The present invention relates to a toilet and specifically to a rimless toilet.
Various types of toilets have been available in the art for some time. An example of one conventional toilet is shown in
Despite the popularity and advantages of conventional toilets there are a number of significant drawbacks with toilets incorporating a rim. For example, because of the profile of conventional toilet rims, they provide a breeding ground for germs and bacteria and also a catchment area for waste matter. The profile of the rim can also make it difficult to effectively clean around the rim. Furthermore, parts of the underside of the rim are difficult to inspect which means parts of the toilet are often left un-cleaned for extended periods of time or indefinitely. This build-up of germs and matter under or around the rim is unhygienic which is of particular concern in public toilets, hospitals and so forth. Toilets with modified rims which attempt to address some of these problems are known in the art, see for example GB 2,431,937.
However, the prior art designs fail to provide a toilet arrangement which offers an efficient and effective flushing action in combination with a toilet which substantially eliminates the possibility of germs and/or bacteria building up or being cultured in or around the rim. There is therefore a need for a toilet which overcomes these problems and for a toilet with improved cleanliness. The present invention has been made, at least in part, in consideration of these problems and in view of the drawbacks of conventional toilets.
According to a first aspect there is provided a toilet comprising a rimless toilet bowl and a pair of water inlets arranged in use to direct substantially all of the water flowing into the toilet in substantially horizontally opposing directions around the inner surface of the toilet bowl.
In accordance with the invention, substantially all of the flushing water received into the toilet is only directed in opposing and substantially horizontal directions by means of the two water inlets i.e. water is not directed from the inlet directly down and into the bowl as is the case in conventional toilets. In the prior art substantially all of the water received in the bowl is directed towards the U-bend to create the necessary flushing action as illustrated by the arrows in
Directing substantially all of the water in horizontally opposing directions has not previously been considered in the art because it is convention to create a necessary flushing action by directing a large volume of water directly down towards the U-bend of the toilet bowl. It will be appreciated that the term substantially all is intended to refer to almost all of the water entering the toilet but that some may remain in the toilet and/or evaporate or the like.
The term ‘rimless’ is intended to refer herein to a toilet bowl which is void of an overhanging surface extending around the upper surface of the rim. By removing the overhanging surface the visibility of the inside of the toilet bowl is substantially improved. In addition access to the bowl is improved for cleaning.
Water may be introduced into the bowl by means of a water distribution arrangement which may for example protrude from the inner wall of the bowl at the rear of the toilet bowl. Alternatively water may be communicated into the bowl from a pair of recesses formed in the wall of the toilet bowl and arranged in use to direct water horizontally as described above. Forming the inlets into recesses in the toilet wall further removes edges around which germs and bacteria may grow which might be associated with a protruding water inlet.
To maximise the flushing and cleaning action the flushing water may be introduced into the bowl close to the upper edge of the rimless bowl. Introducing the water at the top of the bowl maximises the area of the bowl over which the flushing water is arrange to flow and minimises the area of the bowl which is not cleaned.
Each of the two opposing water inlets may be formed of a single orifice arranged to communicate water into the bowl. Alternatively, each orifice may be formed of a plurality of apertures each arranged to communicate water into the bowl.
It will be appreciated that the term ‘substantially horizontally’ used herein is not limited to a purely horizontal flow of water but to a generally horizontal flow such that, in use, water is directed around the inner surface of the bowl to meet and collide at the opposing side of the bowl.
So as to advantageously communicate water all around the bowl, the toilet bowl may be provided with a pair of circumferentially extending water guides or ledges each having a first end adjacent to one of the flushing water inlets and arranged in use to guide or communicate the flushing water in the substantially horizontally opposing directions around the inner circumference of the toilet bowl.
In use water issues from the respective inlets and is directed along the top of the respective water guide and around the bowl. Each guide advantageously prevents the water from flowing in a manner as found in conventional toilets i.e. directly down towards the U-bend. In use the guides communicate water from the respective inlets and around the inner surface of the bowl so as to collide on the opposite side of the toilet bowl and to create a ‘plume’ of water which in turn flows into the U-bend. The arrangement of the guides advantageously provides a surface on which water may be communicated. In addition the guides are void of any concealed portions because there are no overhanging surfaces or rim and can be easily and conveniently inspected for cleanliness. As described above the guide surfaces are also advantageously convenient and easy to clean because they are readily accessible to a cleaner.
It will be recognised that in the prior art the inner surface of the toilet cannot be seen easily. Even in the document referenced above a rim is provided which prevents the inner surface of the bowl being inspected quickly and easily.
Viewed from another aspect there is provided a toilet comprising a rimless toilet bowl and a water distribution arrangement arranged to communicate water into the bowl, the bowl further comprising two generally horizontal water guides disposed on the inner surface of said bowl and arranged to receive in use water from a respective flushing water inlet and to communicate water along an upper surface thereof.
In effect the guides act as a surface along which water is communicated by virtue of the flow rate of the water passing into the bowl. Each guide or ledge may advantageously be formed as a surface protruding from the inner surface of the toilet bowl i.e. integral with the bowl inner surface. Guides may therefore be conveniently formed using conventional manufacturing techniques.
Each guide/ledge is formed of a proximal end adjacent to a respective inlet and a distal end located at some distance around the circumference of the bowl. In order to ensure the entire surface of the bowl is cleaned the ledge may extend around the entire circumference of the bowl so as to meet at the front of the toilet bowl.
The guides or ledges may be provided with any suitable profile or configuration comprising a surface on which the water is supported and/or directed as it flows around the bowl. For example, the guides may be in the form of a substantially horizontal surface on which the water is supported and along which the water flows. As discussed above, such a surface advantageously supports the flow of water around the bowl and additionally allows for convenient inspection of the toilet (for cleanliness) and furthermore allows the toilet inner surface to be easily cleaned.
All or a portion of each guide/ledge may be angled relative to the inner surface of the bowl to support water on the ledge for an extended period of time as it flows around the bowl. The guides may be adapted e.g. angled along all or a portion of their lengths to allow a portion of the water flowing along each guide to flow over the inner edge thereof so as to flow over the inner wall of the toilet bowl beneath the guide. In effect a portion of the water directed around the inside of the bowl is permitted to flow from the guide in a generally vertical direction down the inside surface of the bowl so as to rinse the inner surface of the bowl. It will be recognised that the water flowing from the guide in this fashion will have a generally horizontal component of movement as it flows from the edge of the guide and so the water will circulate around the bowl as it flows from the guide. This advantageously rinses the inner surface of the bowl as it flows around and down the bowl surface. This may be achieved by providing all or part of the ledges with a small angle away from the horizontal such that a portion of the water flows over the inner surface thereof. The ledges may for example be provided with an angle of between 1 and 15 degrees to the horizontal.
Alternatively, or additionally, this may be achieved by providing each ledge with a first width proximate a respective inlet and a second smaller width at a distal end of the ledge. Advantageously, the guides may be arranged to taper from the proximate end to the distal end so that the supporting surface along which the water flows narrows around the circumference of the toilet bowl. The distal ends of the guides may meet at a point on the circumference of the toilet bowl substantially opposite the water distribution apparatus to ensure that water is communicated around the entire circumference of the bowl.
To optimise the cleaning of the bowl and the flushing action for a toilet with a standard volume of flushing water the guides may be provided with a first end proximate the respective flushing water inlet having a guide width of between 40 mm and 65 mm, more preferably between 50 mm and 60 mm and most preferably 58 mm. The distal end of each guide may have a width of between 1 mm and 8 mm, more preferably 2 mm and 5 mm and most preferably 3 mm. It has been established that the most preferred values optimise the creation of the flushing plume whilst optimising the cleaning action of the bowl. The plume creation may also be optimised by making the inside of the bowl generally symmetrical.
Depending on the size of the bowl, the taper may alternatively be arranged such that the guide terminates a part way around the circumference of the rim i.e. the guides may taper into the bowl wall. It will be recognised that in such arrangement an increasing portion of the water flowing along each guide will be permitted to flow into the bowl.
The guides may advantageously be arranged so as to direct the two opposing flows towards each other so as to collide at a position diagonally opposite the inlet apparatus i.e. at the front of the bowl. It will be appreciated that the elevation of the collision point (relative to the height of the bowl from the floor) of the two flows is dependent on the specific configuration of the guides and the flow rate of water. The configuration of the guides is selected such that a sufficient proportion of water collides at the front of the bowl and is directed, by virtue of the momentum of water, in a general direction back across the bowl towards the back of the toilet. A ‘collision point’ is in effect created at which the two streams meet and which creates a turbulent region of water which rebounds across the toilet bowl.
At the portion of each guide proximate the respective flushing water inlet the inlet may, as described above, be formed in a recess in the inner wall of the bowl. The recess is in effect formed of a lower surface defined by the tapered guide and an upper opposing surface which acts as a cover to prevent any spray passing from the respective water inlets over the top of the bowl as the water passes at its highest flow rate onto the guides. Advantageously this surface may taper into the wall of the bowl to maximise access and visibility of the inner surface of the bowl.
The inner surface of the toilet bowl may also be provided with a further small orifice which is arranged in use to allow a small quantity of water to flow over the portion of the toilet bowl between the two opposing water inlets. This ensures that the entire surface of the toilet bowl receives a flow of water to provide a complete bowl surface rinse. Only a small proportion of the flushing water received by the toilet need flow over this portion of the bowl. For example the two opposing inlets may be configured to receive in excess of 90% of the water received into the toilet (45% each) with the remaining quantity passing to the rinse inlet disposed above and between the two opposing inlets. The rinse inlet may be arranged at any suitable height relative to the upper surface of the toilet bowl but is preferably arranged close to the upper surface to maximise the area of the bowl over which water flows
According to another aspect of an invention disclosed herein, there is provided a system comprising a toilet including a rimless toilet bowl; a water reservoir connected to said toilet for supplying flushing water to said toilet bowl; and a water distribution arrangement adjacent an inner wall of said bowl arranged to received said flushing water and comprising two bowl inlets arranged in use to direct substantially all of said water in horizontally opposing directions around the inner circumference of the toilet bowl.
According to another aspect of an invention described herein, there is provided a toilet comprising a rimless toilet bowl and a pair of opposing water inlets arranged in use to direct water flowing into the toilet in substantially horizontally opposing directions around the inner surface of the toilet bowl, and further comprising a third water inlet disposed above and between said pair of opposing water inlets and arranged in use to direct a small quantity of water into the bowl at a position above and between the inlets.
According to yet another aspect there is provided a method for flushing a toilet, said method comprising the steps of providing flushing water to a rimless toilet bowl via a water distribution apparatus comprising two inlets at an inner wall of said toilet bowl; and directing substantially all of said flushing water in first and second substantially horizontally opposing directions around the inner circumference of said toilet bowl so as to collide together at a portion of said inner wall of said bowl located opposite said water distribution apparatus.
It will be appreciated that the various features of the apparatus and method disclosed and described herein may be advantageously used in any suitable or convenient combination.
The invention will now be described, by way of example only, with reference to the accompanying figures in which:
While the invention is susceptible to various modifications and alternative forms, specific embodiments are shown by way of example in the drawings and are herein described in detail. It should be understood, however, that drawings and detailed description thereto are not intended to limit the invention to the particular form disclosed, but on the contrary, the invention is to cover all modifications, equivalents and alternatives falling within the spirit and scope of the present invention as defined by the appended claims.
Referring to the drawings, the toilet according to the invention comprises a rimless toilet bowl 1 and a water reservoir (not shown) for supplying flushing water to said toilet bowl. As shown in
As shown in
In alternative embodiments the outlets 5 and 6 may be formed of a plurality of small apertures.
The toilet bowl includes a pair of water guides adjacent to the water distribution apparatus 3. The guides are first and second symmetrical guiding ledges 7 and 8. Alternatively a single ledge could also be used.
Referring again to
An example of optimal tapering of the ledges 7 and 8 is shown in
In alternative embodiments, the distal ends may only extend along a portion of the circumference of the inner wall and hence not meet at a common point. The distance the ledge extends along the circumference may vary depending on the requirements of the system and the dimensions of the toilet bowl.
The water distribution apparatus may include a portion 11 disposed between the ledges 7 and 8 which extends upwardly from the rear inner wall of the bowl. This is illustrated in
As also shown in
Referring again to
It will be recognised that the extent to which the upper guides protrude from the inner wall of the bowl and their respective lengths along the inner surface of the bowl are determined according to the water pressure/flow rate and the angle at which water is directed from the outlets.
In operation water enters a chamber formed within the bowl wall (disposed behind the portion 11) and exits through inlets 5 and 6 into respective channels defined by the lower guides 7 and 8 and upper guides 9 and 10. The largest proportion of water is communicated along the upper surface of the ledges 7 and 8 and around the bowl. It will be recognised that water will flow from these guides down into the bowl. The arrows shown in
In most applications the flow patterns illustrated in
The amount of surface area rinsed may alternatively or additionally be increased by the addition of a pair of mutually opposed recesses or channels located at points 15 and 16 shown in
In use, when the user activates the toilet's flushing mechanism, water is supplied from the reservoir (not shown) to the conduit 4. The water then passes into a chamber disposed behind the portion 11 and through the inlets 5 and 6. The inlets direct substantially all of the water in horizontally opposing directions around the inner circumference of the toilet bowl 1. The guiding ledges 7 and 8 form the other half of a channel to direct the water exiting from the outlets in substantially horizontally opposing directions and prevent water flowing over the top of the toilet over the short portion of the water passage as it first enters the bowl.
When the water passes through the inlets 5 and 6 it forms first and second substantially horizontally opposing water streams travelling in opposite directions around the inner circumference of the toilet bowl, as shown by the arrows in
At least a portion of the opposing streams then collide together at a portion of the inner wall of the bowl located substantially opposite the water distribution apparatus 3. The specific point on the wall where the collision of the streams will occur may vary depending on the pressure applied to the water and the specifications of the toilet bowl.
Upon colliding, the first and second streams form a water plume and are directed back toward the rear portion of the inner wall adjacent the water distribution apparatus 3. When this water collides with the water already sitting in the bottom of the bowl, the impact and volume is sufficient to move the water trapped in the toilet's U-bend and hence, ‘flush’ the toilet.
During trials using various ledge widths and tapers, the dimensions shown in
In embodiments having flushing water inlets with multiple apertures, more than two water streams may be formed in each direction, however the streams will still be directed in substantially horizontally opposing directions around the inner circumference of the toilet bowl and function in the manner as described above.
Whilst a majority of the first and second water streams collide together at the front portion of the inner wall of the bowl located opposite the water distribution apparatus, a portion of the first and second streams also flow over an edge of the water guide to serve the function of rinsing a portion of the inner wall situated below. This is illustrated by the flow arrows in
In an embodiment where the distal ends of the guiding ledges 7 and 8 do not meet, a portion of the first and second stream may flow past the distal end of its corresponding guiding ledge and rinse a portion of the inner wall situated below.
In embodiments including a rinsing aperture 14, the aperture allows a small portion of the flushing water to rinse the area of the rear inner wall below. During testing, with a 4.5 litre flush cycle, approximately 6.5% of the flush water exited the water distribution apparatus via the rinsing aperture 14. The rinsing aperture 14 may also advantageously function as a draining aperture for draining water collected in the chamber of the water distribution apparatus during the flushing cycle. Hence, the amount of standing water left in the system after flushing may be reduced. This may be advantageous because standing water may be a potential breeding ground for germs.
It will be recognised that the various features, aspects and embodiments described and illustrated herein may be used in any convenient combination and constitute part of the inventions.
This is a continuation of International Application No. PCT/GB2008/002986, with an international filing date of Sep. 3, 2008 which claims the benefit of Great Britain Patent Application Number 0717274.5 filed on Sep. 5, 2007, both of which are hereby incorporated by reference in their entirety.
Number | Date | Country | |
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Parent | PCT/GB2008/002986 | Sep 2008 | US |
Child | 13410095 | US |