EP3412840A1 - Water closet - Google Patents

Abstract

The invention relates to a toilet with a toilet bowl (1), which has a certain, designed to a rotating flow of the rinse water out bowl inner shape, wherein an addition to the prior art provided second flow path part (7) or a separate second flow path an improvement in terms avoiding over-sloshing and thus, especially with regard to the avoidance of undercuts in the inner bowl shape leads to relief.

Description

The present invention relates to a water closet, hereinafter referred to as WC.

WCs with a toilet bowl, a Spülwasserzufuhr for this and a connected usually via a siphon wastewater drain are common and known. In recent years, especially additional functions such as shower facilities, odor evacuation and the like have become the subject of technical development.

WCs have a toilet body, which in particular comprises an upwardly open mold, namely the toilet bowl, and normally, although not necessarily, is made of ceramic. In the ceramic part of Klosettkörpers or in add-on parts or behind or under covers on the ceramic body further technical devices may be provided.

A conventional toilet body has over or at the upper inner edge of the toilet bowl a so-called flushing edge, namely a circulating flushing water channel with downwardly facing inlet openings for the inflow of rinse water into the toilet bowl; so it works like a ring-shaped shower, which concerns the feeding of the rinse water into the bowl. In addition, toilets are known with a rotating flushing water flow in the toilet bowl, which provide by a largely tangential entrance of the rinse water into the bowl for a vortex-like flow therein before the discharge of the rinse water through the siphon and the waste water drain.

The prior art is on the EP patent 2 604 761 B1 referred to the same owner, which relates to an asymmetric and thereby a rotating movement of the rinse water generating or supporting toilet bowl inner shape. Thus, with relatively small amounts of flushing water, good rinsing results reached. Moreover, it has been found that this toilet bowl works very quietly.

The present invention has for its object to provide a further improved toilet bowl. This object is achieved by claim 1, which will be explained in more detail below as well as various preferred embodiments. Preferred embodiments of the device according to the invention and its use are specified in the dependent claims. The features contained therein and also the disclosure of the following description are to be understood in principle with regard to both categories of invention, without any explicit distinction between them.

In order to be able to describe the inner shape of the toilet bowl and the Spülwasserströmung understandable, it is assumed by a coordinate system defined in plan view of the bowl opening. It is assumed that a circular or oval (in the sense of elongated distorted roundish) bowl opening form. The bowl opening shape typically resembles the approximate inner bowl shape, at least in its upper region. Therefore, it makes sense to set as the longitudinal axis of the longest internal dimension through the bowl opening form and as a transverse axis a perpendicular bisector. For typical toilet bowls, this means that in a typical sitting position on the toilet, the user is looking in the direction of the longitudinal axis and his shoulders are in the direction of the transverse axis. When mounted on a wall, the longitudinal axis is then typically perpendicular to the wall and the transverse axis runs parallel thereto.

In conjunction with numerous experiments and investigations by the inventors, two important core ideas have emerged. First, while the toilet bowl with the highly rotating purge flow described in the cited patent is very advantageous in terms of rinsing results, noise, and water saving potential, other manufacturers also make use of other rotating bowl rinse WC bowls. In contrast to conventional toilet bowls with classic Spülrand, so a highly distributed and shower-like flushing, but there is a risk with rotating Spülwasserströmungen generally that the rinse water can slosh over the upper edge of the bowl at too high a speed. This danger is in addition to the concrete design of the bowl interior shape and the resulting flow path also depends on how much inward overhanging the upper edge of the inner shape of the toilet bowl is designed. For example, the show Figures 5 and 6 of the cited patent, that despite avoiding a classic flushing rim, the bowl shape overhangs inwardly at this upper edge.

Secondly, such overhanging forms form undercuts which are disadvantageous in terms of production technology. However, less overhanging or even the avoidance of undercuts are advantageous in terms of production technology. This, however, again results in an increased risk of the described overspill.

It has also been found that due to their kinetic energy, the flushing water flow introduced approximately tangentially to the bowl inner mold can be guided relatively well on a steep wall of the bowl inner mold for a limited distance downstream of the inlet opening, in particular at a relatively pronounced concave location such as that through the bowl Longitudinal axis connected ends of an oval bowl shape. But then it tends increasingly to fall off under the influence of gravity. If such a sloping part of the flow then encounters the less inclined flow path described in the cited patent, a quasi-upflowing flow form may occur. In other words, such a sloping flow part is quasi reflected back upwards. Especially in such situations, there is a particular risk of spewing out, especially if the upper edge of the bowl inner mold is not formed clearly undercut.

It should be briefly noted in this context that a flow path in the sense of this representation is understood as a running in the inner wall of the toilet bowl web-like surface, the outward, ie in the transition to the next wall leading upwards, delimited by a concave edge and delimited by a convex edge to the inside, ie to the wall leading farther downwards and towards the outflow. An edge is determined by a particularly strong curvature in a vertical section, so mathematically speaking by an extreme value of the curvature. The quoted EP 2 604 761 B1 and also the following embodiment give a more vivid idea.

Such a flow path serves to guide or at least support a specific water flow. The water revolves due to the substantially tangential entry into the bowl interior and is held by the centrifugal forces on the bowl inner wall, but at the same time by gravity (more or less obliquely) pulled down, so that due to variations in the shape of the bowl inner wall corresponding flow leading Properties can be produced.

The tangential inlet direction of the rinsing water is determined by the design of the rinse water inlet, ie through the inlet opening and the subsequent upstream piece of pipe for the rinse water. Such a tangential design of the flushing water inlet is already realized in a different form in the prior art and usually serves the purpose of a rotating Spülwasserströmung in the toilet bowl.

According to the invention, in addition to one of EP 2 604 761 B1 known flow path still provided a second or an extension of the known flow path. This second or extended flow path is intended to prevent a flow direction of at least a part of the rinse water that is directed too strongly downwards, and thus to reduce or prevent the "rocking-up" described above. When a portion of the flow is "held" by the flow path at a certain level, there is a lesser or even a lower rate of collapse of the total flow there or downstream of the flow part running on and above the second or extended flow path with a flow part running further down.

From the above longitudinal and transverse axis definition, the rotational movement of the flow in the bowl and the position of certain characteristics of the bowl inner shape shall be described with an azimuthal angle which appears from a certain position in the bowl (in plan view) to the intersection of the axes. namely as an angle to the longitudinal axis. For example, the wall-closest point of the bowl opening lies on the longitudinal axis and thus at 0 ° or 180 ° azimuthal angle. Based on this, there is a lateral area in the area around 90 ° or 270 °.

According to the invention, the rinsing water is to be directed through the inlet opening onto a (with respect to a plan view) concave curvature region of the inner wall of the toilet bowl, for which the inlet opening lies between 80 ° and 180 ° azimuthal angle. Preferably, the inlet opening is at smaller azimuthal angles than 170 °, 160 °, 150 ° or even 140 ° and also preferably at least 90 °. The rinse water flows out in the direction of larger azimuthal angles. In other words, the inlet opening preferably lies in a quadrant upstream of a particularly concave curvature of the bowl opening and aims at this particularly concave location. The background is that with a particularly strong concave curvature in conjunction with a certain residual slope of the bowl inner shape (with respect to a vertical section) stabilizing centrifugal forces the Spülwasserströmung initially relatively stable pass through this curvature, it is assumed that the essential part of the bowl inner shape of extended slightly upwards and there is a corresponding slope. There are exceptions, as mentioned above, typically at the top of the bowl rim in the form of undercuts.

The mentioned and, as a rule, particularly strongly concave curved area of the toilet bowl can be at approximately 180 °, ie at the end point of the longitudinal axis. In individual cases, z. B. bowl shapes with two more curved concave Areas laterally from this location (eg, in a polygonal basic shape with rounded corners), the value may be at a slightly different azimuthal angle, in particular in a range between 150 ° and 210 °, preferably 160 ° and 200 °, instead of at 180 ° or 170 ° and 190 °. He does not have to fill in these angular ranges.

Now, if the rinse water enters a less curved area of the bowl opening, there is an increasing risk of an undesirably strong sinking or sinking of an undesirably large part.

Such a sinking flow part could then meet the inventively provided first flow path or the first flow path part, which extends relative to the azimuthal angle at least between 90 ° and 270 ° and preferably connects below the inlet opening in order to be able to lead the water emerging therefrom , Preferred lower limits for the above angular range are 80 °, 70 °, 60 °, 50 °, 40 °, 30 °, 20 ° and preferred upper limits are 280 °, 290 °, 300 °, 310 °, 320 °, 330 ° and 340 °.

In order to reduce the decrease of a part of the flow, according to the invention a second flow path or a second flow path part is provided, again between an outer concave and an inner convex edge and thereby higher than the azimuthal angle corresponding or next adjacent part of the first flow path / first flow path part. The second flow path or the second part is intended to be provided at least between an azimuthal angle of 310 ° and 340 °. Preferred lower limits are 300 °, 290 °, 280 °, 270 °, 260 °, wherein the second flow path preferably does not begin at angles below 200 °. A preferred upper limit is 345 °, with the second flow path preferably not extending above 400 ° (ie, over 360 °, 40 °), unless it merges into the first flow path anyway.

As already indicated above, can from the EP 2 604 761 B1 namely known flow path according to this invention, namely either extended, while remaining with a continuous flow path, or also adding a second flow path. The difference is ultimately whether there is an interruption between the two flow paths or parts or not, in particular one at 0 ° azimuthal angle, which will be discussed in more detail below. In the following, in the description of the second flow path is spoken, which in the case without interruption then to be understood as the second flow path part of the same uniform flow path. Analogously, this applies to the first flow path, that is without the mentioned interruption, a first part of the flow path and as such (without the second part) already from the EP 2 604 761 B1 is known.

The second flow path should therefore in particular not be completely circumferential, but only cover a limited area, namely where, according to experience, there is a particularly great risk of sinking of the flow of water running along the bowl inner wall. This applies in particular to the "fourth quadrant" (counted from 0 ° with ascending azimuthal angle). As the embodiment illustrates, the second flow path at least partially supports the flushing water flow, thereby preventing over-expression of the already-described "reflection" mechanism on the first flow path.

The previous argument is not dependent on whether the definition of the azimuthal angle with the value 0 start at the front or back, these terms refer to the usual sitting position of a toilet user, "back" so the close-up part of the bowl interior shape (on referred to the horizontal). In addition, the previous argument is not dependent on whether the direction of rotation of Spülwasserströmung in the toilet bowl is left- or right-handed, so if the azimuthal angle increases in plan view with or counterclockwise. The more common and preferred case is a clockwise rotation sense viewed from above, ie clockwise. Further, the case is preferred that the azimuthal angle is calculated from the rear. In this preferred case, therefore, the flushing water flow out of the inlet opening on the concave curvature of the toilet bowl interior facing forward (and would be directed backwards, if one defines the zero point of the azimuthal angle ahead). Both are possible, but in particular in connection with a rather behind Sifonablauf the said variant is preferred.

In particular, could be avoided by the inventive second flow path, so to speak, a second or extended shoulder in the bowl inner mold, a partial sloshing out of rinse water from the bowl, even at low or disappearing undercut the bowl inner shape at its upper edge. It should be noted here that the flushing water inlet opening necessarily requires an undercut and, in this connection, an undercut-free bowl interior mold, of course, nevertheless has an undercut at the inlet opening. It is more about the area just below the upper edge of the bowl interior shape, ie where the Spülrand is arranged in classic toilet bowls.

In principle, the invention aims for the simplest possible, easy to clean (and therefore smooth) and production-favorable form. As already explained, an undercut-free inner bowl shape is therefore preferred in the sense described.

In the same sense, a restriction to the two or one flow path described is preferred, that is, the waiver of more. Although there are no undercuts by the flow paths, in any case preferably not, but they complicate the shape a little and a clever interpretation of Spülwasserströmung by an unnecessarily large number of different flow paths from the perspective of the inventors not easier. Of course, in particular, the first flow path may have a considerable extent in terms of the azimuthal angle, but this does not change the fact that it is a coherent uniform flow path.

The flow paths described with the present invention are intended to carry substantial portions of the flush water flow. This is even more pronounced for the first flow path than for the second, because in the second only one part, namely generally only a part which flows somewhat higher up the bowl inner wall, is captured by the second flow path. In any case, unlike some structures found in the prior art, the two flow paths are relatively distinct in width, the width being understood to be the dimension along the inner wall of the toilet bowl and perpendicular to the longitudinal extent of the flow path, that is, normally with respect to local surface orientation directed downward. Preferred minimum widths at the widest point are 12 cm for the first flow path and 0.8 cm for the second flow path, the following values being 13 cm, 14 cm, 15 cm and the following for the second flow path being 0.9 cm, 1 cm, 1.1 cm are increasingly preferred in this order.

As explained, the second flow path has less of the task of guiding or assisting a downward rotating flow, but of preventing a portion of the water flow from falling too much. In that regard, it may preferably extend approximately horizontally (in relation to its longitudinal direction). Specifically, reference may be made to a middle line between the mentioned convex and concave edges (in each case related to the extreme values of the curvature), and this center line should preferably have an angle of not more than 15 ° to the horizontal along the flow path, preferably at most 13 °, 11 °, 9 °, 7 °. Preferably, the flow path with the flow direction, ie the azimuthal angle, slightly decreases.

The first flow path in turn substantially corresponds to the explanations in the already cited EP patent 2 604 761 B1 The same owner and accordingly runs with increasing azimuthal angle on the one hand downhill and on the other hand rotating along the bowl inner mold to support a downward and rotating flushing water flow.

Accordingly, in this respect, an asymmetrical inner bowl shape is provided, which predefines or generates a downward movement through the bowl inner shape by a lower position of the first flow path on one side than on the other side, similar to a helical shape. Accordingly, the very good surface cleaning properties of a rotating flow in the bowl are combined with a comparatively more pronounced momentum when entering the siphon. As a result, the kinetic energy of the rinse water, for example, as a result of the gradient height compared to a cistern, can be used twice. In addition, the design of the bowl inside shape thus follows the gravitational downward tendency of the water flow and avoids a part of turbulence, which are caused by a run-down of the water regardless of the inner shell shape. Such turbulence reduces the kinetic energy of the rinse water. For similar reasons, for example, a prior art rotating rinse water movement in the bowl for surface cleaning therein is substantially more effective than the conventional solution with a classic rinse edge which degrades much of the kinetic energy of the rinse water entering the rinse water feed.

The predominantly known tangential velocity component of the rinsing water which emerges from the inlet opening into the bowl, so to speak, refers to a projection of a central rinsing water path onto a horizontal plane. The rinse water thus does not emerge from the inlet opening in the direction of the water level in the siphon but rather transversely thereto, whereby the exact angle in a general sense does not matter and this may depend on the individual geometry of the inlet opening and the subsequent first flow path. In particular, the velocity of the rinse water exiting the inlet does not have to be exactly horizontal, but it is preferably substantially horizontal.

The toilet of the invention can be with different methods of Spülwassererzeugung in the sense of supply with a certain rinse water pressure realize, especially on a pressurized water line, ie without cistern. However, preference is given to the combination with a cistern, because of the invention, the limited potential energy of the rinse water from it can be used very efficiently. This is especially true for a concealed cistern in a mounting wall behind the toilet.

In particular, the flushing water quantities can be kept relatively small thanks to the invention, which has economic and environmental benefits. Preferably, the maximum amount of flushing water is less than 6 liters, preferably less than 5.5 liters, and more preferably less than 5 liters.

The rinsing water flow according to the invention allows a good wetting and rinsing action of the soiled areas of the bowl inner mold, as explained by a rotating and falling flow. Accordingly, can be dispensed with a conventional flushing rim, which was compared with a shower at the beginning. This makes the toilet bowl easier to manufacture, but also in the cleaning, because classic Spülränder are particularly dirty and calcification-prone and beyond the bottom is very difficult to achieve. In other words, the invention provides the possibility for a smooth transition from the actual bowl interior surfaces to the bowl top, so the upwardly facing surface areas of the toilet bowl, especially under a toilet seat ring.

The already mentioned several times (preferably only) inlet following the flushing water supply can be relatively high in one embodiment of the invention, in particular higher than 5 cm and in the following order increasingly preferably higher than 5.5 cm, 6 cm, 6.5 cm , With a high inlet opening, a flow-optimized large cross-section can be achieved without impairing the inside of the bowl through the inlet opening too much, both with regard to the flow guidance and to its aesthetic appearance.

In general, the flow cross section of the rinse water supply is preferably relatively large. In particular, in an embodiment of the invention along the extent of the flushing water supply within the WC, ie between the inlet opening and the transition to pipe parts outside the actual WC, ie in particular within an installation wall behind it, it can lie over at least 8 cm ² , preferably over 9 cm ² and more preferably over 10 cm ² or even 11 cm ² . This applies in particular to the inlet opening. Thus, the kinetic energy of the rinse water due to a gradient or a line pressure can be particularly well exploited.

Furthermore, it is preferred that the second flow path with its beginning at small azimuthal angles of the inlet opening maintains a certain distance, preferably at least 60 ° azimuthal angle, more preferably 80 °, 100 °, 120 °, 130 °. This refers to the case that the first and second flow paths are not uniformly connected and the azimuthal angle increasing in the direction from the flow path.

The two flow paths each form a local reduction of the otherwise prevailing inclination of the bowl inner mold. According to a preferred embodiment of the invention, they should therefore not be in the back of the dish interior, at least preferably in a definition of the azimuthal angle of zero at this point, ie a flushing water flow from the inlet opening to the front. It has been found that an inside wall as smooth and steep as possible in the middle is to be preferred in terms of the tendency to dirt on the rear, and this aspect, in the view of the inventors, justifies limiting the flow paths in such a way that they do not cover this rear center. For the sake of illustration, reference is made to the exemplary embodiment. In this case, the first and second flow paths are thus separated from one another.

Furthermore, it has been found that the second flow path should run below a relatively steep part of the bowl inner mold. Accordingly is an inclination angle of at least 70 ° or even 75 ° to the horizontal in this part over the second flow path, preferably between 310 ° and 340 ° azimuthal angle, and preferably along the entire longitudinal extent of the second flow path. Likewise, this statement is valid for a part of the length of the second flow path or for its entire length then for the entire part of the bowl inner shape above, up to an upper edge or rounding, which forms the transition to the top of the toilet body.

Furthermore, a relatively pronounced steepness in the already mentioned central rear area of the toilet bowl inner mold is preferred, at least down to the water level level in the siphon and up to the mentioned transition to the bowl top. Again, the already mentioned angle values come into consideration.

Finally, such a steepness, again with the same angle values, is also particularly preferred on the opposite side, ie in the front center, specifically below the first flow path (preferably downwards from the convex edge) up to the water level in the siphon.

Particularly preferred manner, the statements apply to the steep wall in a part of the height for the entire inner bowl shape.

The steep walls support a good cleaning effect and a sufficient downward trend of the water flow. Accordingly, the flow of water should flow into the Sifon with a significant downward tendency in order to be able to flush it out well.

The second flow path or the second flow path part is preferably relatively high in the multiply-mentioned angular range between 310 ° and 340 °, in particular above the first flow path (the first flow path part), as far as this also preferably exceeds 270 ° azimuthal angle is extended to greater azimuthal angles and into the range at and above 310 ° azimuthal angle. Then, the two flow paths (parts) are spaced apart and arranged one above the other.

The second flow path (the second flow path part) is preferably at least 3 cm higher than the first flow path (the first flow path part), the lower limit being 3.5 cm, 4.0 cm, 4.5 cm, 5.0 cm being increasingly preferred ,

Irrespective of this, the second flow path or the second flow path part in the mentioned azimuthal angle range between 310 ° and 340 ° is preferably higher than the lower edge of the inlet opening for the rinse water, ie again relatively high. Preferably, this lower edge is at least approximately at the same level as the first flow path at this point, that is, the inlet opening injects the water onto the first flow path.

The invention is preferably realized with a toilet bowl, which has at least in the upper region, ie above the first flow path, only a single inlet opening for rinse water. In the prior art variants are quite available with a plurality of inlet openings. This complicates the WC body overall clearly and is not really necessary for good rinsing properties. Preferably, this also applies to the rest of the bowl below the first flow path. In this sense, it is preferable to dispense with nozzle openings in the vicinity of the siphon, which are occasionally used in the prior art to improve the drainage performance. The reasons are the same as above, with a limitation of the total water consumption added.

• Figur 1 und 2 zeigen perspektivische Draufsichten von vorne rechts oben bzw. vorne links oben auf eine erfindungsgemäße WC-Schüssel in Graustufen zur Verdeutlichung der dreidimensionalen Form;
• Figur 3 zeigt eine Seitenansicht der rechten Hälfte der WC-Schüssel aus den Figuren 1 und 2 in längsgeschnittenem Zustand;
• Figur 4 zeigt eine Seitenansicht, jedoch ohne Graustufen und in einem quergeschnittenen Zustand der WC-Schüssel aus den Figuren 1 - 3, und zwar mit Blickrichtung nach hinten und bei einem vereinfachen Ausführungsbeispiel;
• Figur 5 zeigt das Ausführungsbeispiel aus Figur 4 in nebeneinander höhengleich eingezeichneten Seitenansichten entsprechend Figur 3, jedoch ohne Graustufen;
• Figur 6 zeigt in Draufsicht das Ausführungsbeispiel aus den Figuren 4 und 5 zusammen mit der Azimutalwinkeleinteilung, die auch zum Verständnis des ersten Ausführungsbeispiels gedacht ist.

In the following, the invention will be explained in more detail with reference to an embodiment, wherein the individual features may be essential to the invention in other combinations and, as already mentioned, implicitly refer to all categories of the invention.

• FIG. 1 and 2 show perspective top views from the front right above or front left top on a toilet bowl according to the invention in shades of gray to illustrate the three-dimensional shape;
• FIG. 3 shows a side view of the right half of the toilet bowl of Figures 1 and 2 in the longitudinal cut state;
• FIG. 4 shows a side view, but without grayscale and in a cross-cut state of the toilet bowl from the Figures 1 - 3 , Looking backwards and in a simplified embodiment;
• FIG. 5 shows the embodiment FIG. 4 in side by side equal height side views accordingly FIG. 3 but without grayscale;
• FIG. 6 shows in plan view the embodiment of the FIGS. 4 and 5 together with the azimuthal angle division, which is also intended to understand the first embodiment.

The FIGS. 1 to 6 show the invention with reference to two toilet bowls, wherein the first embodiment in the FIGS. 1 to 3 is designed for the installation of a shower device of a shower toilet and the corresponding recesses and openings in the second embodiment in the FIGS. 4 to 6 are omitted. For the invention, these differences are not of particular concern, but illustrate that the invention can also be very beneficial combined with a shower toilet.

The FIGS. 1 and 2 show in perspective oblique views, the toilet bowl 1 of the first embodiment with a conventional bowl opening 2, a rear side (ie in FIG. 1 top right on top and in FIG. 2 shown on the top left) breakthrough 3 for the installation of a shower (not shown) and with a lowering 4 of the upper edge of the toilet bowl at the rear of the bowl rim around the bowl opening 2 for the passage of a shower arm (not shown) of the shower fixture. Hereinafter interested by the bowl opening 2 visible inner shape of the toilet bowl. 1

This first corresponds qualitatively to the one cited several times EP 2 604 761 B1 known toilet bowl by an approximate helical first flow path 5 is provided, which in this case rear and slightly offset to the right, such as at 10 ° azimuthal angle, and in a continuously sloping shape with a widest point at an azimuthal angle of 180 ° almost completely around up to about 350 ° azimuthal angle, so back again, but slightly offset to the left, runs. Their function corresponds to the descriptions in the cited prior art and earlier in this description and need not be explained in detail.

Notwithstanding the cited prior art, however, here is the inlet opening 6 for the rinse water not back (slightly offset right) and directed to the left, as stated in the prior art, but begins laterally at about 100 ° azimuthal angle and is directed forward, ie towards larger azimuthal angles. Accordingly, the rinse water is applied to the first flow path, but not at its start (at 10 °). By the way, for better understanding, the azimuthal angle mentioned here can be up FIG. 6 to get expelled.

Furthermore, in addition to the mentioned prior art in the rear left corner, ie in FIG. 1 clearly visible, a second flow path 7, as it were a further shoulder in the bowl inner wall above the first flow path 5, is provided. This second flow path 7 also strictly defines itself as an inner wall area between an (upper and outer) concave edge and a (lower and inner) convex edge. The second flow path 7 extends with respect to the azimuthal angle between about 250 ° and about 350 °. It is also designed slightly sloping, with an approximate inclination (based on a non-drawn center line between the convex and the concave edge) of about 5 ° in the horizontal direction. At its widest point it is about 1.2 cm wide, while much less flat than the first flow path 5, namely at an angle of about 48 ° to the horizontal at the shallowest point. The first flow path 5 has in contrast z. B. 180 °, an inclination of only about 11 ° relative to the horizontal at a maximum width of 16 cm. The mentioned width refers to the distance between the mentioned edges (convex and concave line), as a straight distance between them along the steepest slope, ie as the shortest distance.

The bowl inner walls above and below the second flow path 7, however, are quite steep with an inclination relative to the horizontal of about 80 °, especially at an azimuthal angle of 0 °. In particular FIG. 3 and FIG. 4 show the bowl walls starting from this forward even steeper and the inclination is at 180 ° azimuthal angle about 89 °. So she avoids just an undercut.

Overall, the bowl inner shape so that, as the figures also show no undercut, especially not at the top (and of course with the exception of the inlet opening 6).

The two flow paths 5 and 7 in this embodiment have a distance of about 6 cm, which is measured as the web width, namely between the convex edge of the upper flow path 7 and the concave edge of the lower flow path 5 and in the direct following the inclination direction. The second flow path 7 is thus significantly increased in relation to the first flow path 5.

It can be imagined on the basis of the figures that a water flow emerging from the inlet opening 6 runs as a result of the centrifugal force to a substantial extent along the steep bowl inner wall above the first flow path 5 and in this form through the (in vertical plan view) concave bowl inner wall to the other, namely left side is brought. Experience shows that the flow of water on the left side tends increasingly downward as a result of gravity and in particular on the part of the first flow path 5 at low azimuthal angles, ie about 10 ° to 90 °, but also already on the opposite part of the first flow path 5 at large azimuthal angles, ie at about 300 ° to 350 °. This leads to a reflection-like flow behavior in which parts of the rinse water tend strongly upwards and can spill out of the bowl 1.

If, as a result of the second flow path 7 in the illustrated Azimutalwinkelbereich, in particular between 310 ° and 340 °, this downward trend a certain obstacle is counteracted, the described behavior is damped or prevented and thus it can be an undercut bowl interior shape with a flow behavior of the rinsing water without Realize danger of spilling out. The extended in terms of the azimuthal angle and in the inclination in vertical sections (by the sealing water level in the drain pipe as in FIG. 3 ) flat configuration of the first flow path 5 is again desired to promote the rotating character of the flushing water flow as possible and to achieve optimal wetting of the bowl inner walls with the smallest possible amounts of flushing water.

FIG. 4 shows on the one hand a side view of the rear portion of the bowl inner mold and on the other hand a section through the bowl. The cutting plane passes through the water level in the lowest part of the toilet bowl, which is marked with 8. In the left part of the bowl inner mold you can see the second flow path 7 and in the right part of the first flow path 5. Both are each characterized by boundary lines of the CAD program, the surfaces with vertical section (through the barrier water level 8) straight cutting profile, such. B. the steep bowl inner wall above the flow paths 5 and 7, separates from curved surfaces. In that regard, it can be seen that the two flow paths 5 and 7 actually have a middle in this sense straight strip, followed by the top and bottom of each curved strip.

FIG. 6 shows in plan view the second embodiment of the FIGS. 4 and 5 with the azimuthal angle division and some values. In particular, it can be seen that 0 ° corresponds to the rear center of the bowl inner shape and 180 ° of the front center. It can be seen in the claims defined Azimutalwinkelbereich for the flushing water inlet opening between 80 ° and 180 °. One can also see the front azimuthal angle range between 150 ° and 210 °, in the claim according to a concave curvature should be present (not necessarily over this entire angular range), is directed to the incoming rinse water. Furthermore, it can be seen between 90 ° and 270 °, the minimum range for the flow path. Further, in the clockwise direction, a little offset from the drawn line at 300 ° and in the same sense offset next to the line at 330 °, the limits of the minimum range (between 310 ° and 340 °) for the second part or the second flow path, the claim should not extend beyond the angular range between 230 ° and 90 °.

Also clarifies FIG. 6 as a plan view additionally explained with reference to the previous figures bowl inner shape, wherein no reference numerals are shown to avoid over-loading.

Claims (15)

WC with a toilet bowl (1), and an oval or round bowl opening (2), and an inlet opening (6) for rinsing water,
wherein, in plan view, a longitudinal axis along a longitudinal extension of the oval and a transverse axis extending perpendicularly and centrally define a center point and, starting from the longitudinal axis and the center point, an azimuthal angle,
wherein the inlet opening (6) is provided for the rinse water with respect to the azimuthal angle between 80 ° and 180 ° and is oriented in the direction of greater azimuthal angle and thereby a tangential inlet direction of the rinse water is provided in plan view and with respect to the shape of the bowl opening (2) .
so that the rinse water after entering the toilet bowl (1) through the inlet opening (6) on an inner wall of the toilet bowl (1) flowing in a plan view and based on the center concave curvature of the inner wall at an azimuthal angle of 150 ° to 210 ° hits,
wherein the toilet bowl (1) has a in the inner shape of the toilet bowl (1) between a vertical section and based on the center outer concave edge and an inner convex edge defined flow path (5) for the rinse water at the bottom of the Adjoining the inlet opening and which, relative to the azimuthal angle, extends at least between 90 ° and 270 °,
characterized in that a flow path (7) is also provided between 230 ° and, once over 360 °, 90 ° azimuthal angle, but not beyond, but at least between 310 ° and 340 ° azimuthal angle, which also in the inner shape of the toilet -Schüssel (1) is defined between a in vertical section and in relation to the center outer concave and an inner convex edge and thereby higher than another Part of the first-mentioned flow path (5) is at the same azimuthal angle. Toilet according to claim 1, having an upper edge of the toilet bowl (1) which does not form an undercut inwardly, in particular with a toilet bowl (1) which is not undercut apart from the inlet opening (6). Toilet according to claim 1 or 2, which exclusively comprises the flow path (s) (5, 7) mentioned in claim 1, ie no further flow path. Toilet according to one of the preceding claims, in which the flow path (5) is at least 12 cm wide between 90 ° and 270 ° azimuthal angles at its widest point and / or the flow path (7) is at least widest between 310 ° and 340 ° azimuthal angles at its widest point 0.8 cm wide. Toilet according to one of the preceding claims, wherein the second flow path (7) extends horizontally with a maximum deviation of +/- 15 °, preferably somewhat sloping with increasing azimuthal angle. Toilet according to one of the preceding claims, in which the flow path (5) slopes down between 90 ° and 270 ° azimuthal angles and thus supports a downward movement of flushing water which has entered through the inlet opening (6), the parts of the inlet opening (6) nearest the inlet opening Flow path (5) between 90 ° and 270 ° azimuthal angle higher than the remaining flow path (7) between 310 ° and 340 ° azimuthal angle next adjacent parts. Toilet according to one of the preceding claims, in which the flow path between 310 ° and 340 ° azimuthal angle and the flow path between 90 ° and 270 ° azimuthal angle over 0 ° away continuously merge into one another and thus form a total flow path. Toilet according to one of claims 1 to 6, wherein the azimuthal angle of 0 ° with respect to a seated posture of a toilet user behind, so close to the gut, and at this position of 0 ° no flow path (5, 7) exists, the Flow path (5) between 90 ° and 270 ° and the flow path (7) between 310 ° and 340 ° azimuthal angle two separate flow paths (5, 7). Toilet according to one of the preceding claims, in which the WC bowl inner mold has a slope of at least 70 ° to the horizontal above the flow path (7) between 310 ° and 340 ° azimuthal angle. Toilet according to one of the preceding claims, wherein the azimuthal angle of 0 ° with respect to a seated posture of a toilet user behind, so close to the gutter, and in which the inner shape of the toilet bowl (1) at this azimuthal angle of 0 ° between a Sifonwasserstandsoberkante (8) and a top-side transition to the bowl top has a slope of at least 70 ° to the horizontal. Toilet according to one of the preceding claims, wherein the azimuthal angle of 0 ° with respect to a seated posture of a toilet user behind, so close to the gutter, and in which at an opposite location, ie at an azimuthal angle of 180 °, the inner shape of the bowl (1) between a flow path (5) defining the convex edge and from there down to a Sifonwasserstandsoberkante (8) has a slope of at least 70 ° to the horizontal. Toilet according to one of the preceding claims, in which the flow path (5) is continuously extended between 90 ° and 270 ° azimuthal angle to greater azimuthal angles and at least partially at the same azimuthal angles as the flow path (7) 310 ° to 340 °, but spaced from and under this runs. Toilet according to one of the preceding claims, wherein the flow path (7) between 310 ° and 340 ° azimuthal angle is higher than a lower edge of the inlet opening (6) for the rinse water. Toilet system with a toilet according to one of the preceding claims and a cistern, preferably concealed cistern, preferably with a flush volume less than 6 l. Use of a WC or a toilet installation according to one of the preceding claims for flushing, in which the flushing water from the inlet opening (6), starting a rotating movement along the flow path (5) performs while a portion of the flushing water via the flow path (7) between 310 ° and 340 ° is guided.

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