This invention relates to shower apparatus and a shower head for use with such apparatus.
Typically, showers, for example for domestic use, comprise a shower head connected to a water supply. The supply may be provided specifically for the shower, or alternatively a shared source may be used, for example by connecting pipes to the taps of a bath. The shower head is typically adapted to provide a spray of water. It is known for shower heads to include venturi sections to increase the velocity of the through-flowing water to provide a stronger spray. In addition, some shower heads are adjustable, to change the spray pattern to suit the user's preference. Furthermore, some shower heads enable ambient air in the vicinity of the shower head to be drawn into the shower head to mix with the water flowing through. This may be used to create a foam effect, whereby the water contains small bubbles of air trapped within it. In such devices, the air may be drawn or sucked in by creating a region of low pressure inside the shower head, which may be effected by passing the water through a venturi similar to that described above. As the water velocity increases, the pressure is reduced, so that air may be drawn in in the region of the venturi, for example through gaps in the body of the shower head. Such an arrangement has an incidental effect of reducing the amount of water needed to shower effectively, as the air bubbles entrained in the water increase the volume of fluid flowing out of the shower head. This reduction in water usage is advantageous for two reasons—firstly by reducing the environmental and financial impact of water use, and secondly by reducing the amount of energy needed to heat the water to an acceptable level for a user of the shower. However, while this reduction in the amount of water is advantageous, the reduction is slight.
It is an aim of the present invention to provide shower apparatus which enables the volume of water necessary for an effective shower to be greatly reduced. This aim is achieved by providing shower apparatus by which pressurised air can be blown into the shower head for mixing with the water flow.
It is a further aim of the present invention to provide shower apparatus which permits simple in-situ drying of a user of the shower. This aim is achieved by enabling pressurised air to be blown through the shower head in the absence of water.
Shower apparatus in accordance with the present invention provides a shower experience similar to that of a conventional “power shower”, despite requiring much reduced power and water.
In accordance with a first aspect of the present invention, there is provided shower apparatus as set out in the accompanying claims.
In accordance with a second aspect of the present invention, there is provided a shower head as set out in the accompanying claims.
Apparatus in accordance with the present invention has various benefits and advantages over known systems. These include:
1) The volume of water needed for an effective shower is dramatically reduced. A typical mixer shower requires in the order of 15-20 liters of water per minute, while a shower incorporating the inventive apparatus may only require in the order of 2-5 liters per minute.
2) The total energy required for an effective shower is reduced. This primarily arises because there is less water to be heated. Even when the energy required to supply pressurized, optionally heated air is taken into account, the net energy usage is still reduced. The invention may have a water usage of about 3 liters/minute, compared with a conventional domestic shower's usage of about 15 liters/minute, i.e. about an 80% water saving. Furthermore, an energy saving of about 79% is achievable over the same conventional shower.
This energy saving provides a further advantage in that the electrical power required could be taken from a domestic ring main, rather than having to use a dedicated high current power line which is typically required by existing electric shower units.
3) A reduction in the water pressure needed for operation. The apparatus will work effectively even if the water is simply gravity-fed from immediately above the shower head. An ingoing water flow rate of just 3 liters per minute is sufficient for effective shower operation.
4) Unlike a conventional shower, which has many spray orifices which tend to block in hard water areas, in certain embodiments the inventive apparatus may use a large water pipe (typically about 8 mm diameter) for the shower fluid output.
5) The apparatus may be retrofitted to existing shower system or alternatively integrated into a new system.
6) The apparatus may be used to dry a user immediately after the shower.
7) Mould formation on and in the shower head is reduced.
The invention will now be described, by way of example, with reference to the accompanying drawings, in which:
Part of the apparatus of
The rear of shower head 1 is connected to ducting 5, so that an air flow, shown by the arrows on
A portion of the shower head 1 forms a venturi 8 in the air flow path. This has a convergent region 9 with an internal diameter which decreases in the direction of air flow, a throat region 10 located after the convergent region 9 in the direction of air flow which has a reduced internal diameter which is substantially constant along its length, and a divergent region 11 with an internal diameter which increases in the direction of air flow.
The shower head venturi 8 is shown in more detail in
In the embodiment shown, unlike conventional shower heads, no shower “rose” (i.e. a plate with a pattern of holes or spray orifices formed therein) is used to create a spray. Instead, a satisfactory spray pattern is produced due to the configuration of the divergent region 11.
Secondly, the water inlet pipe 7 opens in, and thus acts to introduce water to, the divergent region 11 of the venturi 8. In the divergent region, the cross-sectional area of the air flow path expands in the direction of air flow. This means that the air pressure in the divergent region 11 is lower than in either the convergent region 9 or throat region 10, where the air flow path cross-sectional area is reducing or constant respectively. Therefore, providing the water inlet pipe opening at the divergent region 11 aids the introduction of water to the air flow path in comparison to the throat or convergent regions. In fact, positioning the water inlet pipe opening at the divergent region acts to suck water out of the pipe. This effect is particularly beneficial in situations where the water pressure is relatively low, for example in gravity-fed water systems.
The apparatus described may operate in three different modes, depending on which of the air and water supplies are selected to supply fluid to the shower head:
1) Air+Water (Normal Shower Operation)
The basic mode of operation is to have both the air 4 and water 3 supplies feeding fluid to the shower head 1. Air is guided under pressure to the shower head 1 through ducting 5. As it is forced through the convergent region 9 of venturi 8, the air's velocity is increased and its pressure reduced. Meanwhile, water enters the base of the shower head 1 from flexible water pipe 2, with sufficient pressure to cause it to flow from the opening of inlet pipe 7. The water is mixed with the high velocity air in the throat 10 of the venturi 8 and kinetic energy is transferred from the air to the water. The water and air exit through the divergent region 11. Here, the air and water slow and expand into a greater area, thus forming a spray of droplets within a lower velocity shower.
2) Air Only (Drying)
In a second mode, the water supply 3 may be switched off by a user, so that only air is passed through the shower head 1. If a heating means is provided, the air may be heated to a suitable temperature before exiting the shower head 1. This enables the user to be dried by the air flow before stepping out of the shower. An additional benefit if that the inside of the shower head is dried, reducing the formation of mould.
3) Water Only
In the third mode of operation, the water supply is switched on, but the air supply is turned off. This mode may be used where a greater volume of water is needed, for example if the user is using the shower to fill a bath.
The above described apparatus is exemplary only, and various possibilities and alternatives are possible within the scope of the claims.
The water supply may for example be provided at a higher level than the shower head, so that the water is gravity-fed to the shower head.
The air supply may be used to recirculate air from the shower area. The air and water supplies may be combined into a single unit. Controls to effect switching of the air and/or water supplies, or to control the heating means, may be provided on the shower head itself with the inclusion of appropriate electronics.
The shower head may be fixed to a wall, in which case any ducting would be hidden within the wall. The air supply may be housed with a cupboard or roof space for example.
The water could be introduced at any region of the air flow path including and upstream of the divergent region of the venturi. Furthermore, the dimensions and angles of the venturi may be adjusted to alter the spray pattern, volume of water used and efficiency of the shower head.
In addition, the water inlet pipe 7 could have different forms, for example at least one orifice, e.g. eight, may be provided around the perimeter of the pipe so that the water comes out laterally, before being propelled forward by the air flow.
Number | Date | Country | Kind |
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0721477.8 | Nov 2007 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2008/051019 | 10/30/2008 | WO | 00 | 4/30/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2009/056887 | 5/7/2009 | WO | A |
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