RU222139U1 - Toilet with flush system - Google Patents

Abstract

The subject of the utility model is a toilet with a flush system with a rimless bowl (1), with a flush water supply in the upper rear part of the bowl (1), containing an inlet pipe (8) ending in an inlet (7) and a channel located behind it (9), ending at the mouth (10), while the toilet has a first central plane (A-A), which in the assembled state of the toilet is parallel to the mounting wall and mentally divides the toilet through the center of the outlet (2) into front and rear parts, with the rear part adjacent to the mounting wall, and the toilet (1) on the inside at the level of the mouth (10) and just below the upper edge (6), has a horizontally located upper threshold (12), formed in the form of a convexity, and the beginning of the upper threshold (12) is at the level of the mouth (10), and the end of this upper threshold (12) is opposite the mouth (10), on the opposite side of the bowl (1) relative to the first central plane (AA); in this case, the bowl (1) on the side opposite to the side containing the upper threshold (12) has the shape of a smooth arc; wherein the upper edge (6) is made in the form of a flat segment of an elliptical ring, and this segment is located directly above the upper threshold (12) in a section measured horizontally, the length of which corresponds to the length of the section occupied by the upper threshold (12); and at the same time, below the upper threshold (12), and above the level of the water surface in the state of the operating toilet, the bowl (1) has a lower threshold (13) in the form of a convexity, and the beginning of this lower threshold (13) is located in the rear part of the bowl ( 1), then it passes to the side in accordance with the direction in which the mouth (10) is directed, and the end of this lower threshold (13) is located on the opposite side of the bowl (1) relative to the beginning of this lower threshold (13) so that it essentially located on half of the rim of the bowl (1). 15 salary f-ly, 9 ill.

Description

Field of technical application

The utility model concerns a toilet with a bowl into which flushing water is supplied.

State of the art

Toilets with a flush system, with a bowl into which flushing water is supplied, as well as with water discharge (drain) into the sewer system are widely known and used. Typically, flush toilets have a bowl-shaped body with a hole in the top, and used water is drained into the sewer system through a siphon. Toilets are usually made of ceramic material.

The toilet flushing system is used to perform two operations: cleaning the inner surface of the bowl and moving used water along with contaminants through the siphon to the drain. In traditional bowls, a so-called flush rim in the form of an annular channel with holes or a slot is formed as standard on the upper inner edge of the bowl, which acts as a ring (shower) system. Flushing is carried out by diverting part of the water into a hollow rim, from which it exits into the body through a continuous narrow slot or a series of holes located at a distance from each other, which allows you to wash the inner surface of the bowl. Large volumes of water can be directed to specific areas of the bowl, such as down the front and back surfaces of the toilet (for example, through large holes in these areas). The channel portion of the rim may be manufactured as a separate hollow portion and added to the toilet during manufacturing, or as an integral part of the bowl during manufacturing. In both cases, it usually takes the form of a flange - protruding inward so that it hangs from the top of the toilet around all or part of its rim. Toilets with other flushing mechanisms are also known in the art, such as those using a rotating (vortex) movement of the water jet caused by the water jet being introduced tangentially into the bowl, as well as toilets having, instead of a flange hanging down, a hollow groove/channel surrounding the inner surface of the bowl.

The shape of the bowl, which uses a conventional annular flush rim (usually with a flange), as well as various hollow channels or grooves, implies that there are difficult-to-reach areas in the form of ridges and depressions, which makes it difficult and sometimes even prevents effective cleaning of the bowl. The channel in the flushing rim is completely inaccessible and cannot be cleaned. This design makes traditional toilets particularly susceptible to contamination and the accumulation of sediment in the form of limescale. In addition, in toilets of this design, due to the too weak pressure of the water jets on the walls of the bowl, flushing is relatively ineffective, and therefore requires the consumption of large volumes of water. In addition, the water flowing down the walls of the bowl enters the siphon with too weak a force, which can lead to a situation where a single flush will not remove all contaminants.

A flush toilet with a symmetrical internal bowl shape and a traditional flush rim is described, for example, in British patent application GB 685960 A.

Patent GB 2045311 B, in turn, proposes a bowl with a smooth inner contour, which does not have a flange around the rim. However, the rim of such a bowl is surrounded by a hollow water channel with one or more flushing holes. The recesses formed in this bowl rim, as in the case of a conventional flange, also create problems with keeping the toilet clean, since they can accumulate dirt and limescale.

From French patent application FR 2744744 A, a toilet with a flush system with an asymmetrical internal bowl shape having a traditional flush rim is known. The bowl has an outlet for the siphon, offset relative to the axis of symmetry of its rim. The inner wall of the bowl consists of spherical or conical segments joined at the edges, with the joints slightly raised so that the bowl can be washed and emptied at the same time.

In contrast, British patent application GB 2431937 A describes a toilet with a symmetrical internal bowl shape without the traditional ring flush rim. In this solution, flush water is directed into the toilet through a downward-facing inlet and through inlets directed toward the top of the interior surface of the toilet (parallel to the plane of the toilet opening). Flushed water flows out of a preliminary chamber located immediately behind the inlet that supplies water from the pipes into the toilet bowl, and closed by a fragment of the toilet rim, and is directed simultaneously to the left and right sides of the bowl, tangential to its inner wall, after which these two flows move along the inner wall of the bowl and collide with each other in its front part.

Patent EP 2604761 B1 is the closest in technology level to the developed solution. This document applies to a toilet with a flush system without a traditional flush rim, in which the flush flow inlet is asymmetrical and which has an asymmetrical bowl shape. The essence of the solution described in this document is that the bowl has an asymmetrical shape relative to the vertical central plane, due to which the internal shape of the bowl determines the trajectory of the flow of flushed water, that is, it causes it to move in a certain way along the inner wall of the bowl. The trajectory of the flushed water jet on one side relative to the central plane is lower than on the other, as a result of which a downward movement is superimposed on the rotational movement of the water, depending on the internal shape of the bowl, and, therefore, a vertical component directed downwards is added to the speed of the flushed water, due to the inner shape of the bowl.

Disclosure of utility model

Thus, the level of technology described shows various solutions to the technical problem of creating a toilet with a flush system that guarantees a quick release of water into the bowl, while cleaning its surface as thoroughly as possible. Surprisingly, it has been discovered that this problem can be solved even more effectively by a new, previously unknown, toilet design that is an alternative to the designs described above, in particular to the designs described in GB 2431937 A and EP 2604761 B1. GB 2431937 A describes a toilet without a traditional flush rim, with a symmetrical internal bowl shape into which water enters in a symmetrical manner (via a symmetrical inlet), simultaneously on the left and right sides. Patent EP 2604761 B1, in turn, describes a toilet without a traditional flush rim, which has a bowl asymmetrically shaped relative to the vertical central plane and in which the water supply to the bowl is asymmetrical. An alternative solution to the above-mentioned technical problem is a toilet according to claim 1, the design of which provides for the absence of a flush rim (i.e., a rimless toilet) with an asymmetric supply of flush water to the bowl and the asymmetric bowl. This design will be described in more detail later in the description.

As unexpectedly turned out during experimental tests conducted by the authors of this utility model, the most effective in terms of the speed of flushing water into the bowl is a toilet with an asymmetrical supply of water to the bowl - water is supplied tangentially to the inner surface of the bowl, in its upper rear part, and is directed to the left and right sides. Such a toilet allows water to be flushed down much faster and more dynamically than the toilet known from the above-mentioned patent EP 2604761 B1. The developed shape of the bowl, that is, one in which the flow of water supply is asymmetrical relative to the central plane, and the lower part of the bowl is symmetrical, makes it possible to create a rotational movement of the wash water in the bowl, as well as to obtain a significant vertical component of the speed of the downward movement of the water stream towards the outlet into the siphon . The rinsing water in a bowl of this shape moves with a large impulse, which further improves its cleaning properties, since it more effectively cleans the inner walls of the bowl from contaminants.

The authors of this utility model also found that for the flush to work effectively, especially with small quantities of flush water, in addition to the vertical component of the velocity, it is also important to keep the water in the toilet bowl for a long time and to direct the water stream so as to clean the inner walls of the bowl as thoroughly as possible , which, according to the utility model, can be achieved due to the presence of thresholds in the bowl. Due to their design, these thresholds keep the water flow in a rotational motion for a longer time and thus allow the energy of the water flow to be used efficiently. These thresholds are areas on the inner surface of the bowl where the vertical slope of that inner surface is less than the areas immediately above and below them. In simple terms, these are the “more horizontal” areas. And speaking in the precise language of mathematics, the gradient of the vertical inclination of the inner surface of the bowl is locally less significant in these areas than in the areas located directly above and below them. Technically (structurally), the threshold is a convexity running horizontally on the inner surface of the bowl. Each sill runs horizontally, generally around just over half of the bowl, starting at the flush inlet and ending at the opposite end of the bowl to that inlet - opposite it to the central plane dividing the bowl into front and back. The entire interior surface of the bowl below the flush inlet is asymmetrical (from left to right) relative to the vertical center plane.

The toilet, according to the utility model, has a bowl without a flush rim, which in the next part of the description will be called rimless. The internal shape of such a bowl does not have a flush rim, that is, a rim channel with downward inlet holes for flushing water into the bowl.

The design, according to the present utility model, combines the absence of a rim, an asymmetrical supply of wash water to the bowl and an asymmetrical bowl.

A rimless bowl flush toilet has a flush water supply at the upper rear of the bowl containing an inlet pipe terminating in an inlet and a channel thereafter terminating in an outlet in which a siphon outlet is located at the bottom of the bowl. In this case, the toilet has a first central plane (A-A), which in the assembled state of the toilet is parallel to the mounting wall and mentally divides the toilet through the center of the outlet into front and rear parts, with the rear part adjacent to the mounting wall, and a second central plane perpendicular to it (C-C ), mentally dividing the toilet through the center of the outlet into the right and left parts, while the bowl has an upper edge, which is a fragment of the upper inner surface of the bowl with almost vertical walls, located directly below the lid, there is a lid above the upper edge, while the outlet is offset to the rear of the toilet, and at the same time the mouth of the channel is located asymmetrically relative to the second central plane (C-C) to the right or left of the bowl in its upper part in such a way as to allow flush water to enter the bowl and fall first on the back of the upper edge in the horizontal direction and tangentially to the inner surface of the bowl, and then performing a rotational movement inside the bowl, while the bowl on its inner side, at the height of the outlet mouth and just below the upper edge, has a horizontally located upper threshold formed in the form of a convexity, according to the model , is characterized by the fact that

the beginning of the upper threshold is at the level of the mouth, then it runs inside the bowl to the side in accordance with the direction in which the mouth is directed, and the end of this upper threshold is opposite the mouth, on the opposite side of the bowl relative to the first central plane (A-A),

in this case, the toilet bowl on the side opposite (relative to the second central plane C-C) to the side containing the upper threshold has the shape of a smooth arc,

wherein the upper edge is made in the form of a flat segment of an elliptical ring, and this segment is located directly above the upper threshold in a section whose length, measured horizontally, corresponds to the length of the area occupied by the upper threshold,

and at the same time, below the upper threshold and above the level of the surface of the water, which is in the state of a working toilet, the bowl has a lower threshold in the form of a convexity, and the beginning of this lower threshold is located in the rear part of the bowl, then it extends to the side in accordance with the direction in which it is directed mouth, and the end of this lower threshold is on the opposite side of the bowl from the beginning of this lower threshold, so that it is essentially on half the rim of the bowl.

The advantage is that the upper threshold at its end is slightly flattened and goes into the curve of the bowl.

The advantage is that the height of the upper threshold, measured vertically, is 4 mm, and the width of the upper threshold, measured horizontally, is 9 mm. In this case, the radius of curvature of the upper threshold in a plane perpendicular to the inner surface of the bowl is 13 mm, and the radius of curvature of the arc between the upper edge and the beginning of the upper threshold in the above-mentioned plane is 17 mm.

The advantage is that the lower threshold has a radius of curvature in a plane perpendicular to the inner surface of the bowl, ranging from 32 to 66 mm.

The advantage is that the lower threshold is less than half the distance from the upper threshold to the water level, preferably 2/3 of the distance from the upper threshold to the water level.

The advantage is that the channel is inclined into the toilet so that its starting point (A) is higher than the end point (B), with a difference in position between this starting point (A) and the end point (B) being from 23 mm to 27 mm , preferably 25 mm.

The advantage is that the first section of channel behind the inlet is directed towards the right or left side of the toilet and is slightly curved to match the shape of the top edge. In addition, it has a bend of approximately 180°, as a result of which the mouth is located on the right or left of the bowl, but is directed in the opposite direction than the mentioned first section of the channel, and therefore, respectively, to the left or right side.

The advantage is that the cross-sectional area of the wash water inlet is between 15.5 and 16.5 cm ² , preferably 16.04 cm ² .

The advantage is that the cross-sectional area of the channel in the part between the inlet and the bend is from 16 to 17.5 cm ² , preferably 16.81 cm ² .

The advantage is that the canal is flattened in cross section, that is, it is longer in the vertical direction and more strongly narrowed at the mouth.

The advantage is that the channel is rectangular in cross section.

The advantage is that the ratio of the height of the vertically extending mouth to the width of this mouth is from 4.0 to 4.12, preferably 4.06.

The advantage is that the height of the mouth is from 68 to 74 mm, preferably 71 mm, and the width of the mouth is from 17 to 18 mm, preferably 17.5 mm.

The advantage is that the channel has a bend with a radius of curvature from 27 to 40 mm.

The advantage is that the lower threshold is at least 15.5 cm, preferably 17.3 cm, from the top edge of the bowl, this distance being measured in a straight line (vertically) from the edge of the top edge of the bowl to the level at which the lower one is located threshold.

Advantages of a utility model

This useful model, thanks to the use of rotational/vortex movement of water in the bowl, allows you to effectively clean the surface of the bowl and, thanks to the large flow of rinsing water, effectively move contaminated water into the siphon and drain. The design of the toilet, according to the utility model, also makes it possible to significantly reduce the volume of flush water, which is beneficial for economic and environmental reasons. The toilet, according to the utility model, is easy to clean because it has smooth, easy-to-clean internal walls, and because of its simple design it is simple and cheap to manufacture.

Description of drawings

The subject of the utility model will now be presented in more detail in the preferred embodiments with reference to the attached drawings, in which:

Fig. 1 shows the toilet (top view) according to the utility model, with cross-sectional planes marked;

Fig. 2a shows the toilet (top view) according to the utility model without a lid;

Fig. 2b shows the toilet (top view) according to the utility model, with the starting and ending points of the channel marked;

Fig. 3 shows the toilet according to the utility model without a lid in an angular projection;

Fig. 4a schematically shows the cross section of the toilet in plane A-A;

Fig.4b formation of the upper threshold in cross section in plane A-A;

Fig. 5 shows the cross section of the toilet in the A-A plane from Fig. 4a, with a view of the structural elements outside this plane;

Fig. 6 schematically shows the cross section of the toilet in the B-B plane;

Fig. 7 shows the cross section of the toilet in the B-B plane from Fig. 6, with a view of the structural elements outside this plane;

Fig. 8 schematically shows the cross section of the toilet in the C-C plane;

Fig. 9 shows the cross section of the toilet in the C-C plane from Fig. 8, with a view of the structural elements outside this plane;

The following numbers are used in the figures: 1 - bowl, 2 - outlet, 3 - siphon, 4 - drain, 5 - lid, 6 - upper edge, 7 - inlet, 8 - inlet tube, 9 - channel, 10 - mouth, 11 - protrusion, 12 - upper threshold, 13 - lower threshold.

Detailed description of the utility model

In the following, the utility model will be illustrated in more detail based on an advantageous embodiment with reference to schematic drawings.

The schematic drawings generally show a rimless bowl toilet (without a circular flush channel with downward-facing inlets for the flow of flush water into the bowl), made, for example, of a ceramic material. Fig. 1-9 show the toilet according to the utility model.

Fig. 1 shows the toilet (top view) according to the utility model, with marked planes intersecting this toilet in certain places: the first central plane AA, intersecting the toilet horizontally, which in the assembled state of the toilet is parallel to the mounting wall (not shown), and passing through outlet center 2; plane BB intersecting the toilet horizontally below plane AA outside the outlet 2; the second central plane CC is perpendicular to the above-mentioned planes AA and BB and intersects the toilet vertically, dividing it into two equal parts - right and left. Outlet 2 is located at the bottom of bowl 1 and leads to siphon 3, which is known to be connected to rear drain 4 (siphon 3 and rear drain 4 are not shown in Fig. 1). In other words, we can say that the outlet 2 represents the beginning of the siphon 3. The bowl 1 has a cover 5 with an elliptical hole, and the outlet 2 inside this ellipse is offset back (towards the rear drain 4) and is centered in the central plane CC, which is known solution in bowls. In this embodiment, the distance between plane AA and the very starting point on the plane of the bowl 1 (farthest from the mounting wall, in other words: the outer edge of the lid 5 at the front of the toilet) is 240 mm. The cross-sectional plane BB is chosen arbitrarily to better visualize the symmetry of the toilet. This plane is located in Fig. 1 in the middle of the distance between plane AA and the inner edge of the lid 5 in the front of the toilet, in its most protruding part, and in this case the distance between plane AA and plane BB is 100 mm. This plane, however, may be placed at any other location between plane AA and the inner edge of the lid 5 on the front of the toilet - it is marked only to illustrate that the toilet is symmetrical about the plane CC at any location between plane AA and the inner edge of the lid 5 on front of the toilet. Fig. 2a shows a toilet without a lid 5. Bowl 1 has an upper edge 6, which forms a fragment of the top of bowl 1, more precisely, part of the upper inner surface of bowl 1, located directly under the lid 5, the upper edge 6 of which is closed by the lid 5. Upper edge 6 depicted as a flat segment of an elliptical ring located at the top of the toilet, with the walls being generally vertical, and preferably having a height of 90 mm. The fragment representing the upper edge 6 is located in an area occupying just over half of the inner rim of the upper part of the bowl 1, and corresponds to the area occupied by the upper threshold 12, described in more detail later in the description. The remainder of the toilet 1 (minus the top 6) is basically bowl shaped like many traditional toilets. The wash water inlet 7 is preferably located at the rear of the bowl 1, at its top, preferably at the highest point of the wash water flow. The inlet pipe 8 leads to an inlet 7, preferably located parallel to the CC plane and perpendicular to the mounting wall of the toilet (not shown). Behind the inlet 7 there is a channel 9 for draining water into the bowl 1, ending at the mouth 10. The inlet 7 in this embodiment is round and has a diameter of 15.5 to 16.5 cm ² , preferably 16.04 cm ² . The inlet 7 may also have a different shape, however, regardless of this shape, the inlet 7 may have a cross-sectional area of from 16 to 17.5 cm ² , preferably 16.81 cm ² . This relatively large cross-section ensures that an appropriate volume of water is supplied to channel 9, so that the kinetic energy of the wash water can be used more efficiently.

In Fig. 2b the bowl is shown in the same way as in Fig. 2a, but here two places in channel 9 are marked: starting point A and ending point B. To reduce the remaining flushing time from channel 9, channel 9 is inclined between marked points A and B so that starting point A is higher than ending point B. Difference in the position between the height at which point A is located and the height at which point B is located is predominantly 25 mm with a slight deviation (+/- 2 mm). The location of the starting point A is determined by the standards describing the requirements for the size of the toilet. The tilt of channel 9 ensures complete drainage of water after flushing. In other words, the inclination of channel 9 causes it to point slightly downwards towards the inside of the bowl. This shape of channel 9 makes it possible to reduce the time for the outflow of residual water from channel 9, since all the water in channel 9 after flushing bowl 1 flows out of this channel 9. In traditional toilets, in which the angle of inclination of channel 9 is too small, after rinsing the bowl Some of the water entering channel 9 from inlet 7 remains in this channel 9, which is due to the surface tension of the water and the shape of the channel and, in particular, its slight or no slope. Thus, the remaining water flows out of this channel for a long time in a thin stream. In the toilet, according to the utility model, a large angle of inclination of channel 9 will lead to the fact that the flushing water after flushing will very quickly stop flowing, and the problem associated with water leakage in the form of a thin stream will be eliminated. In addition, such water leakage in traditional toilets causes limescale to settle in this area - using a properly inclined channel 9 thus makes the toilet more hygienic and even easier to clean.

In this embodiment, the channel 9 is approximately J-shaped with the tip more curved upward and flattened in cross section, especially near the mouth 10, that is, its height is noticeably greater than its width. The channel 9 is formed in such a way that the first slightly curved (curved in accordance with the line of the upper edge 6) portion of the channel 9 is directed towards the right side of the toilet (substantially parallel to the planes A-A and B-B), in addition, it has a bend, i.e. a bend formed in such a way that the channel 9 is bent through approximately 180°, with the result that the mouth 10 is on the right side of the toilet 1, but is directed in the opposite direction, in this case to the left. The mouth 10 of channel 9 has a predominantly oblong shape - it extends in the vertical direction. The advantage is that the ratio of the height of this mouth 10 to the width of the mouth 10 is in the range from 4.0 to 4.12, preferably 4.06. More precisely, the height of the mouth 10 should be from 68 to 74 mm, preferably 71 mm, and its width should be from 17 to 18 mm, preferably 17.5 mm. The mouth 10 is located in such a way that the water coming out of it is directed to the inner surface of the bowl 1, namely to the inner surface of its upper edge 6 at the back of the bowl 1, as can be better seen in Fig. 3. Fig. 3 shows the toilet according to the utility model from a different angle than Fig. 2a. Thus, the supply of water to bowl 1 is asymmetrical and, in this case, on the right side of bowl 1 (relative to the C-C plane). The correct direction of the water jet is facilitated by the presence of a protrusion 11 at the mouth 10 of channel 9. Channel 9 is flattened in cross section, that is, it has a height greater than its width. In this embodiment, it is made rectangular, and its cross-sectional shape can be any other if it properly performs its function. In order to effectively use the kinetic energy of the water jet, the channel 9 should not bend too sharply and, in particular, it should not have a rectilinear geometric shape. The radius of curvature of the bend of channel 9 should preferably be in the range from 27 to 40 mm.

The toilet, according to the utility model, in this embodiment has an upper threshold 12, running horizontally inside the bowl 1, starting at the level of the mouth 10 of the channel 9 and ending at the front of the bowl 1 (and thus occupying half, or slightly more than the rim of the bowl 1 ), which allows you to maintain a stream of water in bowl 1.

In Fig. 4a and Fig. 5 the toilet is shown in section along plane A-A. Figure 4a clearly shows the shape of the inner surface of the upper edge 6, as well as the position and shape of the mouth 10 of channel 9. The upper edge 6, made in the form of a flat segment of an elliptical ring, is located directly above the upper threshold 12, in a section whose length, measured by horizontally, corresponds to the length of the area occupied by the upper threshold 12; the upper edge is located only above the upper threshold 12. This is directly related to the fact that the presence of the upper edge 6 is due to the presence of the upper threshold 12. Moreover, as can be clearly seen in Fig. 4a, the toilet bowl in its upper part has neither a recess nor a cut between the lid 5 and the inside of the toilet bowl (this does not apply to the water supply point inside the bowl, located on the back wall of the toilet bowl).

In Fig. 4a and Fig. 5 the position and shape of the upper 12 and lower 13 thresholds are clearly visible. These thresholds are in the form of protrusions, with the upper threshold 12 located at the level of the mouth 10 of channel 9, and the lower threshold 13 at less than half the distance from the upper threshold 12 to the water level, starting from the upper threshold 12, preferably at 2/3 of this distance . The upper threshold 12 begins at the level of the mouth 10 of channel 9 and extends further horizontally inside the bowl 1 in the direction of movement of the wash water. Having gone around a little more than half of the bowl 1, the upper threshold 12 ends in a gentle way - it flattens and goes into the rounding of the bowl 1. The end of the upper threshold 12 is located opposite the mouth 10 of the channel 9. In other words, it is located on the opposite side of the bowl 1 relative to the plane A-A, approximately the place where there would be a mirror image of the mouth 10 of channel 9 relative to the plane A-A. Relative to the top edge 6 of the bowl 1 and using absolute values, the lower threshold 13 is located at a distance of at least 15.5 cm, preferably 17.3 cm, from the top edge of the bowl, this distance being measured in a straight line (vertical) from the top edge 6 of the bowl to the level at which the lower threshold 13 is located. The lower threshold 13 runs similarly to the upper threshold 12, that is, it begins at the height of the mouth 10, but accordingly below it (so that the beginning of the lower threshold 13 is approximately below the mouth 10, at the distance indicated higher). Similar to the upper threshold 12, the lower threshold 13 runs horizontally inside the bowl 1, in the direction of movement of the washing water, and, having gone around a little more than half of the bowl 1, the lower threshold 13 ends in a gentle way - it is flattened and turns into the curvature of the bowl 1.

Thus, according to Fig. 4a and 5, the toilet in cross section through the center of siphon 3 has the following characteristics:

- asymmetrical - the side of the bowl 1, containing the upper threshold 12 and the lower threshold 13, has a significantly different shape on the side without these thresholds 12, 13:

one side of the bowl 1 has two clearly marked thresholds 12, 13 along which water can flow, the thresholds 12, 13 being characterized by the fact that two close horizontal tangents are in contact with flat parts of the inside of the bowl;

the other side does not have thresholds and the “water flow paths” are not distinguishable on it - it has the shape of a gentle arc and on it it is impossible to distinguish any tangent close to horizontal, which would come into contact with the flat surface of the bowl;

- thresholds 12, 13 are designed in such a way that the fall of water towards siphon 3 is caused by the mutual relationship of forces associated with the conversion of potential energy of water into kinetic energy, and centrifugal force associated with circular motion relative to the narrowing of the center of siphon 3 in the gravitational field.

To fulfill the functional requirement associated with washing the desired surface of the bowl during rinsing, the upper threshold 12 must have the dimensions shown in Fig. 4b, which will be indicated later in the description. Compliance with these dimensions allows the bowl to be completely washed below the surface of the upper flange - in particular, the water is able to flow down to the place below the outlet (first revolution) and make a total of 1.5 revolutions around the siphon 3. The water flowing out of the mouth 10 has kinetic energy , which depends on the amount of water supplied to flush bowl 1, and the height at which the tank supplying water to the toilet is located. The kinetic energy of water is associated with the speed at which water flows out of the mouth 10 in accordance with the ratio E _k =(mv ² )/2. There are two forces acting on the flowing water: gravity and the force associated with the rotational movement of the water. Theoretically, one can roughly imagine that water will quickly enter siphon 3 of the toilet bowl (approx. 40 cm) and will not be able to cover the entire bowl 1 and, therefore, wash its entire inner surface. In order for the water to wash the entire bowl 1, an upper threshold 12 with correctly selected dimensions is needed, which will allow at least one revolution of water around the perimeter of the bowl 1.

However, the theoretical considerations described above are not sufficient to accurately determine the optimal position and shape of the upper threshold 12 in the bowl 1. In order for the toilet to perform its function correctly, it is necessary to maintain the appropriate dimensions of this upper threshold 12 (also the lower threshold 13) - they must be within appropriate limits. The dimensions of this upper threshold 12 are determined by the following factors: if the threshold is too small, water will enter the siphon 3 too quickly (the surface of the toilet bowl will remain unflushed); if the threshold is too high, then bowl 1 will become unsanitary, as contaminants will be retained on it. The exact, corresponding dimensions of this upper threshold 12 were determined by the author of this utility model through experiments.

Approximate suitable dimensions for the upper threshold 12 are shown in Fig. 4b. In this embodiment, the distance of the beginning of the upper threshold 12 from the upper edge 6, which is equal to the height of the upper edge 6, is 90 mm. The dimensions of the upper threshold 12 are as follows: the vertical height of the upper threshold 12 is 4 mm, the horizontal width of the upper threshold 12 is 9 mm, the radius of curvature of the upper threshold 12 in a plane perpendicular to the inner surface of the bowl 1 is 14 mm, and the radius of curvature of the arc between the upper edge 6 and the beginning of the upper threshold 12 in the specified plane is 17 mm. These dimensions of the upper threshold 12 provide a 1.5-fold turnover of water inside the bowl 1 before it flows into the siphon 3. The upper threshold 12 is shaped (has a fairly sharp edge) that separates the flowing water into two streams. The task of the first jet is to wash the upper mouth of the bowl - the first jet makes 1.5 revolutions around siphon 3. The jet below the upper threshold 12 washes the center of the bowl and makes 0.75-1 revolution.

The lower threshold 13, in turn, has a radius of curvature in a plane perpendicular to the inner surface of the bowl 1, from 32 to 66 mm. The lower threshold 13 slows down the vertical speed of water falling (while maintaining the horizontal one) in order to wash the bowl, performing from 0.25 to 0.75 revolutions of water around siphon 3.

Moreover, as mentioned above, i.e. In order to be able to maintain a balance between appropriate flush dynamics (impulse) and retention of water in the toilet bowl for a sufficiently long time, which leads to a thorough cleaning of the surface, the upper threshold 12 must be placed in an appropriate location, i.e. at an appropriate height in relation to the mouth 10 of the channel 9 - preferably just above the bottom of the mouth 10. The advantage is that the upper threshold 12 is 2-5 mm above the mouth 10, preferably 3.5 mm above the mouth 10.

Figure 6 and Figure 7 show the toilet in a section along the B-B plane. In this section, the shape of the bottom of bowl 1 is clearly visible.

Figure 8 and Figure 9 show the toilet in a section along the C-C plane. Here you can see that siphon 3 is located in the lower part of bowl 1 and is connected to the rear drain 4. In Fig. 8 and Fig. 9 it is clearly visible that the inner surface of the upper edge 6 of bowl 1 is formed in the form of a fragment of a flat (not curved) ring, and through the upper threshold 12 passes into the further part of the bowl 1. The upper threshold 12 occupies slightly more than half of the bowl 1, and in the rear part of the bowl 1 it is less protruding. This structure allows the water jet to be directed in a spiral manner into the bowl 1. In addition, the protrusion 11 also directs the water jet in a suitable manner. The upper edge 6 extends above the upper threshold 12 in a section corresponding to the length of this upper threshold 6. The further part of the bowl 1, below the upper threshold 12, is curved, i.e. roughly the shape of a toilet. In places where there is no upper threshold 12 (on the opposite side of the bowl 1 relative to the C-C plane to this upper threshold 12), the bowl 1 is curved - approximately in the shape of a toilet bowl.

Of course, you cannot limit yourself to only the above options. For example, one can imagine that channel 9, together with the mouth of channel 10, will be directed in opposite directions than in the figure - in other words, that the toilet design will be a mirror image of the design shown in the figures.

The rotating jet of water in the bowl 1 can continuously cover a relatively large surface area around the water level. In this embodiment, the water flow is directed from the mouth 10 of the channel 9 inward, so it first enters the rear central region of the inner part of the bowl 1 (as shown in the figure), where particularly heavy contamination is possible.

The toilet, according to the utility model, functions exclusively gravimetrically, that is, exclusively using gravity and the kinetic energy of water. This means that there is no need to use an internal pump to supply water to the toilet, and therefore the toilet is relatively cheap to manufacture and is also more economical in terms of operating costs.

The rotational movement of the water jet, that is, the trajectory of the jet, is determined by the tangential direction of the flow of flushing water from the inlet 7 and the internal shape of the bowl 1, while the downward movement is due to gravity. The lateral (asymmetrical) inlet of the water flow into the bowl and its internal shape mean that the water flow has a relatively high kinetic energy and is fed into siphon 3 with great force. Consequently, the flushing action is effective both on the inner surface of the bowl 1 and in the deeper one. lower area, directly above siphon 3.

In the toilet, according to the utility model, a static or dynamic siphon can be used, with the static siphon being more preferable. A dynamic siphon is, for example, a solution in which, by artificially narrowing or interrupting the drainage, for example by means of a flap valve, water is artificially accumulated in the bowl in order to then ensure a relatively rapid drainage using a siphon effect. Thus, a dynamic siphon contains moving parts that influence the flow of the drain.

The toilet in question may be made using various methods of supplying flush water at a certain pressure - for example, without a float valve (pressurized) or, more preferably, may have a combination system with a float valve, because in this case potential energy can be better used rinsing water. This refers to the float valve in the mounting wall behind the toilet.

The water in the bowl 1, as already mentioned, first falls onto the back of the upper edge 6, after which it flows in a rotational motion down the bowl 1 to the outlet 2, while along the way it is divided and supported in the bowl 1 by the upper threshold 12 or the upper threshold 12 and lower threshold 13. During this vortex descent in a spiral, the water makes a maximum of 1.5 revolutions inside the bowl, after which it enters the outlet 2 at the water level.

Claims (20)

1. A toilet with a rimless bowl flush system (1), with a flush water supply at the upper rear of the bowl (1) containing an inlet pipe (8) ending in an inlet (7) and a channel located behind it (9) ending in an outlet (10), in which the outlet (2) for the siphon (3) is located in the lower part of the bowl (1), while the toilet has a first central plane (A-A), which, when the toilet is assembled, is parallel to the mounting wall and mentally divides the toilet through the center of the outlet (2) to the front and rear parts, with the rear part adjacent to the mounting wall, and a second central plane (C-C) perpendicular to it, mentally dividing the toilet through the center of the outlet (2) into right and left parts, in this case, the bowl (1) has an upper edge (6), which is a fragment of the upper inner surface of the bowl (1) with almost vertical walls, located directly below the lid (5), above the upper edge (6) there is a lid (5), and the outlet (2) is shifted to the rear of the toilet, and at the same time the mouth (10) of the channel (9) is located asymmetrically relative to the second central plane (C-C) in the upper part of the bowl (1) in such a way as to allow flush water to enter bowl (1), falling first onto the back of the upper edge (6) in a horizontal direction and tangentially to the inner surface of the bowl (1), and then performing a rotational movement of water inside the bowl (1), and at the same time the bowl (1 ) on its inner side, at the height of the mouth (10) and just below the upper edge (6), has a horizontally located upper threshold (12), formed in the form of a convexity, characterized in that the beginning of the upper threshold (12) is at the level of the mouth (10), then it passes inside the bowl (1) to the side in accordance with the direction in which the mouth (10) is directed, and the end of this upper threshold (12) is opposite the mouth (10 ), on the opposite side of the bowl (1) relative to the first central plane (A-A), in this case, the bowl (1) on the side opposite to the side containing the upper threshold (12) has the shape of a smooth arc, wherein the upper edge (6) is made in the form of a flat segment of an elliptical ring, and this segment is located directly above the upper threshold (12), in a section whose length, measured horizontally, corresponds to the length of the section occupied by the upper threshold (12), and at the same time, below the upper threshold (12), and above the level of the water surface in the state of the operating toilet, the bowl (1) has a lower threshold (13) in the form of a convexity, and the beginning of this lower threshold (13) is located in the rear part of the bowl ( 1), then it passes to the side in accordance with the direction in which the mouth (10) is directed, and the end of this lower threshold (13) is located on the opposite side of the bowl (1) relative to the beginning of this lower threshold (13) so that it essentially located on half of the rim of the bowl (1). 2. Toilet according to claim 1, characterized in that the upper threshold (12) ends in a gentle manner and goes into the rounding of the bowl (1). 3. Toilet according to claim 1 or 2, characterized in that the height of the upper threshold (12), measured vertically, is 4 mm, the width of the upper threshold, measured horizontally, is 9 mm, and the radius of curvature of the upper threshold (12) in a plane perpendicular to the inner surface of the bowl (1) is 13 mm, and the radius of curvature of the arc between the upper edge (6) and the beginning of the upper threshold (12) in the above plane is 17 mm. 4. Toilet according to paragraphs. 1, 2 or 3, characterized in that the lower threshold (13) has a radius of curvature in a plane perpendicular to the inner surface of the bowl (1), ranging from 32 to 66 mm. 5. Toilet according to any of the previous paragraphs, characterized in that the lower threshold (13) is less than half the distance from the upper threshold (12) to the water level, preferably 2/3 of the distance from the upper threshold (12) to the water level. 6. A toilet bowl according to any of the previous paragraphs, characterized in that the channel (9) is inclined inside the toilet bowl so that its starting point (A) is higher than the end point (B), and the difference in position is between the end point (A) and the end point (B) is from 23 mm to 27 mm, preferably 25 mm. 7. A toilet bowl according to any of the previous paragraphs, characterized in that the mouth (10) of the channel (9) is located to the right or left of the bowl (1). 8. A toilet bowl according to any of the previous paragraphs, characterized in that the first section of the channel (9) behind the inlet hole (7) is directed towards the right or left side of the toilet bowl and is slightly curved in accordance with the shape of the upper edge (6), in addition, has a bend approximately 180°, as a result of which the mouth (10) is located on the right or left of the bowl (1), but is directed in the opposite direction than the mentioned first section of the channel (9), and therefore, respectively, to the left or right side. 9. A toilet bowl according to any of the previous paragraphs, characterized in that the cross-sectional area of the inlet (7) for flushing water is from 15.5 to 16.5 cm ² , preferably 16.04 cm ² . 10. A toilet according to any of the previous paragraphs, characterized in that the cross-sectional area of the channel (9) in the part between the inlet (7) and the bend is from 16 to 17.5 cm ² , preferably 16.81 cm ² . 11. A toilet bowl according to any of the previous paragraphs, characterized in that the channel (9) is flattened in cross-section, that is, longer in the vertical direction and more narrowed at the mouth (10). 12. Toilet according to claim 10 or 11, characterized in that the channel (9) is rectangular in cross section. 13. Toilet according to claim 11 or 12, characterized in that the ratio of the height of the vertically extending mouth (10) to the width of this mouth (10) is from 4.0 to 4.12, preferably 4.06. 14. Toilet according to claim 13, characterized in that the height of the mouth (10) is from 68 to 74 mm, preferably 71 mm, and the width of the mouth (10) is from 17 to 18 mm, preferably 17.5 mm. 15. Toilet bowl according to any of the previous paragraphs, characterized in that the channel (9) has a bend with a radius of curvature from 27 to 40 mm. 16. Toilet bowl according to any of the previous paragraphs, characterized in that the lower threshold (13) is located at a distance of at least 15.5 cm, preferably 17.3 cm from the upper edge (6) of the bowl (1), and this distance is measured in a straight line , vertically, from the edge of the upper edge (6) of the bowl (1) to the level of the lower threshold (13), at which the lower threshold is located.