JP2004180696A - Liquid type massage apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce noise in a liquid type massage in which liquid for jetting inside a main body housing has a free surface. <P>SOLUTION: A user M is supported on a supporting sheet 2 covering the upper opening 1a of the main body housing 1. Inside the main body housing 1, the liquid for jetting is stored at a liquid level having the free surface. By a pump 14, the liquid for jetting is jetted from a jetting nozzle 12A and made to collide with the supporting sheet 2 and massage is performed. The jetting nozzle 12A is provided with a center nozzle 18A for jetting the liquid for jetting to produce high speed jetted liquid for massage and a plurality of peripheral nozzles 19A disposed around the center nozzle 18A and functioning for noise reduction by jetting the liquid for jetting at low speed. A plurality of jetting ports of the peripheral nozzles can be positioned at roughly equal intervals around the center nozzle (Figure 9 and Figure 14) or can be set in an annular shape continuously extended over the entire length in a peripheral direction of the center nozzle (Figure 13). <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a liquid massage device.
[0002]
[Prior art]
2. Description of the Related Art Some massage devices that perform massage on a human body use liquid ejected from an ejection nozzle, that is, an ejection liquid. As this type of liquid massage device, basically, an upper opening of a main body housing is covered with a support sheet, and a jetting liquid is directed from a jet nozzle provided in the main body housing to a lower surface of the support sheet. By spraying, the user lying on the support sheet is stimulated.
[0003]
There are two types of the above-mentioned liquid massage devices according to the difference in the manner of support by the user. The first type, as shown in Patent Document 1, is a type in which the inside of the main body housing is filled with the jetting liquid, that is, a type in which the jetting liquid in the main body housing has no free surface, The weight of the user on the support sheet is received by the jetting liquid, and is a so-called water-bed type.
[0004]
In the second type of the liquid massage device, as shown in Patent Literature 2, Patent Literature 3, Patent Literature 4, and Patent Literature 5, the jetting liquid in the main body housing has a free surface, that is, This is a system in which an air layer is interposed between the liquid surface of the jetting liquid in the main body housing and the support sheet (this second type is sometimes called a shower nozzle system). In this case, the ejection liquid stored at the bottom of the main body housing is pumped up by the pump and ejected from the ejection nozzle, collides with the support sheet from below, falls, and is supplied to the ejection nozzle again. become. Usually, the liquid level of the ejection liquid in the main body housing is lower than the ejection nozzle, and the ejection liquid ejected from the ejection nozzle passes through the ejection liquid stored in the main body housing. Without reaching the support sheet.
[0005]
[Patent Document 1]
JP-A-8-252293 [Patent Document 2]
JP 2000-325420 A [Patent Document 3]
JP-B-39-15383 [Patent Document 4]
US Patent Specification No. 4,853,988 [Patent Document 5]
US Patent Specification No. 4,976,256
[Problems to be solved by the invention]
In the above-mentioned liquid massage device of the first type (water bed type), the jetting liquid jetted from the jetting nozzle passes only through the liquid, which is advantageous in terms of noise, but it is advantageous for the user. There is a drawback that the stimulus given to the subject becomes monotonous.
[0007]
On the other hand, in the above-mentioned liquid massage device of the second type, the jetting liquid jetted from the jet nozzle reaches the support sheet through the air layer, so that it is effectively provided to the user. Although it has the advantage of being able to provide stimulation, it is disadvantageous in terms of noise. Among these noises, the main one is noise due to the support sheet being vibrated by the ejection liquid ejected from the ejection nozzle vigorously colliding with the support sheet, that is, collision noise, and in addition to this, from the ejection nozzle. Injection sound when the ejection liquid is ejected is also a problem.
[0008]
The present invention has been made in view of the above circumstances, and an object thereof is to reduce noise in a type in which a jetting liquid stored in a main body housing has a free surface. An object of the present invention is to provide a liquid massage device.
[0009]
[Means for Solving the Problems]
To achieve the above object, the present invention basically provides, as an ejection nozzle, a central nozzle for ejecting an ejection liquid at a high speed in order to sufficiently obtain a massage effect, and ejection from around the center nozzle. And a peripheral nozzle for jetting the liquid for use at a low speed. Specifically, as described in claim 1 of the claims,
A main body housing having an upper opening, a support sheet covering the upper opening of the main body housing, and a jetting liquid disposed in the main body housing and jetting from the main body housing toward a lower surface of the support sheet. And a liquid level of the liquid for jetting in the main body housing is set at a height position having a free surface so that an air layer is interposed between the main body housing and the support sheet. Liquid massage device
The ejection nozzle has a central nozzle and a peripheral nozzle that ejects an ejection liquid from around the central nozzle,
The flow rate of the ejection liquid ejected from the peripheral nozzle is set to be smaller than the flow rate of the ejection liquid ejected from the central nozzle,
It is like that.
[0010]
Thereby, a massage effect can be obtained with the ejection liquid ejected at a high speed from the central nozzle. Since the loud jet noise from the central nozzle is jetted at a low speed from the peripheral nozzles, it is prevented from being diffused to the surroundings by the jetting liquid having a low jet noise (spray noise reduction). In addition, since the ejection liquid from the peripheral nozzles ejected at a low speed is present around the ejection liquid from the central nozzle that vigorously collides with the support sheet, the vibration sound of the support sheet is diffused around. Is prevented (collision noise reduction).
[0011]
Preferred embodiments based on the above solution are as described in Claims 2 and 3 in the claims. That is,
The peripheral nozzle may be constituted by a plurality of nozzles arranged at substantially equal intervals in the circumferential direction of the central nozzle (corresponding to claim 2). In this case, by configuring the peripheral nozzles with a plurality of nozzles, each nozzle can have a simple configuration.
[0012]
The ejection port of the ejection liquid in the peripheral nozzle may be set in an annular shape extending over the entire length in the circumferential direction of the central nozzle (corresponding to claim 3). In this case, the entire periphery of the ejection liquid ejected from the central nozzle can be reliably surrounded by the low-speed ejection liquid ejected from the peripheral nozzle, which is more preferable for reducing noise.
[0013]
Injection mode selection means for manually selecting one of the first and second injection modes with respect to the execution of injection of the central nozzle and the peripheral nozzle, and the stop of injection,
An ejection mode switching unit that switches an ejection state of the ejection liquid from the central nozzle and the peripheral nozzle so that the ejection mode is selected by the ejection mode selection unit;
Has,
In the first ejection mode, the ejection nozzle is set to eject the ejection liquid from both the central nozzle and the peripheral nozzle,
In the second ejection mode, it is set so as to eject the ejection liquid only from the central nozzle among the central nozzle and the peripheral nozzle,
(Corresponding to claim 4). In this case, it is possible to select the ejection of the ejection liquid using only the center nozzle, that is, the conventional ejection mode.
In particular, in an environment where noise is a problem, the jetting liquid is also jetted from the peripheral nozzles to reduce noise, while in an environment where noise is not a problem, the jetting of the jetting liquid from the peripheral nozzles is stopped, This is preferable in terms of energy saving.
[0014]
A pump that pumps up the liquid for ejection in the main body housing and supplies the liquid for ejection to the ejection nozzle,
The pump is also used for the central nozzle and the peripheral nozzle,
(Corresponding to claim 5). In this case, the pump is used for both the central nozzle and the peripheral nozzle, which is preferable in terms of reducing the number of parts.
[0015]
A first pump for pumping the liquid for ejection in the main body housing and supplying the liquid for ejection to the central nozzle;
A second pump that is provided separately from the first pump and pumps up the liquid for ejection in the main body housing and supplies the liquid for ejection to the peripheral nozzle;
(Corresponding to claim 6). In this case, the supply of the liquid for ejection to the central nozzle and the supply of the liquid for ejection to the peripheral nozzles are performed by separate pumps, which is preferable for optimally setting the ejection of the liquid for ejection from each nozzle. Take. In addition, by controlling each pump individually, the degree of freedom of control such as the ability to finely change the ejection state of the ejection liquid from the central nozzle and the peripheral nozzles is increased.
[0016]
An injection amount ratio changing means for changing a ratio of the injection amount from the central nozzle and the peripheral nozzle may be further provided (corresponding to claim 7). In this case, it is possible to change the noise reduction level and the massage effect.
[0017]
An injection speed ratio changing means for changing the ratio of the injection speed from the central nozzle and the peripheral nozzle may be further provided (corresponding to claim 8). In this case, it is possible to change the noise reduction level and the massage effect.
[0018]
The liquid level of the ejection liquid stored in the main body housing is set so as to be located below the ejection nozzle, and the ejection liquid ejected from the ejection nozzle is stored in the body housing. Thus, it is possible to reach the support sheet without passing through the ejecting liquid (corresponding to claim 9). In this case, noise can be reduced while obtaining a sufficient massage effect, which is an advantage of a liquid massage device of a conventional general type.
[0019]
The liquid level of the ejection liquid stored in the main body housing is set so as to be located above the ejection nozzle, and the ejection liquid ejected from the ejection nozzle is stored in the body housing. The support liquid may reach the support sheet after passing through the jetting liquid once (corresponding to claim 10). in this case,
The jetting liquid jetted from the jet nozzle, especially from the central nozzle, is impacted by the supporting sheet while its strength is slightly changed under the influence of the oscillating free surface, so that it gives a more effective stimulation for massage. be able to.
Further, since the jetting liquid jetted from the jet nozzle, particularly the central nozzle, passes through the liquid to a considerable extent, noise is reduced as compared with the case where the jetting liquid passes only through the air layer. In addition, the high-speed jet sprayed from the spray nozzles, particularly the central nozzle, is covered by a relatively low-speed spray layer formed by entraining the stored jetting liquid when passing through the jetting liquid, and collides with the support sheet. The noise at the time of performing is also reduced. In addition to this, the area radiated from the main housing to the outside is reduced by increasing the area where the inner surface of the main housing is brought into contact with the liquid for jetting, and (reduction of the function of the main housing as a resonance box). ). Further, the ejection liquid ejected from the ejection nozzle collides with the support sheet in a state where the strength or the like is given as described above, so that the ejection liquid directly passes through only the air layer and is supplied to the support sheet. Therefore, the noise is reduced as compared with the case where the vehicle is collided with the vehicle.
[0020]
The liquid level of the jetting liquid in the main body housing is over the entire surface of the support sheet in a state where a center portion of the support sheet is partially bent downward by a user lying on the support sheet. Is set at a position lower than the support sheet,
(Corresponding to claim 11). In this case, the jetting liquid collides with the support sheet while its strength is slightly changed under the influence of the oscillating free surface, so that the stimulation for massage can be given more effectively. In particular, the entire surface between the jetting liquid in the main body housing and the support sheet has a free surface, which is preferable for sufficiently obtaining the massage effect using the free surface described above.
[0021]
The liquid level of the jetting liquid in the main body housing is bent downward in the state in which the center part of the support sheet is partially bent downward by a user lying on the support sheet. The jetting liquid comes into contact with the salient portion, and the periphery of the downwardly bent portion is set at a height position so as to have a free surface without contacting the support sheet. Yes (corresponding to claim 12). In this case, although the massage effect is slightly inferior, the liquid level can be the most preferable in terms of noise reduction.
[0022]
Liquid level adjusting means for changing the liquid level of the injection liquid stored in the main body housing between a position higher than the injection nozzle and a position lower than the injection nozzle,
In accordance with the change in the liquid level of the injection liquid by the liquid level adjusting means, the liquid level of the injection liquid is higher than the injection nozzle, and the injection liquid injected from the injection nozzle is once in the main body housing. A state in which the liquid reaches the support sheet after passing through the liquid for ejection, and a state in which the liquid level of the liquid for ejection is lower than that of the ejection nozzle, and the ejection liquid ejected from the ejection nozzle is ejected from the main body housing. And a state in which the support sheet is reached without passing through the liquid for use,
(Corresponding to claim 13). In this case, the effects corresponding to the above-described claims 9 and 10 can be selectively obtained.
[0023]
The liquid level adjusting means,
An auxiliary tank for storing the jetting liquid,
Supply and discharge means for performing supply and discharge of the ejection liquid between the main body housing and the auxiliary tank,
Control means for receiving the command from the selection means and controlling the supply / discharge means so that the liquid level of the ejection liquid in the main body housing is at a height position corresponding to the mode selected by the selection means;
(Corresponding to claim 14). In this case, the liquid level of the ejection liquid in the main body housing can be largely changed (adjusted) by utilizing the flow of the ejection liquid between the auxiliary tank and the main body housing.
[0024]
A jet pump is configured such that the injection liquid that is present around the supply path is sucked into the supply path of the injection liquid to the peripheral nozzle to convert a high-pressure small flow into a low-pressure large flow. (Corresponding to claim 15). In this case, a low-pressure large-flow rate, that is, a low-speed ejection liquid suitable for noise reduction can be supplied to the peripheral nozzles while using an inexpensive and small-sized pump for generating a high-pressure small flow rate.
[0025]
The support sheet has a strength capable of supporting the weight of the user and has a mesh-shaped first member having a large number of eyes for allowing the ejection liquid to pass therethrough. And a second member made of an elastic member for securing the second member (corresponding to claim 16). In this case, the member that the user makes contact with and hits the jetting liquid is an elastic member, and the physical stimulation of the jetting liquid is effectively performed while improving the user's contact feeling to the support sheet. Can be communicated to the user. Further, the weight of the user can be firmly supported by the first member having the eyes through which the ejection liquid passes.
[0026]
【The invention's effect】
According to the present invention, noise can be reduced.
[0027]
BEST MODE FOR CARRYING OUT THE INVENTION
1 and 2, a main body housing 1 is fixed and installed on a frame F. The main body housing 1 is formed of, for example, a fiber-reinforced plastic into a long and narrow tank shape with an upper opening. The main housing 1 is disposed substantially horizontally, and its upper opening 1a is covered with a support sheet 2 in a liquid-tight manner. A user (patient) M to be massaged is held (supported) on the support sheet 2 in a lying posture (lying posture) such as a head posture.
[0028]
In the embodiment, the support sheet 2 is configured as a two-layer structure including a first member 2A and a second member 2B, as shown in FIGS. That is, the first member 2A has a mesh shape (lattice shape) having a large number of eyes as shown in FIG. 4, and has a strength (tensile strength) sufficient to support the weight of the user M. I have. The second member 2B is formed of a thin elastic member such as rubber (silicon rubber in the embodiment) or the like, and is placed on the first member 2A. The second member 2B may have a thickness (strength) enough to have a sealing action for preventing leakage of the jetting liquid from the upper opening 1a of the main body housing 1 and therefore be sufficiently soft. Accordingly, the user M is brought into close contact with the second member 2B with a large area, and the physical force of the jetting liquid from below is effectively transmitted to the user M. I have. The periphery of each of the two members 2A and 2B is fixed to the periphery of (the upper opening 1a of) the main body housing 1. In addition, the support sheet 2 is not limited to the embodiment, and may be formed by only a thin elastic member such as rubber as a whole, or a reinforcing fiber is provided inside the support sheet 2 for securing strength. May be included.
[0029]
Injection liquid (usually hot water) is stored as a massage liquid in the main body housing 1, and the liquid level position (liquid level), that is, the free surface thereof is indicated by the symbol L. On the bottom wall (bottom part) of the main body housing 1, a narrow groove-shaped storage part 3 extending substantially horizontally is formed over substantially the entire length in the longitudinal direction. As will be described later, the storage section 3 can store even when the liquid level is sufficiently low. A pair of left and right traveling rails 4 extending substantially horizontally in the longitudinal direction of the main body housing 1 are arranged and fixed to the bottom of the main body housing 1 at the upper opening edge of the storage section 3. A traveling vehicle 5 is adapted to travel on the traveling rail 4, and traveling wheels thereof are indicated by reference numeral 6.
[0030]
A drive chain 7 is provided in the main body housing 1 along the travel rail 4 at a position slightly higher than the travel rail 4. The drive chain 7 extends substantially horizontally and is of an endless type. That is, the drive chain 7 is wound around a pair of sprockets 8 and 9 rotatably held at longitudinal ends of the drive chain 7 in the main body housing 1. The upper stroke portion of the drive chain 7 is denoted by reference numeral 7a. The lower stroke is indicated by reference numeral 7b. The sprocket 8 is a driving sprocket, and the sprocket 9 is a driven sprocket. The driving sprocket 8 is driven by a driving motor (not shown) installed on the side of the main body housing 1 via an interlocking mechanism (not shown). . The traveling vehicle 5 is connected to and fixed to either the upper stroke portion 7a or the lower stroke portion 7b of the drive chain 7, and the traveling vehicle 5 is reciprocated by rotating the sprocket 8 forward and reverse by a motor. You. By controlling the drive of the motor 10, the reciprocating drive range of the traveling vehicle 5 can be arbitrarily changed, and the traveling vehicle 5 can be stopped at any traveling position. In addition, as the driving means for driving the traveling vehicle 5 to travel, other than the chain type shown in the embodiment, an appropriate structure may be adopted.
[0031]
As will be described later, the traveling vehicle 5 is provided with a pair of left and right injection nozzles 12A and 12B. In order to eject the massage liquid from the ejection nozzles 12A and 12B, a pump 14 with a motor is provided on a side of the main body housing 1. As shown in FIG. 5, the pump 14 pumps up the massage liquid in the storage section 3 and pumps the injection liquid to each of the injection nozzles 12A and 12B via the flow rate (pressure) control valve 16. In addition, the pipe 15 for ejecting liquid pressure for injection which extends from the pump 14 is branched into two at the downstream side of the flow control valve 16, one branch pipe 15A is connected to one injection nozzle 12A, and the other branch pipe. The pipe 15B is connected to the other injection nozzle 12B. The branch pipes 15A and 15B are flexible pipes (for example, bellows-like pipes made of synthetic resin) that can bend over a predetermined length so that they can cope with a change in the traveling position of the traveling vehicle 5. I have. The details of the injection nozzles 12A and 12B will be described later.
[0032]
An auxiliary tank 22 is provided on the side of the main body housing 1 (see FIGS. 1 and 5). The auxiliary tank 22 is provided to change the liquid level L of the ejection liquid in the main body housing 1. That is, the liquid level L in the main body housing 1 is reduced by moving the injection liquid from the main body housing 1 to the auxiliary tank 22 by the pump 24 constituting the supply / discharge means. In addition, by moving the liquid for ejection from the auxiliary tank 22 to the main body housing 1 by the pump 24, the liquid level L of the liquid for ejection in the main body housing 1 is raised. The pump 24 is of a forward / reverse rotation type, and functions to transfer the liquid for ejection from the main body housing 1 to the auxiliary tank 22 according to the change of the rotation direction, and to perform the operation for jetting the liquid from the auxiliary tank 22 to the main body housing 1. The operation for transferring the liquid is switched. In addition, the pump 24 is a one-way rotary type, and the pipes connected to the suction port and the discharge port are changed using a switching valve to switch the movement direction of the ejection liquid, such as switching the supply and discharge directions. The mechanism for this can be appropriately selected.
[0033]
By adjusting the liquid level L of the ejection liquid in the main body housing 1, in the embodiment, the following three modes can be taken as different aspects of the liquid level L. The first mode is a mode shown in FIG. 2 in which the liquid level L of the ejection liquid in the main body housing 1 is set to a position higher than the ejection nozzles 12A and 12B, and the entire surface of the support sheet 2 is It has a free surface. That is, when the user M is on the support sheet 2, a part (center portion) of the support sheet 2 is slightly bent and displaced downward, but the liquid level L is higher than that of the portion which is bent and deformed downward. Lower position.
[0034]
The second mode is a mode shown in FIG. 6, in which the liquid level L of the jetting liquid in the main body housing 1 is set to a position higher than that in the first mode (of course, the liquid level L is higher than the jetting nozzles 12A and 12B). Is also high), and has a free surface only on a part of the surface of the support sheet 2. More specifically, in a state where the user M is on the support sheet 2, a part (central portion) of the support sheet 2 is slightly bent and displaced downward. While being in contact with the jetting liquid in the main body housing 1, the periphery of the portion bent downward is positioned higher than L of the jetting liquid, and is brought into a state where it is not in contact with the jetting liquid.
[0035]
The third mode is a mode shown in FIG. 7, in which the liquid level L of the ejection liquid in the main body housing 1 is lower than in the first mode, and is lower than the ejection nozzles 12A and 12B. State (naturally, it has a free surface with respect to the entire surface of the support sheet 2).
[0036]
The ejection liquid ejected from the ejection nozzles 12A and 12B collides with the lower surface of the support sheet 2 (passes through the eyes of the first member 2A and collides with the lower surface of the second member 2B), and this collision stimulates massage. To the user M on the support sheet 2. The jetting liquid that has collided with the support sheet 2 drops and is jetted again from the jet nozzles 12A and 12B.
[0037]
When the ejection liquid is ejected from the ejection nozzles 12A and 12B, in the first mode shown in FIG. 2, the ejection liquid from the ejection nozzles 12A and 12B once passes through the ejection liquid, and thereafter, After passing through the air layer above the liquid level (free surface) L, it will collide with the support sheet 2. In this case, since the free surface L swings, the length of the ejection liquid ejected from the ejection nozzles 12A and 12B passing through the ejection liquid is appropriately changed, and the free liquid L collides with the support sheet 2. The intensity of the jetting liquid is slightly changed. Thereby, more effective stimulation for massage can be given to the user M.
[0038]
In the first mode, noise is also reduced. The following three factors can be considered as factors of this noise reduction. First, the ejection liquid from the ejection nozzles 12A and 12B is not directly ejected into the air layer but is once ejected into the ejection liquid, so that the ejection liquid from the ejection nozzles 12A and 12B is ejected. In this case, noise is reduced. Next, since the main body housing 1 has a box shape, it functions like a resonance box. However, the liquid level L of the ejection liquid is at a position sufficiently higher than before, and the inner surface of the main body housing 1 Since the area in contact with the air layer is sufficiently small, while the area in contact with the jetting liquid is sufficiently large, the sound radiation from the wall surface of the main housing 1 is reduced. Lastly, as described above, the jetting liquid that collides with the support sheet 2 is given a delicate strength, and therefore, compared to the conventional case where the jetting liquid collides with the support sheet 2 continuously in the same state. As a result, the degree to which the support sheet 2 is vibrated by the ejection liquid is reduced, and the noise caused by the vibration of the support sheet 2 is reduced.
[0039]
In the second mode, since the liquid level L of the ejection liquid in the main body housing 1 is set to a higher position, and a part of the support sheet 2 is constantly in contact with the ejection liquid, the above-described noise is reduced. It will be further reduced.
[0040]
The third mode is the same as the conventional mode, and is selected when obtaining a massage effect in the same stimulation mode as the conventional mode.
[0041]
Next, the configuration near the injection nozzles 12A and 12B will be described in detail with reference to FIGS. First, a pair of left and right support shafts 32A, 32B extending in the up-down direction is fixed to the upper surface of the traveling vehicle 5. The support shafts 32A and 32B are formed in a tubular shape, and the above-described branch pipe 15A or 15B is connected to a lower portion thereof.
[0042]
A pair of left and right drums 36A, 36B are rotatably held by the support shafts 32A, 32B via bearing members 34A, 34B. Each of the drums 36A and 36B is a space 37A or 37B in which the inside is sealed. Each of the drums 36A and 36B has a circular outer diameter, and functions as a kind of gear having a tooth profile 38A or 38B formed on an outer peripheral surface thereof. Drums 36A and 36B as gears are configured so that when tooth shapes 38A and 38B mesh with each other, and one of drums 36A and 36B is rotated, the other is also rotated.
[0043]
The above-described ejection nozzles 12A and 12B are fixed to the upper surfaces of the drums 36A and 36B at positions eccentric with respect to the rotation center (see also FIG. 9). The injection nozzles 12A and 12B are always in communication with the space portions 47A and 37B in the drums 36A and 36B. Thus, the jetting liquid supplied from the pipes 15A and 15B passes through the shafts 32A and 32B and the spaces 37A and 37B, and is jetted upward from the jet nozzles 12A and 12B. Then, the position of the ejection nozzles 12A, 12B is changed in accordance with the rotation of the drums 36A, 36B, and the ejection position of the ejection liquid to the user M is changed.
[0044]
A worm gear 42 is fixed to the lower surface of one of the drums 36A in order to rotate the drums 36A and 36B. The worm gear 42 is fitted to the support shaft 32A so as to be relatively rotatable. A worm 44 is meshed with the worm gear 42. The worm 44 is rotatably held on the drum 36A using a bracket (not shown). The worm 44 is held so as to rotate integrally with a rotating shaft 46 extending in the longitudinal direction of the main body housing 1 and slidably in the axial direction. The rotation shaft 46 is rotatably held by the main body housing 1. Thus, when the rotating shaft 46 is rotated by a driving means such as a motor provided outside the main body housing 1, the worm 44 is also rotated, whereby the worm gear 42, that is, the drum 36A is rotated. Accordingly, the other drum 36B is also rotated. When the traveling vehicle 5 moves, the worm 44 is slid with respect to the rotation shaft 46, so that the drums 36A and 36B can rotate regardless of the position of the traveling vehicle 5.
[0045]
Next, the details of the injection nozzles 12A and 12B will be described with reference to FIGS. 8 and 9. Since the left and right injection nozzles 12A and 12B have the same configuration, the description will focus on the injection nozzle 12A. I decided to. First, the injection nozzle 12A has one central nozzle 18A and a plurality of peripheral nozzles 19A. The central nozzle 18A has a large diameter, and the flow velocity and the flow rate of the jetting liquid jetted therefrom are both large so that a sufficient massage effect can be given to the user M.
[0046]
The peripheral nozzles 19A are arranged around the central nozzle 18A, and a plurality of peripheral nozzles (a total of four in the embodiment) are provided at substantially equal intervals in the circumferential direction of the central nozzle 18A. Each peripheral nozzle 19A has a small diameter, and the flow velocity and the flow rate of the ejection liquid ejected from the peripheral nozzle 19A are sufficiently smaller than the flow velocity and the flow rate of the ejection liquid ejected from the central nozzle 18A, respectively. . More specifically, in the embodiment, the flow rate of the ejection liquid ejected from the peripheral nozzle 19A is applied to the support sheet 2 so as to be more advantageous for reducing noise than the massage effect for the user M. On the other hand, the flow velocity does not violently collide. Also, when the flow rate from the peripheral nozzle 19A collides with the support sheet 2 and spreads, the diffusion jetting liquid from each peripheral nozzle 19A causes the jetting liquid jetted from the central nozzle 18A to flow to the support sheet 2. The size is set so as to substantially completely surround the collision site. It should be noted that such setting of the peripheral nozzle 19A can be performed only by setting the diameter and length of the passage, but in addition, the above-described setting can be obtained by separately providing an orifice or the like in the peripheral nozzle 19A. You can also.
[0047]
The central nozzle 18A and the plurality of peripheral nozzles 19A communicate with each other at their base ends. More specifically, the peripheral nozzle 19A is branched from the base end of the central nozzle 18A, and has a format. This branch portion is shown as a communication portion 20A. As shown in FIG. 8, by attaching the injection nozzle 12A to the drum 36A, the communication portion 20A (that is, the central nozzles 18A and 19A) is automatically connected to the space 37A.
[0048]
The other injection nozzle 12B is also configured in the same manner as the injection nozzle 12A, and the same components of the injection nozzle 12B as the injection nozzle 12A are denoted by reference numeral B instead of the reference A used for the injection nozzle 12A. , And a duplicate description thereof will be omitted.
[0049]
Now, let us consider a case where the ejection liquid is ejected from all the nozzles, that is, the center nozzles 18A and 18B and the peripheral nozzles 19A and 19B. The ejection noise from the central nozzles 18A, 18B having a high speed and a large flow rate is considerably loud, but the peripheral nozzles 19A, 19B around the peripheral nozzles 19A, 19B eject the ejection liquid in a state where the ejection sound is small, so Loud spray noise generated by the nozzles 18A and 18B is prevented from being diffused (spray noise reduction).
[0050]
Further, the ejection liquid ejected from the central nozzles 18A and 18B vigorously collides with the support sheet 2 (this collision portion is referred to as a central collision portion), and vibrates the support sheet 2 greatly to generate a large collision sound. Will be. On the other hand, even if the ejection liquid ejected from the peripheral nozzles 19A and 19B having a small flow velocity collides with the support sheet 2 (this collision site is referred to as a peripheral collision site), only a small collision sound is generated. The ejection liquid ejected from the central nozzles 18A and 18B that generate a large collision sound is surrounded by the ejection liquid ejected from the peripheral nozzles 19A and 19B that generate only the small collision sound. Is prevented from diffusing to the surroundings (collision noise reduction). In other words, the central collision site, which is the loud collision sound generation site, is surrounded by the peripheral collision site that generates only a small collision sound, so that the diffusion of the collision sound is prevented.
[0051]
Here, the arrangement positional relationship of various devices will be described with reference to FIGS. First, in plan view, the outer peripheral edge of the frame F is located outside the outer peripheral edge of the main body housing 1. In this plan view, the pump 14 for pumping the ejection liquid, the auxiliary tank 22 for adjusting the liquid level of the ejection liquid, and the pump 24 are arranged on the side of the main body housing 1 and on the inside of the frame F, respectively. Is established. That is, the above-mentioned members 14, 22, and 24, which are large members, particularly the auxiliary tank 22, are disposed by effectively utilizing the dead space between the main body housing 1 and the frame F.
[0052]
Here, in the present embodiment, the liquid level L of the jetting liquid in the main body housing 1 can be automatically adjusted according to the manual selection in the first mode, the second mode, and the third mode. Have been. A control system for automatically adjusting the liquid level L will be described with reference to FIG. First, U is a controller as control means, which is configured using a microcomputer. The controller U receives signals from a mode selection switch S1, an injection amount (injection pressure) setting switch S2, a treatment time setting switch S3, a command switch S4 for fine adjustment of the liquid level L, and a liquid level sensor S5. . The controller U outputs a signal to the above-described flow control valve 16, a pump 24 for adjusting the liquid level, and a notification means S6 including at least one of a buzzer and a display means. The controller U and various switches S1 to S4 and S6 are integrated into one unit using a control box CB, and the control box CB is disposed at a position operable from the side of the main body housing 1. (See Fig. 1)
[0053]
The mode selection switch S1 is for manually selecting one of the first mode (FIG. 2), the second mode (FIG. 6), and the third mode (FIG. 7). The injection amount setting switch S2 is for manually instructing the injection amount (injection pressure) of the ejection liquid ejected from the ejection nozzles 12A and 12B. The treatment time setting switch S3 is for manually commanding the time during which the ejection liquid is being ejected from the ejection nozzles 12A and 12B. The command switch S4 is for manually giving a command to slightly change the liquid level L of the jetting liquid in the main body housing 1 in a continuously variable manner. It is said that they can be commanded individually. The liquid level sensor S5 detects the actual liquid level L of the jetting liquid in the main body housing 1 and is, for example, of a capacitance type, and is attached to the outer wall surface of the main body housing 1 by extending vertically. (See also FIG. 2). As shown in FIG. 2, an observation window 50 through which a liquid level L inside can be observed from the outside by a transparent member such as glass is provided on a side wall of the main body housing 1.
[0054]
The control functions of the controller U are as follows. First, the pump 24 is controlled so that the actual liquid level L of the ejection liquid in the main body housing 1 detected by the liquid level sensor S5 becomes a liquid level corresponding to the mode selected by the mode selection switch S1. Further, the opening degree of the flow control valve 16 is controlled such that the ejection amount (ejection pressure) of the ejection liquid ejected from the ejection nozzles 12A and 12B becomes the ejection amount selected by the ejection amount selection switch S2. When the treatment time set by the treatment time setting switch S3 has elapsed from the start of the ejection of the ejection liquid from the ejection nozzles 12A and 12B, the pump 14 is stopped to stop the ejection of the ejection liquid. While the command switch S4 is continuously operated, the pump 24 is drive-controlled to raise or lower the liquid level L of the injection liquid in the main body housing 1 according to the operation, and the operation of the switch S4 is stopped. At this point, the operation of the pump 24 is stopped. Thereby, the liquid level L of the ejection liquid in the main body housing 1 is finely changed in a continuously variable manner in accordance with the operation of the switch S4.
[0055]
Next, a specific control example of the controller U will be described with reference to a flowchart of FIG. In the following description, Q indicates a step. First, in step Q1, data input such as the operation status of various switches is performed. In Q2, the injection amount is set according to the operation of the switch S2 (the opening degree of the flow control valve 16 is set). In Q3, the drive of the pump 24 is controlled so that the liquid level L becomes the mode L according to the selection of the mode selection switch S1 (feedback control based on the output of the liquid level sensor S5).
[0056]
In Q4, it is determined whether or not the actual liquid level L detected by the liquid level sensor S5 has reached the target liquid level corresponding to the mode selected by the mode selection switch S1. If the determination in Q4 is NO, the process returns to Q3. If the determination in Q4 is YES, in Q5, the notifying means S6 is operated to notify that the target liquid level has been reached.
[0057]
In Q6, it is determined whether or not the switch S4 for manually changing the liquid level has been operated. If the determination in Q6 is YES, in Q7, after the pump 24 is driven and controlled in a direction corresponding to the operation of the switch S4, that is, to raise or lower the liquid level L, the process returns to Q6. If the determination in Q6 is YES, in Q8, the notifying means S6 is activated to notify that the injection is to be started, and then in Q9, the operation of the pump 14 is started, and the injection nozzles 12A, 12B are used for injection. Liquid is ejected. In Q10, it is determined whether or not the treatment time set by the switch S3 has elapsed. If the determination in Q10 is NO, the process returns to Q9 and the injection of the injection liquid continues to be executed, and the determination in Q10 is YES. At the point in time, at Q11, the operation of the pump 14 is stopped, and the injection of the injection liquid from the injection nozzles 12A and 12B is stopped.
[0058]
FIG. 12 and FIG. 13 show a second embodiment of the present invention. In the present embodiment, the ejection nozzles 60 corresponding to the ejection nozzles 12A (the same applies to the ejection nozzles 12B) are each constituted by one central nozzle 61 and one peripheral nozzle 62. That is, the peripheral nozzle 62 is formed in a thick pipe shape, and the central nozzle 61 penetrates therethrough. In other words, the peripheral nozzle 62 has an injection port 62a having an annular shape (annular shape in the embodiment) surrounding the entire periphery of the central nozzle 61. This makes it possible to reliably surround the entire periphery of the ejection liquid ejected from the central nozzle 61 by the ejection liquid ejected from the peripheral nozzle 62, which is extremely preferable in terms of noise reduction.
[0059]
A first pump 64 and an electromagnetic flow (pressure) adjusting valve 65 are connected to a pipe 63 connected to the central nozzle 61. A second pump 67 is connected to a pipe 66 connected to the peripheral nozzle 62, and an electromagnetic flow (pressure) adjusting valve 68 is connected to the pipe 66. Thereby, at least one of the discharge capacity of each of the pumps 64 and 67 and the opening degree of each of the flow control valves 65 and 68 is controlled by the controller U as shown in FIG. At least one of the flow rate ratio and the flow rate ratio between the ejection liquid and the ejection liquid ejected from the peripheral nozzle 62 can be changed.
[0060]
For example, by stopping the operation of the pump 67, the ejection liquid can be ejected only from the central nozzle 61, and the same ejection mode as in the related art can be obtained. Further, by changing the discharge capacity of the pump 64, the massage effect by the ejection liquid ejected from the central nozzle 61 can be changed (in this case, whether or not the ejection liquid is ejected from the peripheral nozzle 62 is determined. Absent). Further, in a mode in which each of the pumps 64 and 67 is operated to eject the ejection liquid from both of the nozzles 61 and 62, for example, by adjusting the opening degree of the flow control valve 68, the ejection is performed from the peripheral nozzle 62. It is also possible to change the balance between the massage effect using the jetting liquid and the noise reduction.
[0061]
When the pumps 64 and 67 are individually provided for each of the nozzles 61 and 62, the flow rate adjusting valves 65 and 68 may be separately omitted (change of the injection state only by controlling the discharge capacity of the pump). . Conversely, when a common pump is used for each of the nozzles 61 and 62, for example, the base end side of each of the nozzles 61 and 62 may be connected to each other as a common pipe. When this pump is used in common, a flow control valve is connected to each of the branch pipes that are individually provided for each of the nozzles 61 and 62, so that the ejection state of the ejection liquid from the central nozzle 61 and the peripheral nozzle 62 And the ejection state of the ejection liquid can be individually changed. In particular, when the change of the ejection state from the central nozzle 61 is performed exclusively by changing the discharge capacity of the pump, the flow control valve is provided only on the peripheral nozzle 62 side, and the ejection of the liquid for ejection from the peripheral nozzle 62 is performed by the flow control valve. You can also change the state. In addition, in FIG. 10, a command for changing the discharge capacities of the pumps 64 and 67 and changing the opening of the flow control valves 65 and 68 is provided with a selection means (for example, a switch or the like) for performing the command manually. The controller U may control the pumps 64 and 67 or the flow regulating valves 65 and 68 based on this command.
[0062]
FIG. 14 shows a third embodiment of the present invention. In the present embodiment, the injection nozzle 70 corresponding to the injection nozzle 12A (same for 12B) includes a central nozzle 71 and a peripheral nozzle 72. The peripheral nozzle 72 has an annular shape (annular shape in the embodiment) surrounding the central nozzle 71, and a plurality of injection ports 72 a are opened at substantially equal intervals in the circumferential direction of the central nozzle 71. That is, in the case of the embodiment of FIGS. 12 and 13, the injection nozzle of the peripheral nozzle 62 is formed in an annular shape extending around the entire periphery of the central nozzle 61, whereas in the present embodiment, the peripheral nozzle 72 The outer wall member itself surrounds the entire periphery of the central nozzle 71, but the injection port 72a itself, which is substantially a peripheral nozzle, is spaced in the circumferential direction of the central nozzle 71 in the same manner as shown in FIGS. (A structure in which the outer wall members of the plurality of outlets 72 are shared).
[0063]
FIG. 15 and FIG. 16 show a fourth embodiment of the present invention. This embodiment uses a jet pump to supply a high-pressure, low-flow rate, that is, a low-speed, high-flow rate to the peripheral nozzles, while using a high-pressure, low-flow rate pump as the jetting liquid pump. It was made possible. That is, the pump 64 is used for generating a high-pressure and small flow rate which is inexpensive and small, and the high-pressure and small-flow ejection liquid from the pump 64 is directly supplied to the central nozzle 61 via the pipe 63 as a supply path. You.
[0064]
A branch pipe 66 as a supply path branched from the middle of the pipe 63 is connected to the peripheral nozzle 62. A jet pump 81 is formed in the middle of the branch pipe 66. The jet pump 81 has a small-diameter upstream pipe 82 forming a pump 64 side, that is, an upstream pipe, and a large-diameter downstream pipe 83 forming a peripheral nozzle 62 side, that is, a downstream pipe.
[0065]
The upstream end of the downstream pipe 83 is an enlarged diameter portion 83a that is expanded in a trumpet shape. The downstream end of the upstream pipe 82 is a tapered nozzle portion 82a, and the nozzle portion 82a faces the enlarged diameter portion 83a. A suction port 85 is provided between the two pipes 82 and 83, and the suction port 85 is opened in the jetting liquid stored in the main body housing 1 (the jetting liquid in the main body housing 1). The liquid level of the liquid is set to a height equal to or higher than the suction port 85).
[0066]
The ejection liquid ejected from the pump 64 is ejected from the central nozzle 61 as it is at a high pressure and a small flow rate. On the other hand, the jetting liquid discharged from the pump 64 and having a high flow rate and a small flow rate is converted into a low pressure and high flow rate by the jet pump 81 and is jetted from the peripheral nozzle 62. That is, when the ejection liquid flows from the upstream pipe 82 to the downstream pipe 83, the surrounding ejection liquid is sucked from the suction port 85, and the ejection liquid flowing through the downstream pipe 83 flows at a low pressure and a large flow rate. It is said. Since the flow of the low pressure and large flow rate is a low speed, the ejection liquid ejected from the peripheral nozzle 62 is in a preferable state for noise reduction.
[0067]
FIG. 17 shows a fifth embodiment of the present invention. In the present embodiment, a case is shown in which the jet pump 81 shown in FIGS. 15 and 16 is configured in the immediate vicinity of the peripheral nozzle 62 (close to the injection port 62a), and the operation is the same as that in FIGS. Therefore, further description is omitted. Of course, also in the present embodiment, the suction port 85 is set at a position lower than the liquid level of the ejection liquid stored in the main body housing 1.
[0068]
Although the embodiments have been described above, the present invention is not limited to this, and includes, for example, the following cases. The liquid type massage device, particularly the main body housing 1, is not limited to the bed type, but may be of an appropriate type such as a chair type. The driving of the traveling vehicle 5, that is, the injection nozzle 12, can adopt an appropriate method such as a method using a threaded bar and a nut screwed thereto, instead of a chain.
[0069]
The number of the injection nozzles 12A and 12B can be set arbitrarily. In addition, assuming that the traveling carriage 5 is not provided, the injection nozzles 12A and 12B may not have a large relative displacement with respect to the main body housing 1 (injection nozzle fixed type; Whether to slightly displace or not can be arbitrarily selected).
[0070]
All three modes among the first mode, the second mode, and the third mode may not be selectable but only two arbitrary modes may be selectable. That is, a selection between the first mode and the second mode, a selection between the first mode and the third mode, and a selection between the second mode and the third mode may be made. . In addition, it is also possible to set only the first mode, only the second mode, or only the third mode.
[0071]
When the auxiliary tank 22 is provided outside (outside) the main body housing 1, the arrangement position is limited to the side of the main body housing (the side in the longitudinal direction and the side in the width direction of the main body housing 1). Instead, the auxiliary tank 22 may be disposed below the main housing 1 (in this case, it is desirable to make the auxiliary tank 22 as thin as possible in the vertical direction so as not to increase the height of the entire apparatus). Further, the auxiliary tank 22 can be disposed in the main body housing 1, particularly, at the bottom of the main body housing 1 corresponding to the storage section 3 (in this case, between the main body housing 1 and the auxiliary tank 22). The pump 24 for supplying and discharging the liquid for ejection can be disposed inside the main body housing 1, but is preferably provided outside the main body housing 1). In addition, if the auxiliary tank 22 is arranged in a form added to the outside of the frame F, the device of the present invention can be easily configured using an existing liquid massage device. If the central nozzle 18A (18B) and the peripheral nozzles 19A (19B) are formed in one nozzle member as in the embodiment shown in FIGS. 8 and 9, the structure of this nozzle portion is formed. Becomes extremely simple as a whole.
[0072]
Only one of the switch S1 for selecting the mode and the switch S4 for instructing the liquid level L to be changed continuously may be provided. When both switches S1 and S4 are provided, the command of one of the switches may be prioritized. For example, when the command of the switch S4 is prioritized, the liquid level L is changed in accordance with the operation of the switch S4, prior to the selection by the mode switch S1. When the switch S1 is prioritized, only a slight adjustment of the liquid level L by the switch S4 can be performed within the range of the liquid level L allowed in the mode selected by the switch S1.
[0073]
The first mode (FIG. 2) is the most preferable setting of the liquid level L from the viewpoint of the balance between the stimulating effect and the noise reduction. The position can be about 6 cm above the upper surfaces of the nozzles 12A and 12B and about 4 cm below the support sheet 2 (of course, the present invention is not limited to such setting of the liquid level L). . In any of the examples of FIGS. 15 to 17, the pump for pumping the ejection liquid may be shared by the central nozzle 61 and the peripheral nozzle 62 or may be independently provided for each of the nozzles 61 and 62. It can also be provided. The purpose of the present invention is not limited to what is explicitly stated, but also implicitly includes providing what is substantially preferred or expressed as an advantage. Further, the present invention can be understood as a method of ejecting the ejection liquid associated with the ejection mode of the central nozzle and the peripheral nozzle.
[Brief description of the drawings]
FIG. 1 is a plan view showing an embodiment of the present invention.
FIG. 2 is a side sectional view showing an embodiment of the present invention, showing a state of a first mode.
FIG. 3 is a sectional view of a main part showing details of a support sheet.
FIG. 4 is a partial plan view showing a first member having a large number of eyes in a support sheet.
FIG. 5 is a simplified system diagram showing a path of a liquid for ejection.
FIG. 6 is a view showing a second mode and corresponding to FIG. 2;
FIG. 7 is a view showing a third mode and corresponding to FIG. 2;
FIG. 8 is a sectional view showing the vicinity of an injection nozzle in detail.
FIG. 9 is a plan view showing a positional relationship between an ejection nozzle and a drum holding the ejection nozzle.
FIG. 10 is a block diagram showing an example of a control system according to the present invention.
FIG. 11 is a flowchart illustrating a control example of the present invention.
FIG. 12 is a side sectional view of a main part showing a second embodiment of the present invention.
13 is a cross-sectional view corresponding to line X13-X13 in FIG.
FIG. 14 shows the third embodiment of the present invention, and is a plan view of an injection nozzle viewed from the injection port side.
FIG. 15 is a main part system diagram showing a fourth embodiment of the present invention.
FIG. 16 is an enlarged sectional view of a main part of FIG. 15;
FIG. 17 is a main part system diagram showing a fifth embodiment of the present invention.
[Explanation of symbols]
M: User F: Frame L: Liquid level (free surface)
CB: control box 1: body housing 2: support sheet 2A: first member 2B: second member 5: traveling vehicle 7: drive chain 12A: injection nozzle (first embodiment)
12B: injection nozzle (first embodiment)
13: Pump (for pumping liquid for injection)
16: Flow control valve (for adjusting injection amount)
22: Auxiliary tank 24: Pump (for moving ejection liquid-supply / discharge means)
18A, 18B: central nozzle (first embodiment)
19A, 19B: peripheral nozzle (first embodiment)
60: injection nozzle (second embodiment)
61: central nozzle (second embodiment)
62: Peripheral nozzle (second embodiment)
62a: Spout (second embodiment)
64, 67: pump 65, 68: flow control valve 70: injection nozzle (third embodiment)
71: central nozzle (third embodiment)
72: peripheral nozzle (third embodiment)
72a: injection port (third embodiment)
81: Jet pump U: Controller (control means)
S1: Mode selection switch (selection means)
S4: Liquid level command switch (for continuous variable-command means)
S5: Liquid level sensor (liquid level detecting means)

Claims (16)

A main body housing having an upper opening, a support sheet covering the upper opening of the main body housing, and a jetting liquid disposed in the main body housing and jetting from the main body housing toward a lower surface of the support sheet. And a liquid level of the liquid for jetting in the main body housing is set at a height position having a free surface so that an air layer is interposed between the main body housing and the support sheet. Liquid massage device
The ejection nozzle has a central nozzle and a peripheral nozzle that ejects an ejection liquid from around the central nozzle,
The flow rate of the ejection liquid ejected from the peripheral nozzle is set to be smaller than the flow rate of the ejection liquid ejected from the central nozzle,
A liquid massage device, characterized in that: In claim 1,
A liquid massage device, wherein the peripheral nozzle is constituted by a plurality of nozzles arranged at substantially equal intervals in a circumferential direction of the central nozzle. In claim 1,
A liquid massaging device, wherein an ejection port of the ejection liquid in the peripheral nozzle is set in an annular shape extending over the entire circumferential length of the central nozzle. In any one of claims 1 to 3,
Injection mode selection means for manually selecting one of the first and second injection modes with respect to the execution of injection of the central nozzle and the peripheral nozzle, and the stop of injection,
An ejection mode switching unit that switches an ejection state of the ejection liquid from the central nozzle and the peripheral nozzle so that the ejection mode is selected by the ejection mode selection unit;
Has,
In the first ejection mode, the ejection nozzle is set to eject the ejection liquid from both the central nozzle and the peripheral nozzle,
In the second ejection mode, it is set so as to eject the ejection liquid only from the central nozzle among the central nozzle and the peripheral nozzle,
A liquid massage device, characterized in that: In any one of claims 1 to 3,
A pump that pumps up the liquid for ejection in the main body housing and supplies the liquid for ejection to the ejection nozzle,
The pump is also used for the central nozzle and the peripheral nozzle,
A liquid massage device, characterized in that: In any one of claims 1 to 3,
A first pump for pumping the liquid for ejection in the main body housing and supplying the liquid for ejection to the central nozzle;
A second pump that is provided separately from the first pump and pumps up the liquid for ejection in the main body housing and supplies the liquid for ejection to the peripheral nozzle;
A liquid massage device comprising: In any one of claims 1 to 3,
A liquid massaging device, further comprising an injection amount ratio changing means for changing a ratio of the injection amount from the central nozzle and the peripheral nozzle. In any one of claims 1 to 3,
A liquid massaging device, further comprising an injection speed ratio changing means for changing the ratio of the injection speed from the central nozzle and the peripheral nozzle. In any one of claims 1 to 8,
The liquid level of the ejection liquid stored in the main body housing is set so as to be located below the ejection nozzle, and the ejection liquid ejected from the ejection nozzle is stored in the body housing. A liquid massaging device, wherein said liquid massaging device reaches said support sheet without passing through said jetting liquid. In any one of claims 1 to 8,
The liquid level of the ejection liquid stored in the main body housing is set so as to be located above the ejection nozzle, and the ejection liquid ejected from the ejection nozzle is stored in the body housing. A liquid massaging device, wherein the liquid massaging device reaches the support sheet after passing through the jetting liquid once. In claim 10,
The liquid level of the jetting liquid in the main body housing is over the entire surface of the support sheet in a state where a center portion of the support sheet is partially bent downward by a user lying on the support sheet. Is set at a position lower than the support sheet,
A liquid massage device, characterized in that: In claim 10,
The liquid level of the jetting liquid in the main body housing is bent downward in the state in which the center part of the support sheet is partially bent downward by a user lying on the support sheet. The jetting liquid comes into contact with the salient portion, and the periphery of the downwardly bent portion is set at a height position so as to have a free surface without contacting the support sheet.
A liquid massage device, characterized in that: In any one of claims 1 to 8,
Liquid level adjusting means for changing the liquid level of the injection liquid stored in the main body housing between a position higher than the injection nozzle and a position lower than the injection nozzle,
In accordance with the change in the liquid level of the injection liquid by the liquid level adjusting means, the liquid level of the injection liquid is higher than the injection nozzle, and the injection liquid injected from the injection nozzle is once in the main body housing. A state in which the liquid reaches the support sheet after passing through the liquid for ejection, and a state in which the liquid level of the liquid for ejection is lower than that of the ejection nozzle, and the ejection liquid ejected from the ejection nozzle is ejected from the main body housing. And a state in which the support sheet is reached without passing through the liquid for use,
A liquid massage device, characterized in that: In claim 13,
The liquid level adjusting means,
An auxiliary tank for storing the jetting liquid,
Supply and discharge means for performing supply and discharge of the ejection liquid between the main body housing and the auxiliary tank,
Control means for receiving the command from the selection means and controlling the supply / discharge means so that the liquid level of the ejection liquid in the main body housing is at a height position corresponding to the mode selected by the selection means;
A liquid massage device comprising: In any one of claims 1 to 14,
A jet pump configured to suck a jetting liquid existing around the supply path into a supply path of the jetting liquid to the peripheral nozzle to convert a high-pressure small flow into a low-pressure large flow. A liquid massage device characterized by the above-mentioned. In any one of claims 1 to 15,
The support sheet has a strength capable of supporting the weight of the user and has a mesh-shaped first member having a large number of eyes for allowing the ejection liquid to pass therethrough. And a second member made of an elastic member for securing.
A liquid massage device, characterized in that:

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