WO2024207033A1 - Device for analysing urine, and separation toilet having such a device - Google Patents

Abstract

The invention relates to a device for analysing urine (22) for connection to the drainage region of ​​a urinal or to a secondary discharge line (1) of a separation toilet (2), the device comprising a pipe portion having an inlet (3), which can be connected to the urinal or to the secondary discharge line (1) of the separation toilet (2), and an outlet (4), which is located at the other end of the pipe portion, for connection to further drainage lines. The pipe portion comprises a measuring portion (5) which, in the installed state, is situated below the inlet (3) and the outlet (4) and is designed as a U-shaped siphon, wherein a first measuring region (6) for at least a first sensor (7) is provided adjacent to the inlet (3) in the descending leg of the siphon and a second measuring region (8) for at least a second sensor (9) is provided within the lower bend portion of the U-shaped portion. The invention further relates to a separation toilet (2) having such a device connected to a secondary discharge line (1).

Description

DEVICE FOR ANALYSIS OF URINE AND SEPARATE TOILET WITH SUCH A DEVICE technical field

The invention relates to a device for analyzing urine for connection to the drain area of a urinal or to a secondary drain of a composting toilet, comprising a pipe section with an inlet that can be connected to the urinal or to the secondary drain of the composting toilet, and an outlet located at the other end of the pipe section for connection to further drain lines. The invention further relates to a composting toilet equipped with such a device.

State of the art

In the state of the art, various toilet facilities and urinals are known which are connected to measuring systems for urine analysis. Different sensors or test strips are used for the measurements to be carried out. The sample is taken or measured directly in or on the drain pipe, as is the case, for example, in the DE 102015214926 A or a sample is taken from an area of the mussel for the measuring system, as is the case, for example, in the WHERE WO 2008/082027 A is disclosed. The more automated the systems are to be, the more complex the sampling must be in order to be able to carry out consecutive measurements correctly. When measurements are taken directly in the drain, the flow time is too short for more complex measurements, which is why only a few values can be read out. Systems with separate sampling openings for urine are complex special designs and either cannot be flushed sufficiently between individual measurements or require additional mechanical valve devices, pumps or the like, as well as specially designed shells for sampling. Due to this high level of effort, such devices for the automated measurement of urine have so far only been implemented to a limited extent in the medical field.

representation of the invention

The object of the present invention is therefore to create a device for analyzing urine which can also be retrofitted to existing toilets and urinals and which enables sample taking and automated measurement in a simple manner. The device should be inexpensive to manufacture and be able to forward the measurement results via appropriate interfaces. Ideally, the device can be designed as an autonomous module and can be used over longer periods with little maintenance effort.

This object is achieved by the present invention in that the pipe section comprises a measuring section which is located below the inlet and the outlet in the installed state and is designed as a siphon in a U-shape, with a first measuring area for at least one first sensor being provided adjacent to the inlet in the descending leg of the siphon and a second measuring area for at least one second sensor being provided within the lower bend section of the U-shaped section. The measurements can thus be carried out in quick succession, with the system automatically recalibrating itself with each flush cycle. In a device according to the invention, at least two measuring areas are provided in the siphon for the measurement, with various sensors, such as pH probes, photosensitive sensors or the like, being arranged in the area of the lowest point and upstream of it. It was surprisingly found that when the toilet is used, the urine sample does not experience any significant dilution in the area of the siphon defined with the corresponding volume, but can be used for a measurement. During the flushing process, the siphon is completely rinsed out and all sensors are recalibrated for further use using the clear flushing water. The first measuring range can also be used to detect when a measurement begins, activating the sensors further downstream when the first sensor measures a change.

According to a further preferred feature, it is provided that the at least two sensors are connected to a control unit, wherein the control unit serves to process the measurement data received from the sensors and, if necessary, to compare them with stored values, and wherein the control unit has a communication interface, preferably for wireless communication, in order to transmit the determined or processed data to a terminal device. Via the control unit with a corresponding interface, either the raw measurement data or already processed data can be transmitted, for example to a display in the toilet area or to a terminal device, such as a smartphone. Conversely, settings on the control unit can also be made via the terminal device. The entire device, including the siphon, electronics with interfaces, sensors and power supply, can also be very easily retrofitted as a compact module to existing separation toilets or urinals. Thanks to the self-contained structure, a health toilet can be created cost-effectively in a wide variety of areas, which can carry out continuous measurements and is particularly user-friendly in terms of operation and maintenance.

Another advantageous feature is that the control unit can be connected to an electronically controlled flush of the urinal or the separate toilet in order to take over the flush control. Some sensors require more time for the measurement process than might be possible when using the toilet. When linked to an electronically controlled flush, a flushing process initiated by the user can be delayed accordingly, or manual flushing by the user is not required at all, as the control unit carries out the flush automatically after the measurement has been taken.

According to a preferred embodiment, a temperature sensor is provided in the first measuring area. This represents a particularly simple way of triggering a measuring process via the first sensor located upstream in the siphon. The temperature sensor measures an increase in the liquid temperature and then triggers the further measurements by the downstream sensors via the control unit with a corresponding delay.

In a further preferred embodiment, an optical sensor with a transmitter for electromagnetic waves and an opposite receiver is provided in the first measuring area, with a pipe section of the first measuring area being designed as a cuvette through which the electromagnetic waves can pass. Different parameters can be read out using a photosensitive sensor depending on the wavelength of the transmitter. By shining a light through the cuvette, turbidity can also be detected very easily, which can also be used as a trigger signal for the other sensors located downstream.

According to a further preferred embodiment, an electrical sensor is arranged in the second measuring area, which determines, for example, the pH value in the U-shaped pipe section. After the inflowing urine has displaced the previously present flushing water in the direction of the outlet, the measurement can be carried out here at an optimal concentration.

A further preferred embodiment provides that a sampling opening is provided in the second measuring area, to which a line with a pump is connected, which supplies a sample quantity taken to a measuring unit connected to the line, with a further discharge line running from the measuring unit back to the outlet area of the device in order to discharge the sample back into the outlet after the measurement has been carried out. If more complex measurements are to be carried out, for example by adding measuring strips or additional reagents, then it can be advantageous to take a sample at the corresponding point in the second measuring area after the measurement process has been triggered by detecting incoming urine in the first measuring area and to pass it on to a measuring unit. This measuring unit can be equipped, for example, with a magazine of measuring strips or a reservoir for adding further reagents as well as the corresponding measuring sensors and the corresponding measuring electronics. Sampling via a line with a pump has the further advantage that correspondingly time-consuming measurements can be carried out while the siphon of the device is already being flushed. After a rinse cycle, water can be taken from the siphon filled with fresh rinse water via the sampling opening in order to also rinse the line and the measuring unit.

Finally, the invention relates to a separation toilet comprising a shell with a pipe section connected in the drainage area with at least partially approximately vertical side walls, wherein a separate secondary drain is provided for separating urine, and wherein the inlet opening of the secondary drain is arranged on one side of the vertical side wall of the pipe section and thus below the shell and is rounded in the transition area at the upper edge of the inlet opening of the secondary drain to the vertical side wall of the pipe section, wherein a device for analyzing urine is connected to the secondary drain as described above. Such a separation toilet without a corresponding device for analyzing urine is disclosed, for example, in WO 2019178622 A1. This separation toilet has the advantage that a large part of the urine that occurs is led into the secondary drain without complex valves or visible separating structures within the shell. The secondary drain provided is particularly suitable for connecting a device according to the invention for analyzing urine. During the rinsing process, enough rinsing water enters the device via the teapot effect at the inlet opening of the secondary drain to completely rinse out the siphon and reset it for the next measuring process.

Short description of the drawings

The invention will now be described in greater detail using embodiments and with the aid of the accompanying figures.
Fig. 1 to Fig. 3 schematically show a sectional view of a device according to the invention at different times during a measuring process,
Fig. 4 is a schematic perspective view of another embodiment of a device according to the invention,
Fig. 5 is a schematic perspective view with circuit diagram of another alternative embodiment of a device according to the invention and
Fig. 6 is a schematic sectional view through a separation toilet according to the invention with a connected device for analyzing urine.

way(s) of carrying out the invention

A device according to the invention is shown schematically in Figs. 1 to 3. The pipe section of the device has an inlet 3 and an outlet 4. Between them is the measuring section 5 designed as a U-shaped siphon. Because the measuring section 5 is designed as a siphon, there is always liquid in this section, be it urine during a measurement or flushing water. The siphon also serves as an odor trap for the waste water pipe located downstream of the outlet 4. Fig. 1 shows schematically the start of a measuring process, in which urine 22 comes from the inlet 3 into the descending leg of the siphon in the first measuring area 6 and displaces the flushing water in the direction of the outlet 4. In the first measuring area 6, a first sensor 7 detects the inflowing urine 22. A temperature sensor can be provided as a sensor, for example, which detects the temperature increase and thus signals a control unit (not shown) to carry out a measuring process.

Fig. 2 shows the following time period in which the inflowing urine completely fills the siphon and has largely displaced the flushing water. Surprisingly, it has been shown that a slight dilution of the urine with flushing water has hardly any effect on the desired measurements and can therefore be neglected, which significantly simplifies the entire supply and sampling process. In the second measuring area 8 there is at least one further sensor 9, such as a pH value sensor, which provides further measurement data.

After the measurement is completed, a flushing process is triggered either manually or by the control unit and fresh flushing water comes from the inlet 3 into the measuring section 5 and displaces the urine 22 towards the outlet 4. This situation is shown in Fig. 3. The measurement data can be processed by the control unit and are then preferably transmitted wirelessly to a terminal device, such as a display in the area of the toilet or urinal or such as a smartphone.

Fig. 4 shows a further embodiment of a device according to the invention, in which a narrowed pipe section designed as a cuvette 12 is provided in the first measuring area 6. A transmitter 10 for electromagnetic waves and a receiver 11 are provided on two opposite sides of the cuvette 12. The urine 22 flowing through the cuvette 12 can thus be optically measured. At the same time, the receiver 11 can also detect the start of a measuring process by a change in state in order to activate sensors located further downstream in the second measuring area 8 via the control unit. During flushing, the receiver 11 is recalibrated against an initial value.

Fig. 5 shows a schematic representation of a further embodiment of the invention. Not only is more time required for some measurements, which can be regulated via an electronic flushing control via the control unit, but for the measuring process, for example, reagents must be added to the urine 22 or test strips must be wetted. Since these reagents represent a more expensive consumable, it is desirable to keep the sample quantity low. Even in existing automated systems with measuring strips, the measuring strips are usually a consumable supplied in the form of cassettes, which are wetted with only small amounts of urine 22. For this reason, it is advantageous to provide a sample extraction opening 13 in the second measuring area 8. A small amount of urine 22 is fed to a measuring unit 16 via a pump 15 via a line 14 connected to the sample extraction opening 13. Depending on the application, different analyses can then be carried out in this measuring unit 16, whereby the automatic addition of reagents and/or measuring strips is also possible. After the measurement has been completed, the sample is returned to the pipe section via a drain 17 near the outlet 4 and disposed of. By branching off a sample for the measuring unit 16, the measuring section 5 can also be rinsed again before the measurement is completed.

Finally, Fig. 6 shows the integration of a device according to the invention into a separation toilet 2, as disclosed, for example, in WO 2019178622 A1. Such a separation toilet 2 has a shell 18, which in the upper area does not differ from a conventional toilet shell and is therefore similarly easy to clean. In the drainage area 19 below the shell 18 there is a section with at least approximately vertical side walls 20. On one side of these side walls 20 there is the inlet opening 21 of a secondary drain 1. The transition area at the upper edge of the inlet opening 21 of the secondary drain 1 and the vertical side wall 20 is rounded so that at this point a large part of the draining urine 22 is led into the secondary drain 1 via the teapot effect. The secondary drain 1 is connected downstream to the inlet 3 of a pipe section designed as a siphon of a device for analyzing urine 22. As already described above, the desired measurements can be carried out via the measuring section 5, comprising the first 6 and second measuring section 8, depending on the sensors 7, 9, 11 present or by means of an existing measuring unit 16. The outlet 4 can either be returned to the normal drainage area 19 or the urine discharged via the secondary drainage line 1 can be used for other purposes.

Claims (8)

Device for analyzing urine (22) for connection to the drainage area of a urinal or to a secondary drain (1) of a composting toilet (2), comprising a pipe section with an inlet (3) that can be connected to the urinal or to the secondary drain (1) of the composting toilet (2), and an outlet (4) located at the other end of the pipe section for connection to further drainage lines, characterized in that the pipe section comprises a measuring section (5) located below the inlet (3) and the outlet (4) in the installed state and designed as a siphon in a U-shape, wherein a first measuring area (6) for at least one first sensor (7) is provided adjacent to the inlet (3) in the descending leg of the siphon, and a second measuring area (8) for at least one second sensor (9) is provided within the lower bend section of the U-shaped section. Device for analyzing urine (22) according to claim 1, characterized in that the at least two sensors (7, 9) are connected to a control unit, wherein the control unit serves to process the measurement data received from the sensors (7, 9) and, if necessary, to compare them with stored values, and wherein the control unit has a communication interface, preferably for wireless communication, in order to transmit the determined or processed data to a terminal. Device for analyzing urine (22) according to claim 2, characterized in that the control unit can be connected to an electronically controllable flush of the urinal or the separation toilet (2) in order to take over the flush control. Device for analyzing urine (22) according to one of claims 1 to 3, characterized in that a temperature sensor is provided at the first measuring region (6). Device for analyzing urine (22) according to one of claims 1 to 4, characterized in that an optical sensor with a transmitter (10) for electromagnetic waves and an opposite receiver (11) is provided on the first measuring region (6), wherein a tube section of the first measuring region (6) is designed as a cuvette (12) through which the electromagnetic waves can pass. Device for analyzing urine (22) according to one of claims 1 to 5, characterized in that an electrical sensor (9) is arranged on the second measuring area (8), which determines, for example, the pH value in the U-shaped pipe section. Device for analyzing urine (22) according to one of claims 1 to 6, characterized in that a sample removal opening (13) is provided on the second measuring region (8), to which a line (14) with a pump (15) is connected, which feeds a sample quantity taken to a measuring unit (16) connected to the line (14), wherein a further discharge line (17) runs from the measuring unit (16) back to the outlet region of the device in order to discharge the sample back into the outlet (4) after the measurement has been carried out. Separate toilet (2) comprising a shell (18) with a pipe section connected in the drainage area (19) with at least partially approximately vertical side walls (20), wherein a separate secondary drain (1) is provided for separating urine (22), and wherein the inlet opening (21) of the secondary drain (1) is arranged on one side of the vertical side wall (20) of the pipe section and thus below the shell (18) and is rounded in the transition area at the upper edge of the inlet opening (21) of the secondary drain (1) to the vertical side wall (20) of the pipe section, characterized in that a device for analyzing urine (22) according to at least one of claims 1 to 7 is connected to the secondary drain (1).

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