, speed, and water force of the hot water discharged from the water discharge unit 6 are limited without controlling the pump 4. Etc. can be easily adjusted. At this time, the flow F23 of hot water flowing from the inlet flow path 24 through the communication flow path inlet portion 50 toward the bathtub communication portion 42 and the flow of hot water from the inlet flow path 24 through the pump flow path inlet portion 52 to the pump 4 A flow of hot water F24 is formed. Here, since the opening degree adjusting mechanism 54 is in a closed state in which the communication flow path inlet portion 50 is narrowed, the flow rate and / or the flow velocity of the hot water flowing into the communication flow path inlet portion 50 is limited, and the flow rate of the F23. And / or the flow velocity is smaller than the flow rate and / or the flow velocity of F21. On the other hand, the flow rates and flow velocities of the flows F23 and F24 are substantially constant because they depend on the performance of the pump 4.
In the present embodiment, the opening degree adjusting mechanism 54 can adjust the open state and the closed state of the communication flow path inlet portion 50 in two stages, but the opening degree adjusting mechanism 54 can adjust the communication flow path. The opening degree (opening / closing ratio of the opening) of the inlet portion 50 may be adjusted according to a plurality of stages such as three stages and five stages.

According to the opening degree adjusting mechanism 54 of the present embodiment, the flow velocity of the bathtub water discharged from the blow water discharge unit 16 is larger than the flow velocity of the bathtub water discharged from the water discharge unit 6 for the bathtub water supplied from the common pump 4. The blow water discharge unit 16 and the water discharge unit 6 can simultaneously discharge water so that the flow rate of the bathtub water discharged from the water discharge unit 6 is higher than the flow rate of the bathtub water discharged from the blow water discharge unit 16. In the bathtub device 1, the hot water discharged from the water discharge unit 6 is not set and / or the pump 4 itself is changed so as to change the flow velocity and the flow rate of the hot water discharged from the blow water discharge unit 16. The flow velocity and flow rate can be changed or adjusted (finely adjusted) relatively easily with a relatively simple configuration.

Next, with reference to FIGS. 3 to 7, the water discharge operation from only the water discharge unit 6 by the bathtub device 1 according to the present embodiment will be described.
FIG. 7 is a perspective view showing a state in which a water discharge operation is performed only from the water discharge portion while the user is sitting in the bathtub of the bathtub device according to the embodiment of the present invention.
Before the water discharge operation from the water discharge unit 6 by the bathtub device 1 is started, hot water having a temperature at which the user H can take a bath is supplied and stored in the bathtub 2 up to, for example, the water supply water level WL0. At this time, since the bathtub 2 and the bathtub communication section 42 are communicated with each other via the inlet flow path 24 and the communication flow path 26, hot water having substantially the same temperature as the bathtub 2 is also stored in the bathtub communication section 42. It has become.

When attempting to start the water discharge operation from the water discharge unit 6 by the bathtub device 1, the user H operates the operation unit 38 to select water discharge from the water discharge unit 6. Information that the user H operates the operation unit 38 is transmitted to the control unit 8. At this time, the control unit 8 determines the height of the hot water in the bathtub 2 based on the value of the water pressure detected by the pressure sensor 40.
When the control unit 8 determines that the water level in the bathtub 2 is equal to or lower than the predetermined water level WL2 at which air may be introduced from the bathtub communication port 12, the pump 4 is controlled so as not to operate. The predetermined water level is, for example, the water level WL2 at the height of the upper end of the bathtub communication port 12. Therefore, when the control unit 8 determines that the water level in the bathtub 2 is higher than the predetermined water level (for example, WL2) at which air may be introduced from the bathtub communication port 12, the pump 4 is operated. Control to let.

When the control unit 8 operates the pump 4, the pump 4 sucks the hot water in the bathtub 2 from the bathtub communication port 12 via the inlet flow path 24 and the pump upstream side flow path 28 as shown by the arrow F1. To do. Then, as shown by the arrow F2, the pump 4 pumps the sucked hot water to the downstream flow path 30 of the pump on the downstream side. The control unit 8 controls the switching valve 18 so as to selectively open and close either or both of the injection unit side flow path 32 and the blow water discharge unit side flow path 36. For example, when the water discharge operation from the blow water discharge unit 16 is not performed and the water discharge operation is performed from the water discharge unit 6, the flow path from the pump downstream side flow path 30 to the blow water discharge unit 16 side flow path by the switching valve 18 The communication is closed, and the communication from the pump downstream flow path 30 to the injection portion side flow path 32 is open. At this time, hot water is supplied from the pump downstream side flow path 30 to the injection portion side flow path 32 as shown by the arrow F3. As shown by the arrow F4, the hot water passing through the injection section side flow path 32 is jetted from the jet nozzle 44 toward the inside of the bathtub communication section 42 and the bathtub water introduction section 46 at high speed and linearly. At this time, the hot water jetted from the jet nozzle 44 in the bathtub communication section 42 flows into the bathtub water introduction section 46 while drawing the hot water in the bathtub communication section 42 by the jet pump action.

The control unit 8 is provided with a water discharge unit water discharge mode in which the bathtub water supplied from the pump 4 is discharged from only the water discharge unit 6, which will be described later. The control unit 8 has a blow water discharge mode in which the bathtub water supplied from the pump 4 is discharged from only the blow water discharge unit 16 described later.
The control unit 8 has the bathtub water supplied from the pump 4, and the flow velocity of the bathtub water discharged from the first water discharge unit is higher than the flow velocity of the bathtub water discharged from the second water discharge unit, and the second water discharge unit. Water discharge is performed simultaneously (at the same time) from the water discharge unit 6 and the blow water discharge unit 16 described later so that the flow rate of the bathtub water discharged from the unit is larger than the flow rate of the bathtub water discharged from the first water discharge unit. It has a simultaneous water discharge mode to execute the operation. Further, the control unit 8 may include a pulsation mode in which the air introduction switching valve 58 is automatically turned on / off periodically or alternately according to other conditions. As a result, the amount of air mixed in the water discharged from the water discharge unit 6 can be changed, and the stimulation given to the user H by the water discharge can be changed, so that the water discharge stimulation effect of the shoulder bath can be further strengthened. .. Further, the control unit 8 is provided with a stirring water discharge mode for executing a water discharge operation in which water discharge from the water discharge unit 6 and water discharge from the blow water discharge unit 16 (stirring water discharge unit) are performed at the same time (at the same time). According to the stirring water discharge mode, the hot water in the bathtub 2 can be agitated by spouting water from the blow water discharge unit 16 into the water discharge from the water discharge unit 6 so that the hot water having a relatively low temperature is not discharged from the water discharge unit 6. it can.

Next, as shown in FIGS. 5 and 6, the state in which the hot water injected from the jet nozzle 44 flows to the bathtub water introduction section 46 while drawing the hot water in the bathtub communication section 42 by the jet pump action will be described in more detail. ..
As shown in FIGS. 5 and 6, the hot water jetted from the jet nozzle 44 at high speed forms a jet flow (jet flow) as shown by arrow F4, and is fast and powerful in the direction of the opening of the jet nozzle 44. Form a flow with propulsion. At this time, the flow of the jetted hot water causes a jet pump action, that is, an action of drawing in the surrounding hot water by the ejector effect. In the present embodiment, the hot water in the bathtub communication portion 42 is drawn in (according to other expressions) with respect to the linear jet as shown by the arrow F4, as shown by the arrows F5 and F6. .. At this time, the flow rate q2 of the hot water drawn from the bathtub communication portion 42 is added to the flow rate q1 of the hot water injected from the jet nozzle 44, and the flow rate q3 of the hot water in the bathtub water introduction portion 46 having a larger flow rate is obtained ( See arrow F4'). Such a flow rate relationship can be expressed by the equation q1 + q2 = q3. As described above, the jet pump unit 10 can realize a technique of entraining hot water in the bathtub communication portion 42 on the downstream side of the jet nozzle 44 to amplify the discharge water flow rate by using the jet pump action.

Since the hot water jetted from the jet nozzle 44 draws the hot water flowing in from the bathtub 2 in the bathtub communication portion 42, the hot water sprayed from the jet nozzle 44 is filled with low-temperature hot water (residual water from the previous use, etc.). Even when they are mixed, the hot water in the bathtub communication section 42 is drawn in and supplied to the spouting section 6, so that the hot water at a temperature relatively close to the temperature of the hot water in the bathtub 2 can be spouted from the spouting section 6. .. Therefore, it is possible to more reliably suppress the user H from feeling cold, and the water discharged from the water discharge unit 6 can be used immediately after the start of use of the pump 4, improving the startability of the bathtub device 1. Can be made to.
Further, the flow rate q2 of the hot water drawn from the bathtub communication portion 42 is set to be larger than the flow rate q1 of the hot water injected from the jet nozzle 44. In this way, since there is a flow rate relationship of q2> q1, the hot water jetted from the jet nozzle 44 has a low temperature hot water (low temperature residual water at the time of the previous use or after the hot water is supplied to the bath 2). Even when low-temperature hot water, etc., when the temperature of hot water in the flow path of the pump 4 or the like drops with the passage of time), the jetted hot water is more than the flow rate q1 of the hot water jetted from the jet nozzle 44. Since the hot water in the tub communication section 42 having a large flow rate q2 is drawn and supplied to the water discharge section 6, the temperature of the hot water in the hot water drawn from the tub communication section 42 in the hot water of the tub water introduction section 46 is relatively close. The proportion of warm water is dominant. Therefore, it is possible to more reliably suppress the user H from feeling cold, and the water discharged from the water discharge unit 6 can be used immediately after the start of use of the pump, improving the startability of the bathtub device 1. be able to.

The flow rate q3 of the hot water in the bathtub water introduction unit 46 is set to, for example, a flow rate range of 2 to 4 times the flow rate q1 of the hot water jetted from the jet nozzle 44. Further, for example, the flow rate q3 of the hot water in the bathtub water introduction unit 46 is set in the range of the flow rate of 30 l / min to 80 l / min. The flow rate q2 of the hot water drawn from the bathtub communication portion 42 is set to, for example, a flow rate range of 1 to 3 times the flow rate q1 of the hot water injected from the jet nozzle 44.

As described above, the hot water sprayed from the jet nozzle 44 draws the hot water in the bathtub communication section 42 and flows into the bathtub water introduction section 46. The hot water in the bathtub water introduction unit 46 flows upward while maintaining the water force and flow velocity of the hot water jetted from the jet nozzle 44, and reaches the development unit 48. The flow of hot water becomes a flow spread in the left-right direction at the developing portion 48, and reaches the spouting portion 6. As shown by the arrow F7, the hot water is discharged like a waterfall from the spout 22 formed long in the left-right direction toward the front side (inside the bathtub). In this way, the hot water is discharged as a strip-shaped flow having a width of about the shoulder width, and is relatively evenly applied to the neck and shoulders of the user H. The hot water discharged from the water discharge unit 6 forms a stable flow of flowing water having a substantially constant width and thickness. The hot water discharged from the water discharge unit 6 can flow so as to spread relatively evenly over a wide range such as the neck, shoulders, chest and back of the user H. For example, the body of the user H in a half-body bath state becomes cold. It can be warmed so that it does not exist.

Further, since the hot water discharged from the water discharge unit 6 is supplied via the jet pump unit 10, the flow rate is set to be larger than the pumpable flow rate due to the size of the pump 4. That is, it is possible to discharge a large flow rate from the water discharge unit 6 having a size of, for example, 2 to 4 times the pumpable flow rate of the pump 4 without increasing the size of the pump 4. It is very difficult to increase the size of the pump in order to realize a large flow rate of water due to space restrictions regarding the installation position and size (size) of the pump. Further, if the size of the pump is increased in order to realize a large flow rate of water, the vibration and operating noise of the pump become large, which may cause discomfort to the user H.
On the other hand, in the present embodiment, a large flow rate of water can be discharged by using the jet pump unit 10 in an environment where the size of the pump cannot be easily increased. Since a large flow rate of water can be discharged from the water discharge unit 6, the body of the user H becomes cold even when the amount of hot water stored in the bathtub 2 (the amount of hot water in which the user H is immersed) is relatively small. It can be warmed more efficiently so that it does not exist. Further, since the amount of hot water stored in the bathtub 2 (the amount of hot water in which the user H is immersed) can be relatively small, a water saving effect can be realized. Since a large flow rate of water can be discharged from the water discharge unit 6, the body warming effect and the massage effect of the user H can be increased, and the relaxing effect and the relaxing effect of the user H can be increased.

Next, as shown in FIG. 8, the water discharge operation from only the blow water discharge unit 16 by the bathtub device 1 according to the present embodiment will be described.
FIG. 8 schematically shows the internal structure of the bathtub device as viewed along the lines III-III of FIG. 2 with the user sitting in the bathtub of the bathtub device according to the embodiment of the present invention, and blows water discharge. It is schematic cross-sectional view explaining how the water discharge operation is performed only from a part.

When attempting to start the water discharge operation from only the blow water discharge unit 16 by the bathtub device 1, the user H operates the operation unit 38 to select water discharge from the blow water discharge unit 16. Information that the user H operates the operation unit 38 is transmitted to the control unit 8. At this time, the control unit 8 determines the height of the hot water in the bathtub 2 based on the value of the water pressure detected by the pressure sensor 40. When the control unit 8 determines that the water level in the bathtub 2 is the water level equal to or lower than the water level WL3 at the height of the blow water discharge unit 16, the control unit 8 controls the pump 4 so as not to operate. Therefore, when the control unit 8 determines that the water level in the bathtub 2 is higher than the height of the blow water discharge unit 16, the control unit 8 controls to operate the pump 4.

When the control unit 8 operates the pump 4, the pump 4 pumps the sucked hot water as shown by the arrow F8 to the downstream flow path 30 of the pump as shown by the arrow F9. The control unit 8 performs a water discharge operation from the blow water discharge unit 16 and does not perform a water discharge operation from the water discharge unit 6, so that the flow path from the pump downstream side flow path 30 to the blow water discharge unit side flow path 36 The switching valve 18 is controlled so that the communication is in the open state and the communication of the flow path from the pump downstream side flow path 30 to the injection portion side flow path 32 is in the closed state. At this time, hot water is supplied from the pump downstream side flow path 30 to the blow water discharge portion side flow path 36 as shown by the arrow F10. The hot water that has flowed into the blow water discharge unit side flow path 36 is ejected from the blow water discharge unit 16 toward the inside of the bathtub as shown by an arrow F11. The hot water discharged from the blow water discharge unit 16 is hot water pumped by the pump 4, and forms a relatively small flow rate and a high-speed water discharge flow. The hot water discharged from the blow water discharge unit 16 collides with the waist and back of the user H, so that the collided portion can be massaged. During this time, since the switching valve 18 closes the communication of the flow path from the pump downstream side flow path 30 to the injection part side flow path 32, the water discharge operation from the water discharge part 6 is not performed.

Next, as shown in FIG. 9, in the bathtub device 1 according to the present embodiment, the water discharge operation performed simultaneously (at the same time) from the water discharge unit 6 and the blow water discharge unit 16 will be described.
FIG. 9 schematically shows the internal structure of the bathtub device as viewed along the lines III-III of FIG. 2 with the user sitting in the bathtub of the bathtub device according to the embodiment of the present invention. It is a schematic cross-sectional view explaining how the water discharge operation performed simultaneously from the blow water discharge part is performed.

Regarding the water discharge operation performed simultaneously from the water discharge unit 6 and the blow water discharge unit 16 by the bathtub device 1 according to the present embodiment, the water discharge operation from only the water discharge unit 6 by the bathtub device 1 and the blow water discharge unit 16 according to the embodiment The explanation about the water discharge operation common to the water discharge operation of the above will be omitted, and the different parts will be mainly described.
The water discharge operation performed from the water discharge unit 6 and the blow water discharge unit 16 at the same time (at the same time) is a water discharge operation performed from the water discharge unit 6 and a water discharge operation performed from the blow water discharge unit 16 at a certain time. It refers to the water discharge operation when there is. Therefore, not only when the water discharge operation performed from the water discharge unit 6 and the water discharge operation performed from the blow water discharge unit 16 are started at the same time, but also the water discharge operation performed from the water discharge unit 6 and the blow water discharge unit 16 are performed. This includes the case where the water discharge operations are started at different times and both water discharge operations are performed in parallel.

When attempting to start the water discharge operation simultaneously performed from the water discharge unit 6 and the blow water discharge unit 16 by the bathtub device 1, the user H operates the operation unit 38 to discharge water from the water discharge unit 6 and blow water from the blow water discharge unit 16. Select both spouts.
As described above, the control unit 8 determines that the water level in the bathtub 2 is higher than the predetermined water level WL2 at which air may be introduced from the bathtub communication port 12, and the water level in the bathtub 2 is blown out. When it is determined that the water level is higher than the water level WL3 at the height of the unit 16, the pump 4 is controlled to operate.

When the control unit 8 operates the pump 4, the pump 4 sucks the hot water in the bathtub 2 from the bathtub communication port 12 via the inlet flow path 24 and the pump upstream side flow path 28, as shown by the arrow F12. To do. Then, as shown by the arrow F13, the pump 4 pumps the sucked hot water to the downstream flow path 30 of the pump on the downstream side. The control unit 8 controls the switching valve 18 so that both the injection unit side flow path 32 and the blow water discharge unit side flow path 36 are in the open state. Therefore, as shown by arrows F14 and F15, hot water is supplied from the pump downstream side flow path 30 to both the injection part side flow path 32 and the blow water discharge part side flow path 36.

As shown by the arrow F14, the hot water passing through the injection section side flow path 32 is a high-speed and straight line from the jet nozzle 44 toward the inside of the bathtub communication section 42 and the bathtub water introduction section 46, as shown by the arrow F16. Is jetted. At this time, the hot water injected from the jet nozzle 44 in the bathtub communication portion 42 flows to the bathtub water introduction portion 46 while drawing the hot water in the bathtub communication portion 42 by the jet pump action, as shown by the arrow F17. The flow rate q3 of the hot water supplied from the bathtub water introduction unit 46 to the water discharge unit 6 is amplified with respect to the flow rate q1 of the hot water injected from the jet nozzle 44 (see arrow F16'). As shown by the arrow F18, the hot water is discharged like a waterfall from the spout 22 formed long in the left-right direction toward the front side (inside the bathtub).
Even when low-temperature hot water (residual water from the previous use, etc.) is mixed with the hot water ejected from the jet nozzle 44, the hot water in the bathtub communication section 42 is drawn in and supplied to the water discharge section 6, so that the bathtub 2 Hot water having a temperature relatively close to the temperature of the hot water inside can be discharged from the water discharge unit 6. Further, by using the jet pump unit 10, a large flow rate of water can be discharged from the water discharge unit 6.

Next, it will be described that the air is mixed into the hot water injected by the air inlet portion 45 in the present embodiment.
In FIGS. 3 and 5, as shown by the arrow F4, hot water is jetted from the jet nozzle 44 toward the inside of the bathtub communication portion 42 and the bathtub water introduction portion 46 at high speed and linearly. At this time, the hot water injected from the jet nozzle 44 in the bathtub communication portion 42 flows to the bathtub water introduction portion 46 while drawing in the air in the air introduction port portion 45 by the jet pump action. At this time, since the air introduction port 45 is arranged near the downstream side of the injection portion, the hot water injected from the jet nozzle 44 draws air into the hot water immediately after the injection. The flow rate of the flow of hot water injected from the jet nozzle 44 is relatively small. At this time, since the flow rate of the flow of hot water injected from the jet nozzle 44 is relatively small immediately after the injection (the flow rate is almost the same as the flow rate of the hot water injected from the jet nozzle 44), the hot water to be injected The amount of air introduced according to the flow rate can be suppressed to a relatively small amount. As the hot water injected from the jet nozzle 44 passes through the bathtub communication section 42 and the bathtub water introduction section 46 on the downstream side of the air introduction port 45, the flow rate of the hot water while drawing in the hot water in the bathtub communication section 42 by the jet pump action. Is increased. In this way, since the flow rate is amplified mainly on the downstream side of the air introduction port 45, an increase in the flow rate of the flow passing near the air introduction port 45 is suppressed, and the air introduction port 45 enters the hot water. It is possible to prevent the flow rate of the drawn air from being excessively increased.

Further, since the flow rate of the hot water injected from the jet nozzle 44 is increased while drawing the hot water in the bathtub communication portion 42 by the jet pump action, a relatively large flow rate of water is discharged while suppressing the increase in the amount of air mixed. It can be performed. Therefore, even when air is introduced into the flow of bathtub water that discharges a relatively large flow rate from the water discharge portion by the ejector action, the amount of air introduced can be suppressed to be relatively small, and the amount of air introduced can be reduced. It is possible to suppress the increase in the amount of water discharged from the water discharge portion from becoming fragile, and it is possible to form a relatively uniform and stable water discharge state. More specifically, when water is discharged from a horizontally long water discharge port 22 as a wide and thin film flow having a predetermined width, the water discharge contains bubbles having a relatively large size. , The water flow is turbulent so that it is divided into multiple water flows, the water flow is biased so that a part is interrupted, or a space appears so that the water flow is turbulent in a part of a uniform wide thin film-like flow. It is possible to suppress cracking and turbulence of the water flow, and to form a uniform wide thin film-like smooth flow even when air is mixed in the discharged water.
According to such a flow, not only a relaxing effect and a massage effect are given when the flow mixed with air hits the user, but also a water discharge stimulus (given to the user) when the flow mixed with fine bubbles hits the user. Disturbance of sensation) is suppressed, and water splashing is also suppressed, so that an effective relaxing effect can be given when the user uses it as a shoulder bath.

Further, since the air inlet portion 45 is arranged in the vicinity of the downstream side of the jet nozzle 44 and / or in the front region near the front surface in the injection direction, the comparison immediately after the hot water injected from the jet nozzle 44 is injected. Air is drawn into hot water in a region where the target flow velocity is high. Therefore, the air is drawn from the air introduction port 45 by the relatively high flow velocity of the hot water, so that the air is suppressed from being introduced as relatively large bubbles, and the air is divided and introduced as fine bubbles. be able to. In this way, by mixing fine-sized bubbles in the hot water, it is possible to prevent the mixing of relatively large-sized bubbles that make the water discharged from the water discharge portion fragile. Further, since air is mixed little by little in the state of fine bubbles, it is possible to prevent a large amount of air from being mixed as relatively large bubbles and to mix a relatively small amount of total air. Therefore, a relatively small amount of air bubbles in a fine state can be mixed in, and the water discharge flow from the water discharge portion can be made more difficult to break.

Here, the flow of hot water in the inlet flow path 24 will be described. Hot water flows into the inlet flow path 24 from the bathtub 2 through the bathtub communication port 12. In the inlet flow path 24, the flow of hot water flowing into the communication flow path inlet 50 from the bathtub 2 and the flow of hot water flowing into the pump flow path inlet 52 from the bathtub 2 are independent of the inlet. Is formed. Since the communication flow path inlet portion 50 and the pump flow path inlet portion 52 each form an opening toward the internal region A of the bathtub 2 in parallel, the communication flow path inlet portion 50 and the pump flow path inlet portion 52 The flow of hot water flowing into each forms an independent and linear flow toward each opening. Therefore, the two flows can be less likely to affect each other, and the hot water flowing from the communication flow path inlet portion 50 toward the bathtub communication portion 42 is affected by being sucked into the pump flow path inlet portion 52 by the pump 4. This can be prevented and hot water can be stably supplied to the jet pump unit 10.

Further, in the inlet flow path 24, the flow path cross-sectional area of the inlet flow path 24 is larger than the sum of the flow path cross-sectional area of the communication flow path inlet portion 50 and the flow path cross-sectional area of the pump flow path inlet portion 52. The flow of hot water flowing into the communication flow path inlet 50 from the bathtub 2 and the hot water flowing into the pump flow path inlet 52 from the bathtub 2 are branched in the inlet flow path 24. Since the flow of the water is relatively stably formed in the spatial region in the inlet flow path 24 in an independent state, the flows can be less likely to affect each other. The flow lines of the hot water flowing into the communication flow path inlet 50 from the bathtub 2 and the flow of hot water flowing into the pump flow path inlet 52 from the bathtub 2 do not intersect with each other. It has a sufficient flow area (flow space) so that it can flow independently to the extent that it is less likely to affect each other. The flow of hot water sucked into the pump flow path inlet portion 52 is formed as a flow of hot water water from the internal region A of the bathtub 2 toward the pump flow path inlet portion 52, and is formed from the communication flow path inlet portion 50 side to the pump flow path inlet portion. It is formed so as to suppress the flow of hot water toward 52. Therefore, it is possible to more reliably prevent the hot water flowing toward the bathtub communication portion 42 from being sucked by the pump 4, and the hot water can be stably supplied by the jet pump unit 10.

As shown by the arrow F15, the hot water flowing into the blow water discharge unit side flow path 36 is jetted from the blow water discharge unit 16 toward the inside of the bathtub as shown by the arrows F19 and F20. The hot water discharged from the blow water discharge unit 16 is hot water pumped by the pump 4, and forms a relatively small flow rate and a high-speed water discharge flow. The hot water discharged from the blow water discharge unit 16 collides with the waist and back of the user H, so that the collided portion can be massaged.

In FIG. 9, it will be described that the blow water discharge unit 16 also functions as a stirring water discharge unit that agitates the bathtub water stored in the bathtub 2. The hot water in the bathtub 2 can be agitated by simultaneously spouting water from the water spouting unit 6 and spouting water from the blow water spouting unit 16 (stirring water spouting unit).
The hot water discharged from the blow water discharge unit 16 at high speed forms a strong flow as shown by arrow F20, and in addition to the convection of the natural hot water in the bathtub 2, the hot water in the bathtub 2 is forcibly agitated. Form a flow. Further, even when the hot water discharged from the blow water discharge unit 16 at high speed collides with the user H, for example, a flow that spreads in the vertical direction as shown by arrow F25 is generated, and the hot water in the bathtub 2 is forced. Form a stir-like flow.

The bathtub communication portion 42 and the bathtub water communication flow path portion 47 are arranged in the bathtub 2 at a height position equal to or less than the intermediate height position h1 between the bottom portion 2a and the upper end portion 2c of the bathtub 2. Even when there is a possibility that relatively low temperature hot water that tends to be stored in a low position among the hot water may flow into the bathtub communication portion 42, the blow water discharge portion 16 agitates the bathtub water in the bathtub 2 and the jet pump unit 10 Hot water with a relatively high temperature can flow into the bathtub. By discharging water from the blow water discharge unit 16 together with the water discharge from the water discharge unit 6, hot water having a relatively low temperature is supplied from the jet pump unit 10 to the water discharge unit 6, and hot water having a relatively low temperature is discharged from the water discharge unit 6. It is possible to more reliably suppress the water being discharged to the user H.
Further, the blow water discharge portion 16 is arranged on the vertical wall 2b of the bathtub 2 to which the communication flow path 26 of the bathtub water communication flow path portion 47 is connected, and the blow water discharge portion 16 and the bathtub communication port portion 12 have the same vertical length. Since it is arranged relatively close along the wall 2b, the hot water flowing into the communication flow path 26 of the bathtub water communication flow path portion 47 can be more efficiently agitated by the blow water discharge section 16. Therefore, it is possible to more reliably prevent the jet pump unit 10 from supplying hot water having a relatively low temperature to the water discharge unit 6 and the water discharge unit 6 from discharging the hot water having a relatively low temperature to the user H.

In the present embodiment, the water discharge unit 6 forms a wide and relatively large water discharge port 22 to discharge water at a low speed and a large flow rate, whereas the blow water discharge unit 16 forms an opening having a small diameter to discharge water at a high speed and a small flow rate. Is going. Water discharges with different flow velocities and flow rates are performed at the same time. In the present embodiment, the difference between the pressure loss in the jet nozzle 44 attached to the injection section side flow path 32 and the pressure loss in the blow water discharge section 16 attached to the blow water discharge section side flow path 36 is relatively small. Therefore, even when hot water is supplied from the common pump 4, it is possible to prevent the flow rate of hot water from being significantly biased to any of the flow paths, and to simultaneously discharge water from the water discharge unit 6 and the blow water discharge unit 16. It can be performed. Further, by using the jet pump unit 10, even when the flow rate of the hot water supplied from the pump to the injection unit side flow path 32 is constant (when it is not increased), the large flow rate of water discharged from the water discharge unit 6 is increased. This can be done, and the water discharge unit 6 and the blow water discharge unit 16 can discharge water having different flow velocities and flow rates at the same time.

According to the bathtub device 1 according to the embodiment of the present invention described above, by providing the jet pump unit 10 on the injection section side flow path 32 and the bathtub water introduction flow path 34, blow water is discharged from the blow water discharge section side flow path 36. Since the difference between the pressure loss of the flow path leading to the section 16 and the pressure loss of the flow path from the injection section side flow path 32 and the bathtub water introduction flow path 34 to the water discharge section 6 can be made relatively small, it is common. It is possible to suppress that the hot water supplied from the pump 4 of the above is largely biased to any of the blow water discharge part side flow path 36, the injection part side flow path 32, and the bathtub water introduction flow path 34, and the common pump 4 can be used. The hot water supplied from the blow water discharge unit 16 is simultaneously discharged from the water discharge unit 6 and the blow water discharge unit 16 so that the flow velocity of the hot water discharged from the blow water discharge unit 16 is higher than the flow velocity of the hot water discharged from the water discharge unit 6. Can be done.

Further, according to the bathtub device 1 according to the embodiment of the present invention, the hot water of the bathtub 2 is bathtubed without separately providing a dedicated water supply source for supplying hot water to the jet pump water storage unit 41 of the jet pump unit 10. It can be introduced from the water communication flow path portion 47 to the jet pump water storage portion 41, and the entire structure of the bathtub device 1 can be simplified. Further, since the jet pump water storage unit 41 of the jet pump unit 10 is not separately provided with a dedicated water supply source for supplying hot water from outside the bathtub, the hot water discharged from the blow water discharge unit 16 by the jet pump unit 10 is not provided separately. Even when a flow rate larger than the flow rate is discharged from the water discharge unit 6 into the bathtub 2, it is possible to prevent the water level in the bathtub 2, that is, the amount of water from increasing.

Further, according to the bathtub device 1 according to the embodiment of the present invention, the flow of hot water flowing into the communication flow path inlet 50 from the bathtub 2 and the flow of hot water flowing into the pump flow path inlet 52 from the bathtub 2. Is formed for each independent inlet, so that the flows are less likely to affect each other, and the hot water flowing from the communication flow path inlet portion 50 toward the bathtub communication portion 42 is pumped by the pump 4. It is possible to prevent the influence of being sucked into the inlet portion 52 and to stably supply hot water to the jet pump unit 10.

Further, according to the bathtub device 1 according to the embodiment of the present invention, the flow path cross-sectional area of the inlet flow path 24 is the flow path cross-sectional area of the communication flow path inlet portion 50 and the flow path cross-sectional area of the pump flow path inlet portion 52. Since it is formed so as to be larger than the sum of the above, the flow of hot water flowing into the communication flow path inlet portion 50 from the bathtub 2 and the pump flow path from the bathtub 2 are branched in the inlet flow path 24. Since the flow of hot water flowing into the inlet portion 52 is formed relatively stably in an independent state, the flows can be less likely to affect each other. Therefore, it is possible to more reliably prevent the hot water flowing toward the bathtub communication portion 42 from being sucked by the pump 4, and the hot water can be stably supplied by the jet pump unit 10.
Further, since one inlet flow path 24 can be formed on the bathtub 2 side without forming two openings of the communication flow path inlet portion 50 and the pump flow path inlet portion 52, the inlet flow path can be formed in the bathtub 2. The processing work for connecting the 24 can be reduced, and the manufacturing work and the management work can be reduced by reducing the sealing portion between the bathtub 2 and the inlet flow path 24, and the risk of water leakage can be reduced. Can also be reduced.

Further, according to the bathtub device 1 according to the embodiment of the present invention, the flow velocity of the hot water discharged from the blow water discharge unit 16 is higher than the flow velocity of the hot water discharged from the water discharge unit 6. In the bathtub device 1 capable of simultaneously discharging water from the blow water discharge unit 16 and the water discharge unit 6, the pump is set so as to change the flow velocity and the flow rate of the hot water discharged from the blow water discharge unit 16. / Alternatively, the flow velocity and flow rate of the hot water discharged from the water discharge unit 6 can be changed with a relatively simple configuration by the opening degree adjusting mechanism 54 without changing the pump itself.

Further, according to the bathtub device 1 according to the embodiment of the present invention, the flow velocity of the hot water discharged from the blow water discharge unit 16 is higher than the flow velocity of the hot water discharged from the water discharge unit 6. Water can be discharged from the water discharge unit 6 arranged above the blow water discharge unit 16 to the upper part of the user's body, for example, the neck, shoulders, etc., above the blow water discharge unit 16. it can.

1 Bathing device 2 Bath 2a Bottom 2b Vertical wall 2c Upper end 4 Pump 6 Water discharge part 6a Water discharge part Top surface 8 Control unit 10 Jet pump unit 12 Bath communication port 14 Circulation flow path 16 Blow water discharge 18 Switching valve 20 Casing 22 22a Water discharge part inner flow path bottom surface 24 Inlet flow path 26 Communication flow path 28 Pump upstream side flow path 30 Pump downstream side flow path 32 Injection part side flow path 34 Bath water introduction flow path 36 Blow water discharge part side flow path 38 Operation part 40 Pressure Sensor 41 Jet pump water storage 42 Bathtub communication part 42a Bottom surface 42b Top surface 44 Jet nozzle 44a Tip 45 Air introduction part 45a Tip opening 46 Bath water introduction part 46a Inlet part 47 Bath water communication flow path part 48 Deployment part 50 Communication flow path Inlet 52 Pump flow path Inlet 54 Opening adjustment mechanism 56 Air pipe 58 Air introduction switching valve H User q1 Flow rate q2 Flow rate q3 Flow rate W Wall surface WL0 Water supply water level WL1 Full water level WL2 Water level WL3 Water level

Claims (6)

A bathtub device installed in a bathtub that stores hot water.
A pump that sucks hot water in the bathtub and supplies this hot water to the downstream flow path of the pump on the downstream side.
The first flow path branched from the downstream flow path of the pump and
The second flow path branched from the downstream flow path of the pump and
A first water discharge unit that discharges hot water supplied from the first flow path into the bathtub, and
A second water discharge unit that discharges hot water supplied from the second flow path into the bathtub, and
The control unit that controls the pump and
Equipped with a jet pump unit,
The spout of the second spout has a larger opening than the spout of the first spout, and the horizontal length of the spout of the second spout is vertical to the spout. Formed to be longer than the length in the direction,
The above jet pump unit
The jet pump water storage section where hot water is stored and
It is an injection part formed so that its own flow path diameter is smaller than the flow path diameter of its own upstream side flow path, and the injection part accelerates hot water supplied to the second flow path and jets the jet. The above-mentioned injection part, which induces a jet pump action by injecting into the pump water storage part, is provided.
The flow path on the downstream side of the jet pump water storage section is formed so that the flow path diameter of the flow path on the downstream side is larger than the flow path diameter of the injection section.
Further, the jet pump unit is provided on the second flow path, and the flow velocity of the hot water supplied from the pump is discharged from the first water discharge unit and the flow velocity of the hot water is discharged from the second water discharge unit. A bathtub device characterized in that water is simultaneously discharged from the first water discharge unit and the second water discharge unit so as to be higher than the flow velocity. The jet pump unit is further provided with a bathtub water communication flow path portion formed between the jet pump water storage unit and the bathtub and for introducing hot water from the bathtub into the jet pump water storage unit. The bathtub device according to claim 1. The communication flow path inlet portion of the bathtub water communication flow path portion is characterized in that it is formed independently of the pump flow path inlet portion of the pump upstream side flow path that sucks the hot water in the bathtub into the pump. 2. The bathtub device according to claim 2. The bathtub forms a single inlet flow path portion, and the communication flow path inlet portion and the pump flow path inlet portion are connected to the inlet flow path portion, and further, the flow of the inlet flow path portion. 3. The invention according to claim 3, wherein the road cross-sectional area is formed so as to be larger than the total of the flow path cross-sectional area of the communication flow path inlet portion and the flow path cross-sectional area of the pump flow path inlet portion. Bathtub device. The third or fourth aspect of the invention, wherein the jet pump unit further includes an opening degree adjusting mechanism capable of adjusting the opening area of the communication flow path inlet portion of the bathtub water communication flow path portion. Bathtub device. The second water discharge unit directs the bathtub water supplied from the pump from a position near the upper end of the bathtub above the water surface in the bathtub toward the space near the shoulder of the user who sits in the bathtub and takes a bath. The bathtub device according to any one of claims 1 to 5, wherein the bathtub device is arranged above the first water discharge portion in order to discharge water.

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