The present application relates to jet massage systems used in tubs, such as bathtubs, hot tubs, whirlpools and similar basins, and more particularly to a jet for the injection of fluids into the liquid of such tubs to procure a massaging effect for the occupant of the tub.
Tubs are well known for their primary use, namely a washroom installation in which a user person washes/bathes. Tubs have, however, evolved to add pleasure and comfort to practicality, and are found in many forms, such as bathtubs, spas and whirlpools. For instance, tubs are now provided with air-jet systems and whirlpool systems.
Massage systems of various configurations have been provided to inject fluids, such as air or water, into the liquid of the tub, so as to procure a massaging effect for the occupant of the tub. One known massage system combines the injection of air and water to provide a different sensorial experience to the bather. The known massage system comprises water jets equipped with venturi devices whereby air is sucked by the flow of water directed to the tub. Accordingly, the resulting flow of water in the tub comprises air bubbles, thereby causing a different sensation on the skin of the bather.
In such a massage system, the water jet pressure must be maintained relatively high to induce a suitable sucking effect on the air in the venturi device. Therefore, the presence of air bubbles is limited in the flux of fluid being injected by the jets.
It is therefore an aim of the present application to provide a novel fluid massage system and method that addresses issues associated with the prior art.
Therefore, in accordance with the present application, there is provided a method for injecting fluids in the water of a tub, comprising: providing a jet having a gas injector and a liquid injector sharing a common outlet; supplying pressurized gas to the gas injector of the jet; and simultaneously supplying pressurized liquid to the liquid injector of the jet; whereby gas and liquid exit the common nozzle concurrently.
Further in accordance with the present application, there is provided a method for injecting fluids in the water of a tub, comprising: providing a jet having a gas injector and a liquid injector, with the gas injector and the liquid injector being arranged such that gas and liquid flux exiting the injectors converge; supplying pressurized gas to the gas injector of the jet; and simultaneously supplying pressurized liquid to the liquid injector of the jet; whereby gas and liquid exit the jet concurrently.
Referring to the drawings and more particularly to
The fluid jet 10 of
The water injector 12 is the interface between a water piping system and the tub. Therefore, water passes through the water injector 12 to be injected in the tub.
The wall fitting 13 is used to secure the fluid jet 10 to the tub. Water and air exit the fluid jet 10 through the wall fitting 13.
The air injector 14 is the interface between an air pressure system and the tub. Therefore, air passes through the air injector 14 to be injected in the tub.
Referring concurrently to
A downstream end of the tubular body 20 supports the air injector 14, whereas a flange 22 is provided at an upstream end of the body 20. The flange 22 is grooved so as to accommodate a seal 23. When the fluid jet 10 is mounted to the tub, the flange 22 is opposite a hidden surface of the wall of the tub, and concentrically aligned with a hole in the wall. Accordingly, the seal 23 is pressed against the hidden surface of the tub to generally prevent leaks between the flange 22 and the hidden surface of the tub. The tubular body 20 is tapped at its upstream end for threading engagement with the wall fitting 13.
The wall fitting 13 has a flange 30. The flange 30 is positioned inside the tub and is therefore visible to a user of the tub. The nozzle 13 has a flared conduit 31 (conduit body) that passes through the hole in the tub and interconnects with the tubular body 20 of the water injector 12, by threading engagement. Therefore, the area of the wall of the tub about the hole is sandwiched between the flanges 22 and 30. By this configuration, the fluid jet 10 is solidly anchored to the wall of the tub, and can withstand the forces associated with the injection of pressurized fluids in the tub.
Although the conduit 31 is flared in
The air injector 14 has a hollow body, for instance defined by an elbow fitting 40 that is connected to the downstream end of the tubular body 20. The interconnection between the elbow fitting 40 and the tubular body 20 is watertight to prevent leaks, and may result from welding, threading engagement, force-fitting engagement or any other interconnection configuration. The elbow fitting 40 has a hose barb 41 by which the air injector 14 is connected to pressurized air tubing or hose.
A nozzle 42 is connected to the elbow fitting 40 and is concentrically positioned within the tubular body 20. It is observed that the outlet end 43 of the nozzle 42 extends downstream of the lateral inlet 21 of the tubular body 20. Therefore, an annular passage may be defined between the wall fitting 13 and the nozzle 42, and water passes through this annular passage to be injected in the tub. Other passage sections are considered as well.
In order to generally prevent water infiltration in the pressurized air system, a unidirectional flow mechanism, such as a check valve, may be provided with the nozzle 42. In the embodiment of
Referring to
The massage system also features a pump W1 having a return pipe W2 connected to the tub T so as to receive water from the tub T. A main water pipe W3 is connected to the outlet of the pump W1, and diverges into a plurality of pipes W4 each connected to one of the fluid jets 10. Therefore, water is injected into the tub T through the fluid jets 10.
Referring to
As the venturi effect is not required in the injection of air, the water pump W1 (
Numerous configurations are considered for the fluid jet to operate in injecting air and water in the manner described above. Accordingly, like elements will bear like reference numerals in
Referring concurrently to
The flange 52 is spaced from the throat 51, so as to define a volume for a flared conduit 53 for the wall fitting 13. The wall fitting 13 has a threaded collar 54 that engages with tapping in the water injector 12, whereby the fluid jet 50 is secured to the tub by the flange 52 and the wall fitting 13.
An injector tube 55 has an outlet that is generally flush with the throat 51, to ensure the mix of the air and water flux, within the flared conduit 53. The injector tube 55 is shorter than the nozzle 42 of the fluid jet 10 (
Finally, an alternative to a hose bard is illustrated in the fluid jet 50. A straight inlet 56 is provided for connection of a tubing.
Referring to
The water injector 12 and the wall fitting 13 are combined to define a cylindrical conduit 62 as opposed to the flared conduits of the fluid jets 10 and 50 of the previous figures. The wall fitting 13 has a threaded collar 63 for threading engagement with the water injector 12.
The wall fitting 13 has a set of arms 64 converging centrally in the conduit 62 so as to support an injector tube 65. The injector tube 65 is partially accommodated in the air injector 14. The injector tube 65 has a central disk 66. The disk 66 is provided to define a generally annular outlet for the air. Therefore, both the water and air flux exit the fluid jet 60 through annular outlets. A seal 67 is provided between the injector tube 65 and an inner surface of the air injector 14 to prevent air leaks therethrough.
Referring to
The water injector 12 and the wall fitting 13 are combined to define a cylindrical conduit 72 as opposed to the flared conduits of the fluid jets 10 and 50 of the previous figures. The wall fitting 13 has a threaded collar 73 for threading engagement with the water injector 12.
The wall fitting 13 has a set of arms 74 converging centrally in the conduit 72 so as to support an injector tube 75. The injector tube 65 partially covers the air injector 14. The injector tube 65 has a central disk 76. The disk 76 is provided to define a generally annular outlet for the air. Therefore, both the water and air flux exit the fluid jet 70 through annular outlets. A seal 77 is provided between the injector tube 75 and an outer surface of the air injector 14 to prevent air leaks therethrough.
A check valve 78 has a piston biased in a normally closed position by a spring, to generally prevent water infiltration in the air conduits of the massage system.
Referring to
The fluid jet 100 also has a body 20′ incorporating the air injector 14, through an inlet 41′. In the previous embodiments, the water injector 12 and air injector 14 were separate pieces, whereas they are integral in the fluid jet 100. Both configurations and other configurations are supported by the present disclosure.
A cap 103 is releasably secured to the wall fitting 13, and covers the outlet of the fluid jet 100. As will be described hereinafter, the cap 103 has openings to allow water and air mixture to be projected out of the fluid jet 100.
Referring to
Referring to
At the end of the flared head 120B, the channels 121 are separated by ribs 123. The end of the ribs 123 come into contact against the cap 103 as shown in
Referring to
Referring to
Referring to
The fluid jets 50, 60 and 70 may be used in the manner described for the fluid jet 10. Moreover, different configurations are considered for the mixture of the flux out of the jets. For instance, different outlets may be provided for a same jet, with the water and air flux directed toward one another to produce the micro-bubbles.
Referring to
It is pointed out that the fluid jet 10 may be installed without the fitting 13. For instance, the water injector 12 may be connected directly to the tub wall. For instance, the water injector 12 may be connected to the tub wall in a similar fashion as the fluid jet described in U.S. Patent Application Publication No. 2002/0062520, by Castellote.
This patent application claims priority on U.S. Provisional Patent Applications No. 61/080,359, filed on Jul. 14, 2008, and No. 61/174,603, filed on May 1, 2009.
Number | Date | Country | |
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61080359 | Jul 2008 | US | |
61174603 | May 2009 | US |