JP2785306B2 - Bubble tub - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

(A) Industrial application field The present invention relates to a bubble generating bathtub. (B) Conventional technology Conventionally, as one form of an air intake section of a bubble generation bath, there is one described in Japanese Utility Model Laid-Open No. 59-133218. That is, as shown in FIG. 18, the air intake portion fits the cap body (b) into the upper end opening of the air intake portion body (a) having the lower end connected to the ejection nozzle, and
A female screw part (d) provided in the air intake part main body (a) with a male screw part (c) extending from the center of the lower surface of the cap body (b) toward the air intake part main body (a). Screwed on
By adjusting the rotation and tightening of the cap body (b), the air inflow path (e) formed between the inner surface of the cap body (b) and the upper end opening of the air intake body (a) is opened and closed. Thus, it is possible to increase or decrease the amount of air bubbles mixed into the jet bath water in the jet nozzle from the air intake unit main body (a). (C) Problems to be Solved by the Invention However, in the case of the above-described bubble generating bath, the amount of bubbles in the spouting bath water can be simply changed by manual operation to change the feeling of irritation caused by the bubbles. ,
In addition, it is not possible to enjoy a change in the stimulus sensation due to the presence or absence of bubbles periodically. (D) Means for Solving the Problems The present invention relates to a bathtub body, a circulation pump, a bath water suction flow path communicating the bathtub body with the circulation pump, a plurality of ejection nozzles provided in the bathtub body, An opening / closing valve provided in a strong bath flow path for communicating a circulation pump with each ejection nozzle, an air suction path provided in the strong bath flow path, and a bubble amount adjusting valve provided in the air suction path; A control unit that controls the driving of the bubble amount control valve according to a preset program, and the control unit periodically changes the air intake time and the air intake stop time, thereby controlling In addition to alternately jetting hot water with air bubbles and hot water without air bubbles, the on-off valve can be driven to switch between jetting and stopping of hot water from multiple jet nozzles. To provide a bubble generating bathtub characterized by It is intended. The present invention is also characterized in that the control unit controls the operation of the on-off valve in accordance with a preset program, and selectively switches between jetting and stopping of hot water from a plurality of jet nozzles. . (E) Example Hereinafter, the bubble generating bathtub according to the present invention will be described in detail with reference to the accompanying drawings.

[Explanation of the overall structure of the bubble tub]

First, the overall configuration of the bubble generating bath according to the present invention will be described. (A) shown in FIG. 1 and FIG. 2 is a bubble generation bathtub according to the present invention. The bubble generation bathtub (A) includes a front and rear wall of a bathtub body (1) formed in a box shape having an upper surface opening. Foot side, back side, and ventral side jet nozzles on the left and right side walls, respectively (2) (2)
(3) (3) (4) (4) are provided in total of six. The bathtub body (1) has a flange-shaped edge (1a) having a constant width at the periphery, and the air intake section (5) is formed at the edge (1a).
Are formed at substantially center portions of the left and right side walls, and a vertically long concave portion (1b) (1b) having a substantially V-shaped cross section is formed on the side facing the rear wall (back side) of the concave portion (1b) (1b). The ventral ejection nozzles (4) and (4) are attached to the inclined surface (1'b) toward the center of the rear wall. Further, a pump protection case (9) is provided outside the bubble generation bathtub (A). Inside the case (9), a circulation pump (P) for circulating bath water and a pump (P) are provided. Filter (43) for filtering the bath water circulated by P)
And a pump driving motor (M) for driving the pump (P); a motor (M1) for driving the pump (P), a valve valve opening / closing operation motor (M1) for a nozzle described later; M2) and a control unit (C) for controlling the drive of the electric three-way valve (45). Further, the circulation pump (P) is connected to the bubble generating bath (A).
And a hot water circulation flow path (D) is interposed therebetween. That is, the hot water circulation flow path (D) includes a hot water suction pipe (10) for sending hot water from the bubble generation bath (A) to the circulation pump (P), and a hot water bath from the circulation pump (P). It is composed of a hot water supply pipe (11) for sending hot water to the hot water (A). And the bath water suction pipe (10) is the bathtub body (1)
One end is opened at the lower part of the pump, and the other end is connected to the water suction port of the circulation pump (P) so that the bath water is sucked into the circulation pump (P). (P)
One end is connected to the water outlet of the nozzle, and the jet nozzles (2) and (3)
The other ends are connected and connected to (4). Also, as shown in FIG. 3, the circulation pump (P)
A rotation speed detection sensor (6) for detecting the rotation speed of the circulation pump (P) is attached, and the detection result from the sensor (6) is
It is sent to a control unit (C) described later, and the control unit (C)
The number of rotations of the circulation pump (P) is controlled. Further, the rotation frequency of the circulation pump (P) can be controlled by changing the output frequency of the inverter. As shown in FIG. 3, a pressure detection sensor (48) for detecting the pressure of the bath water pumped through the pipe (11) is mounted in the middle part of the hot water bath pipe (11). The detection result from the sensor (48) is sent to a control unit (C), which will be described later, and the control unit (C) sends each ejection nozzle (2) (3)
The jet pressure of the bath water jetted from (4) is changed by the rotation speed of the pump drive motor (M) and the angle jet nozzles (2) and (3).
The control is performed by changing the position of the ejection amount adjusting valve body (22) of (4). The pressure detection sensor (48) can also be used as a water level sensor for detecting the amount of hot water in the bathtub body (1). In FIG. 1, (7) is an outlet connected to a power source, (30b) is an infrared receiving sensor for receiving infrared rays transmitted from a remote controller (30) described later, and (30b).
c) is a reception indicator lamp provided in the infrared sensor. Hereinafter, the configuration of each part in the bubble generating bath will be specifically described.

[Description of configuration of each part]

[Explanation of the structure of the jet nozzle] The jet nozzles (2), (3), and (4) use the same jet volume automatic variable jet nozzle that is configured to automatically change the jet amount and jet pressure of the bath water. And the fourth
The structure of the foot-side ejection nozzle (2) will be described with reference to FIGS. That is, the foot-side jet nozzle (2) is connected to the bathtub body (1).
A cylindrical nozzle casing (20) is connected to the outside of the bathtub body (1) in a cantilevered manner at the foot-side jet nozzle connection port (1g) of the above, and air bubbles are mixed in the nozzle casing (20). A jet forming part (50) for spouting the hot water and a throat part (60) for determining the jetting direction of the hot water mixed with bubbles spouted from the jet forming part (50) are provided on the bathtub body (1) side. It is arranged and fixed via the located decorative cover (26). Hereinafter, the nozzle casing (20), the decorative cover (26), the throat section (60), and the jet forming section (50), which are components of the ejection nozzle (2), will be described individually. As shown in FIG. 4, the nozzle casing (20) has its front end connected to a circular foot-side jet nozzle connection port (1g) opened at the lower part of the front wall of the bathtub body (1), and its rear end is substantially connected. It extends rearward horizontally. Then, a ring-shaped packing (1h) is fitted to the periphery of the foot-side spouting connection port (1g), and a female screw is attached to the front surface of the packing (1h) located in the bathtub body (1) and to the inner peripheral surface. Attach the rear face of the ring-shaped female screw part (1i) formed with, and attach / detach the outer male screw part (20a) formed on the outer peripheral surface of the front end of the nozzle casing (20) to the ring-shaped female screw part (1i) The nozzle casing (20) is freely screwed and attached to the front wall of the bathtub body (1) in a substantially orthogonal state and in a watertight state. The decorative cover (26) has a cylindrical shape as a whole, and has a female screw portion (26a) formed on the outer peripheral surface thereof.
Is detachably screwed to an inner peripheral male screw portion (20j) formed on the inner peripheral surface of the front end portion of the nozzle casing (20), and the front end portion (26b) of the decorative cover (26) is screwed into an inner / outer superimposed state. Along the front end of the attached nozzle casing (20) and the front end of the ring-shaped internal thread portion (1i), it is folded back to the outer peripheral surface of the ring-shaped internal thread portion (1i), and the front end portion (26b) This covers the front end of the nozzle casing (20) and the ring-shaped female screw portion (1i), and the throat fixing member (25) described later is fixed at the rear end of the decorative cover (26). In addition, as shown in FIGS. 5 and 6, on the peripheral wall of the central portion of the nozzle casing (20), a connecting portion of the intake pipe (20) is provided.
b), and an inlet pipe (1) having one end connected to the connecting portion (20b) and connected to the air intake portion (5) (see FIG. 1).
The other end of 2) is detachably connected. The rear peripheral wall of the nozzle casing (20) has a fourth
As shown in FIG. 5 and FIG. 5, a strong feed pipe connecting portion (20c) orthogonal to the nozzle axis is opened, and a bath water strong feeding pipe (11) is detachably connected to the connecting portion (20c). Yes (first
See figure). (N) indicates the direction of bath water inflow. The throat portion (60) is composed of a throat (24), a throat fixing member (25) for supporting the throat (24) to be able to swing freely, and a front portion of the valve seat forming cylinder pair (21). ing. Then, the throat (24) is formed such that the outer peripheral surface of the base (24a) is formed in a spherical shape, and the base (24a) is attached to the throat fixing member (2).
The inner peripheral surface of 5) and the throat support surfaces (25a) (21b) formed on the inner peripheral surface of the valve seat forming cylinder (21) are slidably fitted in surface contact with the throat support surfaces (25a, 21b). 24a) Protrude forward the cylindrical tip (24b) with a smaller outer diameter, and swing the tip (24b) manually in any direction up, down, left and right around the base (24a). Adjustable. Moreover, a constant sliding resistance acts on the base (24a) of the throat (24) from the throat support surfaces (25a) (21b),
The throat (24) can be stopped at any swing angle. The base (24a) of the throat (24) has its top (24'a) fitted to the throat support surface (21b),
Position it on the same vertical as the front end face of the valve seat forming cylinder (21),
In addition, the width from the center of the base (24a) to the rear end face (24'b) is formed to be approximately half of the half of the base (24a), and the throat from the inside of the bathtub body (1) to the throat support surface (21b). The base (24a) can be easily fitted. In addition, the base (24a) of the throat (24) has a substantially front half inner peripheral surface having the same diameter as the inner diameter of the distal end portion (24b), and a substantially rear half inner peripheral surface formed to have a diameter which is enlarged rearward. Base (24a)
The rear end opening diameter is larger than the inner diameter of the valve seat forming cylinder (21), and when the throat (24) swings, the valve seat forming cylinder (21) blows out to the throat (24). The influx of bathing water can be done smoothly. Further, the front end (24b) of the throat (24) extends the front end surface to the vicinity of the front end surface located in the bathtub body (1) of the decorative cover (26), and the outer peripheral surface of the front end portion (24b) is A throat swing operation space (28) is formed between the inner peripheral surface of the cover (26). And the throat swing operation space (28)
The bather grabs the tip (24b) of the throat (24)
The throat (24) is formed in such a size that it can be swung in any direction. The throat fixing member (25) is fitted into the front inner peripheral surface of the nozzle casing (20) via a positioning groove, and the front surface (25b) is fixed to the rear end of the decorative cover (26) by the fixing ring (2).
8), the inner peripheral surface (25a) is formed into a concave spherical surface corresponding to the front spherical surface of the base (24a) of the throat (24), and the throat (25a) is formed by the inner peripheral surface (25a). 24) at the base (2
The front outer peripheral surface of 4a) is slidably supported in surface contact. Also, the valve seat forming cylinder (21) is connected to the nozzle casing (2
0) The front end opening is freely inserted into and out of the center of the nozzle casing (20), and the rear end face is positioned near the high-feed pipe connecting portion (20c) to form on the front outer peripheral surface. The projecting step (21b) engages with the concave step (20i) formed on the inner peripheral surface of the nozzle casing (20) to regulate backward sliding and rotation around the axis, as well as the valve seat. The position of the jet forming portion (50) provided in the forming cylinder (21) and the position of the air mixing portion (70) provided in the nozzle casing (20) are aligned. A throat support surface (21c) of a concave spherical shape corresponding to the base (24a) rear spherical surface of the throat (24) is formed on the inner peripheral surface of the front portion of the valve seat forming cylinder (21). (21c), as described above, the base (2
4a) is fitted in surface contact, and the throat fixing member (25)
The base portion (24a) of the throat (24), which is restricted from sliding forward, restricts the sliding of the valve seat forming cylinder (21) forward. The jet forming part (50) includes an air mixing part (70) provided in the middle of the valve seat forming cylinder (21) and the air mixing part (70).
Immediately after the valve seat (21a) forming the jet forming flow path (27), and the jet forming flow path (2
7) A valve for opening and closing the valve (22) for opening and closing, a valve for opening and closing the valve for opening and closing the valve (22) for opening and closing the valve (22), and a motor (M1) And a rear wall forming plate (29). The valve seat forming tubular body (21), which is perpendicular to the axis of the intake pipe connecting part (20b), has a fifth outer peripheral surface located at an intermediate position.
As shown in FIG. 6 and FIG. 6, an annular air inflow path (21d) is formed along the outer peripheral surface, and the air pipe (21d) has an intake pipe connecting portion (20b) side and the connecting portion (20d). Air inlets (21e) and (21f) are provided on the side opposite to 20b), and the valve seat forming cylinder (2) is passed through the air inlets (21e) and (21f).
1) The inside and the intake pipe connecting portion (20b) are communicated to form an air mixing portion (70) in the valve seat forming cylinder (21). (M) indicates the air inflow direction. Further, the valve seat (21a) is attached to the valve seat forming cylinder (2) in the middle of the valve seat forming cylinder (21) immediately behind the air mixing part (70).
1), a jet forming flow path (27) is formed on the axis of the valve seat (21a), and a right-angled corner (21) is formed on the inner peripheral edge of the rear end of the valve seat (21a). 'A) to form the same corner (2
1'a), the ejection amount adjusting valve element (22) having the outer peripheral edge at the inclined surface (22a) is brought into contact with or separated from the ejection amount adjusting valve element (22). 27) The opening and closing amount (adjusting the ejection amount and ejection pressure) can be adjusted. As shown in FIG. 7, the nozzle valve opening / closing operation motor (M1) includes a tubular motor casing (23) detachably mounted on a rear wall forming plate (29), and the motor casing (23). ), A cylindrical coil (23a) is provided coaxially with the nozzle casing (20), and a cylindrical magnet (23b) is disposed within the coil (23a).
The magnet (23b) can be rotated forward and reverse by exciting a), a cylindrical rotor nut (23c) is concentrically and integrally mounted inside the magnet (23b), and the rotor nut (23c) is 23e) so that it can rotate freely, and the valve support rod (2
3d) penetrates slidably forward and backward. Then, a spiral rotor nut-side ball groove (23k) is formed on the inner peripheral surface of the rotor nut (23c), and a spiral groove is formed on the outer peripheral surface of the valve body support rod (23d) in the same direction as the rotor nut-side ball groove (23k). Spiral rod-side ball groove (23
m) to form the opposing rotor nut side ball groove (23
k) Ball (23n) between rod side ball groove (23m)
Are rollably interposed. (23g) is a rotation restricting piece that prevents the valve body support rod (23d) from rotating with the rotor nut (23c). With this configuration, the valve support rod (2) is linked to the rotor nut (23b) that rotates integrally with the magnet (23c).
3d) can be moved forward and backward through a ball (23n) a minute distance steplessly. In addition, the distal end of the valve body support rod (23d) is connected to a rod insertion hole (29) provided in the center of a rear wall forming plate (29) described later.
e) It penetrates the inside and extends into the nozzle casing (20), and a valve body (22) for adjusting the ejection amount is attached to the tip of the valve body support rod (23d). The valve body support rod (23d) has, at its rear end, an amount of advance / retreat of the valve body support rod (23d), that is, a valve for adjusting the ejection amount by the advance / retreat operation of the valve body support rod (23d).
2) A valve reference position detection sensor (23f) that detects the opening and closing amount (adjusts the ejection amount and ejection pressure) is installed. The detection sensor (23f) is attached to the reference position Hall element (23i) Positioning element (23i) and valve support rod (2
3d) A reference position detecting magnet (23j) attached to the rear end position. The valve body reference position detection sensor (23f) includes a reference position hall element (23i) and a reference position detection magnet (23j) that change in accordance with the advance / retreat operation of the valve body support rod (23d).
Is converted into an electrical change and sent to the control unit (C) to detect a reference position (for example, a completely closed position), and the control unit (C) uses the control unit (C) to open and close the nozzle valve element. The number of pulses (rotation angle) from the reference position of the motor (M1) is calculated. (23h) is the coil (2
3a) and a cord connected to the valve body reference position detection sensor (23f). With this configuration, the motor (M1) for opening and closing the valve body for the nozzle energizes the coil (23a) to turn on the magnet (23c).
At the same time, the rotor nut (23b) is rotated, and the rotation of the rotor nut (23b) causes the valve body support rod (23d) to move forward and backward to adjust the ejection amount attached to the tip of the valve body support rod (23d). The valve body (22) is brought into contact with and separated from the valve seat (21a) so that the amount and pressure of the hot water jetted into the bathtub body (1) can be adjusted. In addition, the opening / closing amount of the valve body (22) for adjusting the amount of jet is
The result of the reference position detected by the valve body reference position detection sensor (23f) is sent to the control unit (C), and based on the result, the control unit (C) controls the energization of the coil (23a) to eject the same. The quantity adjusting valve element (22) is properly opened and closed to allow fine adjustment of the amount and pressure of the spout of bath water into the bathtub body. Also, the nozzle valve opening / closing operation motor (M1) is a motor that can advance and retreat the ejection amount adjusting valve element (22) steplessly over a small distance to finely adjust the ejection amount and ejection pressure of the bath water. Any other piezoelectric actuators may be used. A waterproof cover (40) integral with the ejection amount adjusting valve element (22) is attached to the periphery of the rear end of the ejection amount adjusting valve element (22). The waterproof cover (40) surrounds the distal end of the valve body support rod (23d) and prevents water from entering the valve body opening / closing operation motor (M1) through the surface of the rod (23d). The mounting flange (30) provided on the peripheral edge at the rear end of the nozzle casing (2)
It is attached to the front surface of the rear wall forming plate (29) in a watertight state in (0). The waterproof cover (40) is connected to the valve support rod (23
It has a bellows-like configuration that expands and contracts in the front-rear direction in conjunction with the forward / backward movement of d). Further, the valve body (22) for adjusting the amount of jet formed integrally with the waterproof cover (40) is formed of a synthetic resin such as polytetrafluoroethylene or nylon 11 throughout this embodiment. Also, (44) is a cover for preventing bites of hair and the like to prevent the bellows-like waterproof cover (40) from biting cotton chips and hair, and the cover (44) is used for mounting. It can be detachably attached to the flange (30) and can be removed when unnecessary. (20m) is an air breathing port. The rear wall of the nozzle casing (20) is formed by a rear wall forming plate (29) separate from the nozzle casing (20), and the rear wall forming plate (29) is formed of a nozzle casing (29). 20) It has a disk shape with the same diameter as the inner diameter of the rear end, and is fitted and detached from the opening at the front end of the nozzle casing (20) so as to be freely attached and detached. The rear wall forming plate (29) is connected to the nozzle casing (2
0) The rear peripheral edge is brought into contact with and locked to the rear wall forming plate restricting piece (20 g) formed on the inner peripheral surface of the rear end, thereby restricting the rearward sliding, while the valve seat forming cylindrical body (21). The front peripheral edge is brought into contact with and locked to a rear wall advancement restricting step (21g) formed at the rear end of the rear end, thereby restricting forward sliding. (29a) is the rear wall forming plate (2
9) Packing provided on the peripheral surface. The outer diameter of the motor casing (23) is
The diameter of the nozzle casing (20) formed by the inner peripheral surface of the rear wall forming plate (29) is smaller than the inner diameter of the rear end opening (20k). With the above configuration, the foot-side ejection nozzle (2) can be disassembled from inside the bathtub body (1). That is, the foot-side jet nozzle (2) is connected to the bathtub body (1).
By removing the decorative cover (26) from the inside, the throat fixing member (2) fixed by the decorative cover (26)
5) and the valve seat forming cylinder (21) can be taken out of the ejection nozzle body (20) into the bathtub body (1), and the ejection amount adjusting valve body (22) is opened and closed by the nozzle valve. It can be taken out from the nozzle casing (20) together with the motor (M1) to the inside of the bathtub body (1). The nozzle valve opening / closing operation motor (M1) can be removed from the outside of the bathtub body (1) if necessary. As described above, since the foot-side jet nozzle (2) only fixes each component member only by the decorative cover (26), it can be easily disassembled and assembled, and maintenance and the like can be easily performed. Further, the other ejection nozzles (3) and (4) are configured in the same manner as the ejection nozzle (2), so that the adjustment of the amount of bathwater to be ejected and the adjustment of the bathwater ejection pressure can be performed. The adjustment of the jet nozzles (2), (3) and (4)
This can be performed by a wireless remote controller (30) described later. The use patterns of the six foot-side / back-side and ventral-side jet nozzles (2), (3), and (4) will be described later with reference to FIGS. 13 and 16c. When spraying bath water at the same time, use the foot side spray nozzle (2) →
Bath water is sequentially ejected from each ejection nozzle in a fixed time cycle in the order of dorsal ejection nozzle (3) → ventral ejection nozzle (4) or foot ejection nozzle (2) → back ejection nozzle (3). In some cases, one or two types of ejection nozzles may be selected and used.
The selection can be made by a changeover switch to a desired ejection nozzle use pattern of the remote controller (30). [Description of Configuration of Air Intake Unit] Hereinafter, the configuration of the air intake unit (5) will be described. As shown in FIGS. 8 to 10, the air intake section (5)
Air inlet fitting (1f) at the edge (1a) of the bathtub body (1)
And a rectangular box-shaped air intake unit main body (80) with a top opening is fitted into the air intake unit mounting opening (1f), and a mounting flange formed on the upper edge of the air intake unit main body (80). (80
a) is fixed to the upper surface of the periphery of the air intake unit mounting port (1f), and is fixed with mounting bolts (81). The outside air and the inside of the air intake section body (80) are communicated by an air intake (82a) formed only outside the lid (82). And, in the center of the bottom surface of the air intake unit body (80), an intake pipe connecting part (83) is connected and connected, and one end of the intake pipe (12) (12) is connected to the front and rear walls of the connecting part (83) respectively. The air intake passage is formed by communicating with each other, and the air taken into the air intake unit main body (80) is sent to each intake pipe (12) (12) through the intake pipe connection part (83), and each intake pipe is (12) From (12), air can be supplied to each ejection nozzle (2) (3) (4). In FIG. 8, (84) is a reactance type silencer, and (85) is a check valve. The check valve (85) prevents backflow of bath water in the intake pipe (12). . In addition, a bubble amount control valve (87) for opening and closing a communication path (86) between the connection part (83) and the air intake part body (80) is provided in the intake pipe connection part (83). The valve (87) has a cylindrical valve body (88) having an upper edge communicating with the bottom of the air intake unit body (80), and a valve body (8).
8) A valve opening / closing motor (M2) attached to the bottom (88a) of the valve (88a), a valve support rod (89) attached to the motor (M2), and a tip of the rod (89) Mounting,
A valve body (90) that can freely contact and separate from a valve seat (88b) formed at the upper edge of the valve body (88). The air volume control valve (87) is connected to the intake pipe connection (8
3) The air volume control valve (87) can be easily maintained from the inside of the air intake unit (80). (88d) is a communication port provided on the peripheral wall of the valve body (88). In addition, the motor for opening and closing the valve body for adjusting the amount of air bubbles (M2)
Has a linear stepping motor structure similar to the nozzle valve opening / closing operation motor (M1), which can be controlled by a control unit (C) described later, and a bubble amount increasing / decreasing switch of a remote controller (30) described later. (66)
By operating (67) and driving the motor (M2) for controlling the opening and closing of the valve body for adjusting the amount of air bubbles, the valve body (90) is advanced and retracted, and the valve body (90) and the valve seat (88b) Adjusting the gap between the nozzles (2) through the suction pipe (12)
(3) It is possible to adjust the amount of air sucked into (4), that is, the amount of air bubbles mixed in the bath water. The valve opening / closing operation motor (M2) for controlling the amount of air bubbles is provided with a valve base position detection sensor (23f) attached to the nozzle valve opening / closing operation motor (M1). A position detection sensor (91) is attached, and the detection result from the sensor (91) is sent to the control unit (C), and the control unit (C) controls the opening / closing amount of the valve element (90). . The air intake unit body (80) is made of a plastic porous sintered body (for example, polyethylene sintered body, polypropylene sintered body, etc.), and has a cylindrical shape made of a sound absorbing material having a sound absorbing function and an air purifying function. Silencer formed in (92)
The silencer (92) has a silencer support plate (9)
3) Erect the silencer (9
The lower end openings (92a) of 2) are erected on the silencer support plate (93) at regular intervals in the front and rear, and the lower end openings (92a) of each silencer (92) are attached to the silencer support plate (93). The plurality of communication holes (94) are in communication with each other by matching each other. The upper surface of each silencer (92) is closed by the lid (95), and the air taken into the air intake unit body (80) from the air intake (82a) of the lid (82) is removed by the silencer (80). The air passes through the peripheral wall of 92) and is sent from the lower end opening (92a) to the lower part of the air intake unit body (80), and the air is sent to the intake pipe (12) via the bubble amount adjusting valve (87). .
(R) indicates the air inflow direction. In this manner, the air taken into the air intake unit main body (80) can be silenced and cleaned by passing through the peripheral wall of the silencer (92). [Description of Circulation Pump] Hereinafter, the configuration of the circulation pump will be described. As shown in FIG. 11, the circulating pump (P) communicates the upper impeller chamber (33) and the lower impeller chamber (34) in the pump casing (32) through a communication passage (32d). The lower impeller chamber (34) is provided with a bath water suction passage (32) provided on one lower side of the pump casing (32).
a) through the bath water suction pipe (10), and the hot water bath provided on the other lower side of the pump casing (32) through the (32b) to the hot water bath pipe (11). Then, it is communicated with one end of a suction pipe (41) of a filter (43) to be described later via a strong filtration path (32c) provided on one side of the upper impeller chamber (33). (32e) is the water intake,
(32f) indicates the lower outlet, (32g) indicates the upper outlet, (z1) indicates the circulating flow direction, and (z2) indicates the filtration flow direction. Then, the impeller shaft (35) is suspended from the upper and lower impeller chambers (33) and (34) so as to penetrate the center vertically.
The upper impeller (33a) and the lower impeller (34a) are respectively mounted on the upper and lower impeller chambers (3) on the impeller shaft (35).
3) Mounted coaxially in (34), and linked the impeller shaft (35) to the drive shaft (39) of the pump drive motor (M) mounted integrally and watertightly on the pump casing (32). Has been established. (36) is a sealing material attached to the impeller shaft (35), and ensures watertightness in the pump casing (32). As shown in FIG. 12, a filter (43) is connected to the upper impeller chamber (33) of the circulating pump (P) through a suction pipe (41) and a return pipe (42). ,
A part of the bath water sucked into the lower impeller chamber (34) is sent to the filter (43) through a suction pipe (41) connected to the upper water outlet (32g) of the upper impeller chamber (33). The bath water filtered by the filter (43) is sent through the return pipe (42) into the bath hot water supply pipe (11), and is sent from the lower water discharge port (32f) of the lower impeller chamber (34). 11) Merge with the bath water that is forcibly sent inside. With this configuration, the upper and lower impellers (33a) (34a)
When the is rotated, hot water in the bathtub body (1) is sucked from the hot water suction pipe (10) through the water inlet (32e) into the hot water suction passage (32a) of the lower impeller chamber (34), and the lower impeller is turned on. From the chamber (34), the water is forcibly fed into the bathtub main body (1) through the lower bath water intake (33a) through the inside of the bathwater strong feeding path (32b) and further through the bathwater strong feeding pipe (11). At this time, part of the bath water flowing into the lower impeller chamber (34) passes through the flow passage (32d), and the upper impeller chamber (3).
3), then through the strong filtration path (32c), through the upper outlet (33a), into the suction pipe (41), and through the filter (4).
It is sent to 3) where it is filtered, and it is sent through the filtered hot water and return pipe (42) into the hot water bath (11). As described above, the bath water circulating in the bath circulation path (D) by the circulation pump (P) including the upper and lower impellers (33a) and (34a) is partially filtered by the filter (43). I am trying to. In FIG. 11, (39a) is a rotor attached to the outer peripheral surface of the drive shaft (39) of the pump drive motor (M).
b) A fixed magnetic pole mounted on the inner peripheral surface of the motor casing (38) so as to face the rotor (37) inside and outside, (39c)
Is a cooling fan. [Description of Filter] Hereinafter, a configuration of the filter will be described. As shown in FIG. 12, the filter (43) has an acrylic mesh (43b) stretched in the lower portion of the inside of the filter body (43a), and a filter (43c) is provided on the mesh (43b). A baffle (43d) is attached to the inner surface of the upper wall of the machine body (43a). Then, one end of the drawing pipe (41) is connected to the upper end of the filter body (43a) in communication with the filter body (43a).
The lower end of the return pipe is connected to one end of the pipe (42), and the bath water is filtered downward from above the filter body (43a).
By passing through 3c), the bath water can be filtered. An electric three-way valve (45) is provided in the middle of the retraction pipe (41), and a drain pipe (46) is connected to one end of the electric three-way valve (45). The pipe (41) and the drain pipe (46) can communicate with each other. Then, the electric three-way valve (45) is switched so that the suction pipe (41) and the drain pipe (46) are in communication with each other, and the upper and lower impellers (33a) (34a) of the circulation pump (P) are rotated. By returning a part of the bath water through the return pipe (42) and passing the filter medium (43c) upward from below the filter body (43a), the filter medium (43c)
Can be cleaned. The switching operation of the electric three-way valve (45) can be performed by a remote controller (30) described later. [Description of Control Unit] Hereinafter, the configuration of the control unit will be described. As shown in FIG. 3, the control unit (C) includes a microprocessor (MPU) and an input / output interface (50) (5).
1), a memory (52) including a ROM and a RAM, and a timer (53). In the above configuration, the input interface (50) includes a rotation speed detection sensor (6) for detecting the rotation speed of the circulation pump (P), and a valve body for detecting the opening / closing amount of the ejection amount adjustment valve body (22). A reference position detection sensor (23f), a valve reference position detection sensor (91) for detecting the opening / closing amount of the bubble amount adjusting valve (5d), a pressure sensor (48) for detecting a water pressure in the hot water supply pipe (11), A bath temperature detecting sensor (T) for detecting the temperature of bath water in the bathtub body (1) and an infrared receiving sensor (30b) for receiving a driving signal by infrared rays from a remote controller (30) are connected. On the other hand, the output interface (51) includes a pump drive motor (M) and a nozzle valve opening / closing operation motor (M
1), a motor for opening and closing the valve for adjusting the amount of air bubbles (M2) and an electric three-way valve (45) are connected. The memory (52) stores the motors (M) (M1) (M2) and the electric three-way valve (45) based on the output signals from the sensors described above and the drive signals from the remote controller (30). And the like, and stores a drive order program for driving the drive unit. Further, the rotation speed of the circulation pump (P) may be changed by changing the frequency of the current supplied to the pump driving motor (M) by the inverter. [Description of Remote Controller] Hereinafter, a remote controller (30) for manually transmitting the drive output of the control unit (C) will be described. As shown in FIG. 13, the remote controller (30) includes an operation switch (60), a mild blow switch (61) which is a favorite jet mode switch, a finger pressure blow switch (62), a pulse blow switch (63), Massage blow switch (64) wave blow switch (65) and air pulse blow switch (79), bubble amount increase / decrease switch (66) (67), bath water spouting intensity switch (68) (69), Period increase / decrease switch (70) (71)
And the pattern switch (72), the pattern switch (73), the pattern switch (74), and the pattern switch (foot) 75), and a ventral jet nozzle use pattern switch (76) and a filter washing switch (77). Then, by turning on the operation switch (60),
The blow operation described later can be started. (78) is a power lamp that lights when the plug is inserted into the outlet (7) connected to the power source, (60)
a) is an operation table lamp that lights when the operation switch (60) is turned on, (61a) (62a) (63a) (64a) (65a) (7
9a) is a mode switch display lamp, (66a) and (67a) are bubble amount setting lamps, (68a) and (69a) are bath water jet intensity setting lamps, (70a) and (71a) are bath water jet cycle setting lamps,
(72a), (73a), (74a), (75a), and (76a) are ejection nozzle use pattern setting lamps, and (77a) is a filter washing switch indicator lamp. Further, as shown in FIG. 13, the remote controller (30) includes an infrared irradiator (30a) at a front end thereof, and operates a switch to operate a preset multi-frequency seattone modulation system (MFTM).
When infrared rays having a predetermined cycle corresponding to each switch are emitted from the infrared irradiator (30a), the infrared rays are detected by an infrared receiving sensor (30b) (see FIG. 1) installed in the bathroom. The detection signal is sent to the input interface (50) of the control section (C) to drive a desired drive device based on the drive program read from the memory (52). Moreover, the remote controller (30) is configured to be able to float on the surface of the bath (specific gravity is set to 1 or less) so that a bather can operate in a bathing state. Further, the infrared receiving sensor (30b) and the air intake section (5) may be integrally formed. With the above-described configuration, in the bubble generation bathtub (A) according to the present invention, the remote controller (30) is operated on the bath surface to operate the pump driving motor (M) and the nozzle valve opening / closing operation. Driving devices such as a motor (M1), a motor (M2) for controlling the opening and closing of a valve body for controlling the amount of air bubbles, and an electric three-way valve (45) are driven and controlled via a control unit (C), and are driven by the respective driving devices. The number of rotations of the circulation pump (P), the opening / closing amount and opening / closing speed of the ejection amount adjusting valve body (22) provided in each ejection nozzle (2), (3), (4), and the air intake section (5) The opening and closing speed and opening / closing speed of the bubble amount adjusting valve (5d) can be adjusted, and the switching operation of the electric three-way valve (45) can be performed. Then, the rotation speed of the circulation pump (P) is adjusted, the opening / closing amount and the opening / closing speed of the ejection amount adjusting valve element (22) are adjusted, and the opening / closing amount and the opening / closing speed of the bubble amount adjusting valve (5d) are adjusted. 6 different jet modes (mild blow, finger pressure blow, pulse blow, massage blow, wave blow and air (Pulse blow) can be set, and each jet mode can be selected by turning on / off a favorite jet mode switch provided in the remote controller (30). In addition, for each mode, the bubble amount increase / decrease switches (66) and (67) and the bath water jet strong / weak side switch (68)
By turning ON / OFF the (69) and the cycle increase / decrease switches (70) and (71), respectively, the increase / decrease of the amount of bubbles, the strength of the spout bath, and the increase / decrease of the spout bath cycle Can be performed. Further, by turning on / off each changeover switch to a favorite ejection nozzle use pattern, a use pattern of six ejection nozzles to which the above-mentioned ejection mode is applied can be selected. Further, the filter washing can be started by turning on the filter washing switch (77), and can be ended by turning off the filter washing switch (77).

[Explanation of favorite jet mode]

Hereinafter, the air pulse blow which is the gist of the present invention will be described with reference to FIGS. 14 and 15, and other preferred jet modes (mild blow, acupressure blow, pulse blow, massage blow, and wave blow) will be described. Will also be described briefly. [1] Air Pulse Blow Air pulse blow is a method of periodically changing the air intake time and the air intake stop time by the air intake section (5), to thereby mix the bubble-containing bath water and the bubble-free bath water. This is a jet form in which the jets are alternately spouted, and stimulates the bather. That is, in the air pressure blow, in the acupressure blow, the air volume control valve (5d) of the air intake portion (5) is alternately repeatedly opened and closed at regular intervals (for example, within 1 second). As a result, as shown in FIGS. 14a and 14b, the hot water (p3) containing air bubbles and the hot water (p4) containing no air bubbles can be alternately ejected. FIG. 15 shows the relationship between the bubble amount and the ejection time when the bubble ejection time of the air pulse blow and the bubble ejection stop time are the same (t2) seconds. In addition, such a change in the level of the air pulse blow can reduce the amount of bathwater to be spouted within a certain range (for example, 30 to 50 / m
It can be set in several steps (for example, five steps) in (in). The air pulse blow is operated by turning on the air pulse blow switch (79) of the remote controller (30). In addition, the usage pattern of the jet nozzle for jetting the hot water of the air pulse blow is as follows. Turn on the pattern switch (72) for all of the ejection nozzles and turn on the four ejection nozzles (2).
(2) (4) (4) When the bath water is simultaneously ejected from (4), and when the circulation use pattern switch (73) is turned ON, a cycle of X seconds (for example, 3 seconds) from each ejection nozzle (2) (4) When bath water is spouted alternately with each spout nozzle (2)
(3) There is a case where one or two types of (4) are selected and the bath water is jetted by the selected jet nozzle. The switching time of each switch when changing the level of the air pulse blow or changing the ejection nozzle use pattern is, for example, 1 second. When air pulse blow is used, the air intake section (5)
The opening / closing operation cycle of the air bubble amount control valve (5d) of the above can be adjusted by the cycle increase / decrease switches (70) (71) of the remote controller (30) so that the stimulus given to the bather can be varied. I have. The opening / closing operation cycle of the bubble amount control valve (5d) is
For example, five levels of 1 second, 2 seconds, 3 seconds, 4 seconds, and 5 seconds can be set. [2] Mild blow Mild blow is performed for each jet nozzle (2) (3) (4)
It is a jet form in which the amount of bath water spouted from the bath is large and the jet pressure is low, wrapping the whole body of the bather mildly and softly, giving the bather the feeling of stimulating massage. That is, mild blow is performed for each jet nozzle (2).
(3) By fully opening each ejection amount adjusting valve element (22) of (4), the rotation speed of the circulation pump (P) is set within a certain range (for example,
In the range of 2100 to 3000 rpm, and several steps (for example, five steps) within a low pressure range (for example, 0.2 to 0.5 kg / cm ² ) in which the discharge pressure of the pump (P) is set to be constant. By setting the strength level, a large amount of bath water (for example, 40 to 80 min) can be ejected from each ejection nozzle (2) (3) (4). The above-mentioned mild blow is operated by turning on the mild blow switch (61) of the remote controller (30). The usage pattern of the jet nozzle for jetting the mild blow bath water is the same as in the case of the air pulse blow described above. When using mild blow, air intake section (5)
Operate the air bubble amount control valve (5d) of the remote controller (30) with the air bubble increase / decrease switches (66) (67) to adjust the air bubble amount and change the mildness given to the bather's body. I can give it. [3] Acupressure blow Acupressure blow is a jet form in which the amount of bath water spouted from each spout nozzle (2), (3), (4) is small and the spout pressure is high, and is vigorously applied to a part of the bather's body. By applying the jet, the bather is given a stimulating massage sensation with a sense of acupressure. That is, the acupressure blow is performed at the highest rotation speed (N1) (for example, 3000 rpm) so that the discharge pressure of the circulation pump (P) is constant (for example, 1.0 kg / cm ² ).
The operation is controlled in the vicinity, and the ejection amount adjusting valve body (22) of each ejection nozzle (2) (3) (4) is adjusted to adjust the ejection amount of the bath water within a certain small range (for example, 30 to 50). / min) (in five steps). The above-mentioned acupressure blow is activated by turning on the acupressure blow switch (62) of the remote controller (30). The usage pattern of the jet nozzle for jetting the bath water in the acupressure blow state is the same as in the case of the air pulse blow described above. In addition, when using the acupressure blow, the bubble amount adjustment valve (5d) of the air intake unit (5) is operated by the bubble amount increase / decrease switches (66) (67) of the remote controller (30) to adjust the bubble amount. This is done so that the acupressure sensation given to the bather's body can be changed. [4] Massage blow Massage blow is performed for each jet nozzle (2) (3)
This is a jet form in which the above-mentioned mild blow and acupressure blow are alternately performed by periodically changing the amount and pressure of the bath water from (4). Are given alternately. That is, in the massage blow, the air amount adjusting valve (5d) of the air intake section (5) is fully opened, the rotation speed of the circulation pump (P) is kept constant, and each jet nozzle (2)
(3) By gradually decreasing or gradually increasing the opening degree of the ejection amount adjusting valve element (22) of (4), the change of the ejection amount of the bath water from each ejection nozzle is increased or decreased (for example, 30 to 80 / min). ) And the change in the jet pressure (for example, 0.3 to 1.0 kg / cm ² ) are periodically performed. The massage blow described above is operated by turning on the massage blow switch (64) of the remote controller (30). The usage pattern of the jet nozzle for jetting the bath water for the massage blow is the same as in the case of the air pulse blow described above. When using the massage blow, the opening / closing operation cycle of the ejection amount adjusting valve body (22) of each ejection nozzle (2), (3), (4) is controlled by the cycle increase / decrease switch (70) ( 71) so that the acupressure effect given to the bather can be varied. [5] Pulse blow Pulse blow is a jet form in which the individual jet nozzles (2) and (4) are periodically opened and closed to alternately jet and stop the bath water. By not giving out, it is possible to give the bather a sharp stimulus different from the air pulse blow described above. That is, the pulse blow is performed in the acupressure blow by the ejection amount adjusting valve element (2) of each ejection nozzle (2) (4).
2) is alternately moved to the fully open position and the fully closed position at the maximum speed (for example, within one second) every predetermined time. This makes it possible to alternately generate a state in which the bath is spouted and a state in which the bath is not spouted. When the bath water is ejected, there are cases where bubbles are contained and cases where bubbles are not contained. The above-described pulse blow is operated by turning on a pulse blow switch (63) of the remote controller (30). The usage pattern of the jet nozzles for jetting the bath water for the pulse blow is the same as in the case of the air pulse blow described above. In addition, when pulse blowing is used, the opening / closing operation cycle of the ejection amount adjusting valve body (22) of each ejection nozzle is adjusted by the cycle increase / decrease switches (70) (71) of the remote controller (30) to provide a bather with It is possible to change the sense of shiatsu given. [6] Wave blow Wave blow is a jet form in which the rotation speed of the circulation pump (P) is periodically changed to periodically change the jet amount of the bath water, and the jet amount changes at a slow cycle. This creates an unsteady flow and gives the bather a jet of the image of the returning wave. That is, the wave blow is performed by each ejection nozzle (2).
(3) Turn the circulating pump (P) ON / OFF with the valve (22) of (4) fully opened or in the intermediate state.
Alternatively, the circulation pump (P) NO rotational speed is periodically changed within a certain range (for example, within a range of 1500 to 3000 rpm). The level of the wave blow is changed by opening and closing the bubble amount control valve (5d) of the air intake section (5) in addition to the flow rate change. As the bubble amount increases, the ejection pressure increases. can do. In addition, Wave Blow uses a remote controller (3
This is activated by turning on the wave blow switch (65) of (0). The usage pattern of the jet nozzle for jetting bath water in such a wave blow state is the same as in the case of the air pulse blow described above. When using wave blow, the circulation pump (P)
The cycle of changing the rotation speed of the remote controller (3
Adjustment is made by the cycle increase / decrease switches (70) and (71) of (0) so that the shiatsu effect given to the bather can be varied.

[Explanation of operation of bubble generation bathtub]

The operation of the bubble generating bath (A) will be described below with reference to FIG.
A description will be given based on the control sequences in FIGS. First, a plug such as the control unit (C) is inserted into the power supply to supply power (100). Next, freeze prevention operation is performed (110). That is, in the freezing prevention operation, as shown in FIG. 17, the bath temperature in the bath circulation channel (D) is detected by the bath temperature detection sensor (T) (111), and the bath temperature becomes 0. If the temperature is higher than 110 ° C (111Y) and lower than the temperature at which the circulation pump (P) can be used normally (for example, 5 ° C) (112N), it is checked whether the level of the bath water in the bathtub body (1) is above a certain level. (113) If the water level is above a certain level (113Y), the abnormal lamp is flashed (114), the circulation pump (P) is operated at a low speed by inverter control (115), and the bath water is circulated to After the temperature has reached the level where it can be used normally (11
2Y), stop the control operation of the circulation pump (P) (11
6), proceed to the next step (120). If the temperature of the bath water is lower than 0 ° C. (111N), an abnormal lamp (not shown) is blinked (117), and the circulating pump control operation is maintained in the OFF state (118). Further, it is checked whether the water level of the bath water in the bathtub body (1) is above a certain level (113), and if the water level is not above a certain level (113N), the operation of the circulation pump (P) is stopped (116). If the temperature of the bath water in the bathtub body (1) is equal to or higher than the temperature at which the circulation pump (P) can be normally used, the process proceeds to the next step (120) in the normal mode. Then, the operation switch (60) provided on the remote controller (30) is turned on (120). In this case, if the above bath temperature condition (5 ° C. or higher) is not satisfied, even if the operation switch (60) is turned on,
Each drive does not work. Next, the water level of the bath water in the bathtub body (1) is equal to or higher than a certain level by the pressure sensor (48) also serving as the water level sensor.
That is, it is detected whether or not the water level is higher than the mounting position of each jet nozzle and is equal to or higher than the water level at which the bath water can be jetted in a desired mode from each jet nozzle (121). As a result, if the water level is above a certain level (121
Y), the operation lamp (60a) is turned on (122), but if the water level is not above a certain level (121N), the abnormal lamp flashes (123). In the bathtub equipped with an automatic water heater, Begins (124). The hot water operation is performed by the bathtub body (1).
The bath water is replenished inside the bath so that the water level of the bath water is equal to or higher than the predetermined level. When the water level reaches a certain level, the hot water operation stops and the operation lamp (60
a) lights up (122). Next, it is determined whether the flow rate adjusting valve element (22) and the bubble amount adjusting valve (87) of all the ejection nozzles (2), (3), (4) are at preset positions by a valve element reference position detection sensor (23f). (9
It is detected by 1) (125). Here, the preset position refers to, for example, a state in which the opening degree of each of the valve bodies (22) of all the ejection nozzles (2), (3), and (4) is fully opened, and all the ejection nozzles (2), (3), (4). ) It is a position where the bath can be spouted with a more constant spout amount and spout pressure. If the detection result is the preset position, the favorite jet flow mode can be selected. If the detected position is not the preset position (125N), the ejection amount adjusting valve element (22) and the bubble amount adjusting valve (87) of all the ejection nozzles (2), (3) and (4) are moved to the preset position. It is moved (126). Then, in the favorite jet mode, turn on the air pulse blow switch (79) provided in the remote controller (30).
(127Y), the air pulse blow operation is selected (128), or the pulse blow switch (63) is turned on (129Y) to select the pulse blow operation (13).
0) or turning on the massage blow switch (64) (131Y) to select the massage blow operation (13
2) Alternatively, turn on the wave blow switch (65) (133Y) to select the wave blow operation (134).
Or turning on the mild blow switch (61) (135Y) to select mild blow operation (136),
Or, by turning on the acupressure blow switch (62) (13
1aY), Acupressure blow operation is selected (132a). Below, when air pulse blow operation is selected (128)
Will be described. When one of the jet modes is selected, it is checked again whether or not the level of the bath water in the bathtub body (1) is above a certain level (200). This is because the bath water in the bathtub body (1) may be pumped out before the favorite jet mode is selected, and the water level may not be maintained at a certain level or higher. And when the water level is not above a certain level (200N)
, The abnormal lamp flashes (201), and in the case of a bathtub equipped with an automatic water heater, the hot water operation starts (202) to bring the water level to a certain level or higher. Next, when a water level above a certain level is detected,
The control operation of the circulation pump (P) starts (203). Then, the discharge pressure of the circulation pump (P) is detected by the pressure sensor (48), and it is checked whether the discharge pressure is normal (204). If the discharge pressure is abnormal, the abnormal lamp is blinked (205), and the operation of the circulation pump (P) is stopped (206). If the discharge pressure is normal (204N), the drive time setting mimer of the circulation pump (P) is automatically turned on (20).
7). Next, the air pulse uro use lamp (jet operation mode lamp) is turned on (208). Next, the ejection period of the bubbles or bath water or the ejection intensity of the bubbles or bath water is adjusted to be increased or decreased as necessary based on the preset values. That is, if none of the cycle increase / decrease switches (70) (71) provided in the remote controller (30) is turned on, the rotation speed of the circulation pump (P) changes, and the ejection amount adjusting valve element ( 22) Opening / closing speed and bubble amount control valve (5
The opening / closing speed of d) is kept at a preset value (209Y), and bubbles and bath water are jetted at the same preset value cycle (21).
0). Moreover, in the case of the air pulse blow operation, in step (209) and the subsequent step (217), a preset value is previously set, and the air intake time and the air intake stop time by the air intake unit (5) are periodically determined. By changing, it is set so as to be able to take one form of a jet flow in which a bubble-containing bath water and a bubble-free bath water are alternately jetted. Also, turn on the cycle increase switch (71) to increase the cycle.
If the operation is continued (211Y), the period becomes longer than the preset value (212). Also, turn on the cycle decrease switch (70) to decrease the cycle.
If the operation is continued (214Y), the cycle is shorter than the preset value (215). In addition, if neither of the bath water spouting strength switch (68) (69) provided in the remote controller (30) is turned on,
The rotation speed range of the circulation pump (P), the opening / closing width of the valve body (22) for adjusting the ejection amount of each ejection nozzle, and the opening / closing width of the bubble amount adjusting valve (5d) are kept at preset values (217Y) Bubble and bath water are jetted out at the intensity of the value (218). Further, if the bath hot water ejection side switch (68) for increasing the ejection intensity (ejection pressure / ejection amount) is kept ON (219Y), the ejection intensity becomes larger than the preset value (220). Further, if the bath hot water jet weak side switch (69) for decreasing the jetting intensity is kept ON (222Y), the jetting intensity is reduced below the preset value (223). After setting the jetting strength as described above, the discharge pressure of the circulation pump (P) and the water level of the bath water in the bathtub body (1) are again measured by the pressure sensor (48), and the rotation of the circulation pump (P) is performed. The number is detected by the rotation speed detection sensor (6), and it is checked whether or not it is normal (154). If there is an abnormality, the abnormality lamp flashes (15
5) Stop the operation of the circulation pump (P) (156). Further, the discharge pressure and the number of revolutions of the circulation pump (P) are checked (157), and the control unit (C) is controlled according to the deviation from the set value.
To control the discharge pressure and rotation speed of the circulation pump (P) (140). If the deviation is within the set range (157), the bubble amount setting lamps (66a) (67a), the bath water jet cycle setting lamps (70a) (71a), and the bath water jet strength setting lamps (68a) (6)
9a) lights up (158). The user can visually recognize the use state by turning on the lamp. In this state, each of the ejection nozzles (2) (3) (4)
Can be selected by turning on the changeover switch. That is, unless all the ejection nozzles using all ejection nozzles (2), (3), and (4) are used as the preset pattern, and none of the changeover switches are turned on (159Y).
(161N), bath water in a preset jet mode is jetted from all the jet nozzles (2), (3) and (4) (160). Then, when the circulation use pattern switch (73) is turned ON (161Y), bath water in the set jet mode is sequentially ejected from the ejection nozzles (2), (3), (4) according to the circulation use pattern (162). When the circulation use pattern switch (73) is turned off (163Y), the mode returns to the preset pattern. Also, turn on the back side spray nozzle use pattern switch (74).
Then (164Y), the bath water in the set jet mode is jetted from each jet nozzle (3) (3) in accordance with the back side jet nozzle use pattern (165). When the back side nozzle use pattern switch (74) is turned off (166Y), the pattern returns to the preset pattern. Also, use the foot side spray nozzle use pattern switch (75).
When turned on (167Y), bath water in the set jet mode is jetted from each jet nozzle (2) (2) according to the foot jet nozzle use pattern (168). When the foot-side ejection nozzle use pattern switch (75) is turned off (169Y), the pattern returns to the preset pattern. Also, use the ventral ejection nozzle use pattern switch (76).
When turned on (170Y), bath water in the set jet mode is jetted from each jet nozzle (4) (4) according to the ventral jet nozzle use pattern (171). When the ventral ejection nozzle use pattern switch (76) is turned off (172Y), the mode returns to the preset pattern. When the back-side ejection nozzle use pattern switch (74) and the foot-side ejection nozzle use pattern switch (75) are turned on (173Y), each of the ejection nozzles (according to the back-side ejection nozzle use pattern and the foot-side ejection use pattern) is turned on. 2) (2)
(3) The bath water in the set jet mode is jetted from (3) (174). When the back-side ejection nozzle use pattern switch (74) and the foot-side ejection nozzle use pattern switch (75) are turned off (175Y), the mode returns to the preset pattern. When the back side nozzle use pattern switch (74) and the ventral side nozzle use pattern switch (76) are turned on (176Y), each of the discharge nozzles (2) is turned on according to the back side use nozzle use pattern and the foot side use pattern. ) (2)
(4) A bath in the set jet mode is jetted from (4) (177). When the back side nozzle use pattern switch (74) and the ventral side nozzle use pattern switch (76) are turned off (178Y), the mode returns to the preset pattern. When the foot-side ejection nozzle use pattern switch (75) and the ventral-side ejection nozzle use pattern switch (76) are turned on (179Y), each ejection nozzle (3) is turned on in accordance with the back-side ejection nozzle use pattern and the foot-side ejection use pattern. ) (3)
(4) Bath water in the set jet mode is jetted from (4) (180). When the foot ejection nozzle use pattern switch (75) and the ventral ejection nozzle use pattern switch (76) are turned off (181Y), the mode returns to the preset pattern. As described above, the jet pressure and the rotation speed of the circulating pump (P) and the inside of the bathtub body (1) are constantly maintained while the bathing is being enjoyed while the favorite jet is spouted in the desired jet nozzle use pattern. It has been checked whether the level of the bath water is kept normal (182). If there is an abnormality (182N), the abnormality lamp blinks (183), and the operation of the circulation pump (P) is stopped (184). If there is no abnormality (182Y), the discharge pressure and the rotation speed of the circulation pump (P) are checked (185).
Feedback control is performed on the discharge pressure and the number of revolutions in accordance with the deviation from the set values (140). If there is no deviation (185Y), the ejection nozzle use pattern lamp is turned on (186). By turning on the lamp, the user can visually recognize which pattern is selected. Then, when the operation switch (60) is turned off (187
Y), the operation of the circulation pump (P) is stopped (188). Subsequently, the bubble amount setting lamps (66a) (67a), the bath water ejection cycle setting lamps (70a) (71a), or the bath water ejection intensity setting lamps (68a) (69a) are turned off (189). The nozzle use pattern setting lamp is turned off (190), and the jet operation mode lamp is turned off (191). Then, the operation is turned off (192) and the operation lamp (60
a) goes out (193). Further, while the operation switch (60) is not turned off (187N) and the drive time setting timer of the circulation pump (P) is not completed (194N), the control operation of the circulation pump (P) is continued ( 140). When the drive time setting timer is up (194Y). The operation of the circulation pump (P) is stopped (18
8) The following steps (189) to (193) are followed. The air pulse blow operation has been described above. However, when the pulse blow operation is selected (130), when the massage blow operation is selected (132), and when the wave blow operation is selected (134), the air pulse blow operation is also performed. Step (20) is the same as when driving is selected (128).
0) to (223) and steps (154) to (194). In the case of pulse blow operation, step (20)
9) In (217), the preset value is set in advance so as to take one form of a jet flow in which each jet nozzle is periodically opened and closed to jet and stop the bath water alternately. In the case of massage blow operation, step (20
9) In (217), the preset value is set in advance so as to take a form of jet that alternately performs mild blow and acupressure blow by periodically changing the amount and pressure of jet of bath water. I have. In the case of wave blow operation, step (20
9) In (217), the preset value is set in advance so as to take one form of a jet flow in which the rotation speed of the circulation pump is periodically changed to periodically change the intensity of the jet pressure of the bath water. I have. Next, the case where the mild blow operation is selected (136) will be described with reference to FIG. 16f. As in the case where the air pulse blow operation is selected (128), it is checked again whether the water level of the bath water in the bathtub body (1) is equal to or higher than a certain level (137). When the water level is not higher than a certain level, the abnormal lamp flashes (138), and in the case of a bath with an automatic water heater, the hot water operation starts (139), and the bathtub (1) Keep the bath water level above a certain level. Next, when a water level above a certain level is detected,
The control operation of the circulation pump (P) starts (140). Then, the discharge pressure of the circulation pump (P) is detected by the pressure sensor (48), and it is checked whether the discharge pressure is normal (141). If the discharge pressure is abnormal (141N), the abnormal lamp is flashed (142), and the operation of the circulation pump (P) is stopped (143). If the discharge pressure is normal (141Y), the drive time setting timer of the circulation pump (P) is automatically turned on (14Y).
Four). This means that by setting the drive time of the circulation pump (P) in advance (for example, 30 minutes), the operator forgets to turn off the operation switch (60) and drives the circulation pump (P) for a long time. This is to prevent a failure from occurring. Next, the jet operation mode lamp is turned on (145). In this method, the lamp of the previously selected favorite jet mode is turned on so that the user can visually recognize which mode has been selected. Next, the air bubble amount is increased or decreased as necessary based on the preset amount. That is, if neither the bubble amount increase / decrease switch (66) (67) of the remote controller (30) is turned ON,
The air volume control valve (87) is maintained at the preset position (14).
6Y), a certain amount of air bubbles are blown out together with the bath water (147). In addition, in the case of mild blow operation, step (14)
In b), the preset amount is set in advance so as to be able to take one form of a jet having a large amount of bathwater and a low pressure. A bubble amount increasing switch (67) for increasing the bubble amount
If the is kept ON (148Y), the bubble amount increases (149). In addition, a bubble amount reduction switch (66) that reduces the bubble amount
If is kept ON (151Y), the bubble amount decreases (152). Thereafter, steps (154) to (194) in the case of the air pulse blow operation are followed. During this time, a desired use pattern of the ejection nozzle can be selected by turning on the changeover switch. The mild blow operation has been described above.
When the acupressure blow operation is selected (132a), steps (137) to (194) are followed in the same manner as when the mild blow operation is selected (136). Then, in the case of the acupressure blow operation, step (146)
In, the preset amount is set in advance so as to be able to take one form of a jet with a small amount of bathwater jetting and a high jetting pressure. (F) Effects According to the present invention, the following effects can be obtained. A bathtub body, a circulation pump, a bathwater suction flow path communicating the bathtub body with the circulation pump, a plurality of ejection nozzles provided in the bathtub body, and a bathwater bath communicating the circulation pump with each ejection nozzle. An on-off valve provided in the supply channel, an air intake path provided in the bath hot water supply channel, an air volume control valve provided in the air intake channel, and driving of the air volume control valve according to a preset program. A control unit for controlling the air supply time and the air supply stop time by periodically changing the air intake time and the air intake stop time. The bather alternately performs the jetting and drives the open / close valve to switch between jetting and stopping the bath water from a plurality of jetting nozzles. Can enjoy the stimulating change , It is possible to obtain a massage effect, moreover, it is possible to receive a blow with a change without operating the frequent operation switch. Further, since an opening / closing valve is provided in the bath water circulation flow path to enable selection of switching between bath water jetting and stopping from a plurality of jet nozzles, the bather needs to obtain the above-mentioned massage effect. The massage effect can be further improved by applying the bath water only to the part. The control unit controls the operation of the on-off valve in accordance with a preset program, so as to switch and select the ejection and stop of the bath water from the plurality of ejection nozzles.
Various blow modes can be easily enjoyed.

[Brief description of the drawings]

FIG. 1 is a perspective view of a bubble generating bathtub according to the present invention. FIG. 2 is a plan view of the bubble generating bathtub. FIG. 3 is an explanatory view of a conceptual configuration of the bubble generating bath. FIG. 4 is an enlarged sectional view of the ejection nozzle. FIG. 5 is a rear view of the jet nozzle. FIG. 6 is a sectional view taken along line II of FIG. FIG. 7 is an enlarged sectional view of a motor for opening and closing a valve body for a nozzle. FIG. 8 is an explanatory diagram of a piping of an intake pipe. FIG. 9 is an enlarged sectional view of an air intake section. FIG. 10 is a sectional view taken along line II-II of FIG. FIG. 11 is a partially cutaway front view of a pump driving motor and a circulation pump. FIG. 12 is a cross-sectional view of a filter. FIG. 13 is a plan view of a remote controller. 14a and 14b are illustrations of air pulse blowing. Fig. 15 shows air pulse blow pulses. 16a to 16f are flowcharts of the operation of the bubble generating bathtub. FIG. 17 is a flowchart of the freeze prevention operation. FIG. 18 is a cross-sectional view of a conventional air intake section. (A): Bubble generation bathtub (P): Circulation pump (C): Control unit (1): Bathtub body (2): Foot side jet nozzle (3): Dorsal jet nozzle (4): Ventral jet nozzle ( 10): Bath hot water suction pipe (11): Bath hot water pipe

──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Mitsuaki Hashida 2-81-1, Honmura, Chigasaki-shi, Kanagawa Prefecture Tochiki Kikai Co., Ltd. Chigasaki Plant (72) Inventor Koichi Uchiyama 2-81-1, Honmura, Chigasaki-shi, Kanagawa Prefecture No. Tochi Kiki Co., Ltd. Chigasaki Plant (72) Inventor Kenji Moriyama 2-8-1, Motomura Chigasaki City, Kanagawa Prefecture Toto Kiki Co., Ltd. Chigasaki Plant (56) References JP-A-64-56053 (JP, A JP-A-57-175360 (JP, A) JP-A-64-19425 (JP, U) (58) Fields investigated (Int. Cl. ⁶ , DB name) A61H 23/00

Claims (2)

(57) [Claims] 1. A bath tub body, a circulation pump, a bath water suction flow path communicating the bath tub body and the circulation pump, a plurality of ejection nozzles provided in the bath tub body, and each of the circulation pumps being connected to each ejection nozzle. An open / close valve provided in the communicating hot water flow path, an air suction path provided in the hot water flow path, a bubble amount control valve provided in the air suction path, and driving of the bubble amount control valve. A control unit for controlling according to a preset program. The control unit periodically changes the air intake time and the air intake stop time, so that the bubbled bath water and air bubbles are discharged from the ejection nozzle. Bubble generation characterized by alternately ejecting unmixed bath water, and by driving the on-off valve to switch between selecting and stopping the injection of bath water from a plurality of ejection nozzles Bathtub. 2. The control unit according to claim 1, wherein the control unit controls the operation of the on-off valve in accordance with a preset program, and selects and switches between jetting and stopping of hot water from a plurality of jet nozzles. 2. The bubble generating bathtub according to 1.