EP4248028A1 - Vacuum toilet - Google Patents

Abstract

The invention relates to a vacuum toilet with a toilet bowl (10), a transfer tank (12), and a flushing water container (14). The flushing water container (14) is designed and connected such that a flushing process is triggered when the toilet is actuated, wherein flushing water is conveyed into the toilet bowl (10) from the flushing water container via a first flushing water line (16) using positive pressure, which is applied in the flushing water container (14) by a compressed air source (21), and the transfer tank (12) is designed and connected such that after the flushing process, a suction material is suctioned out of the toilet bowl (10) and into the transfer tank (12) using negative pressure which is applied to the transfer tank (12). The invention is characterized in that flushing water is conveyed into the transfer tank (12) by means of a second flushing water line (18), which is supplied by the first flushing water line and which has a controllable valve (Q07), when the controllable valve (Q07) opens the second flushing water line (18) in order to flush the transfer tank (12).

Description

vacuum toilet

The present invention relates to a vacuum toilet which has a toilet bowl, a transfer tank and a flushing water tank. The flushing water tank is designed and connected in such a way that when the toilet is actuated, a flushing process is triggered, in which, with the help of an overpressure applied in the flushing water tank by a compressed air source, flushing water is conveyed from this via a first flushing water line into the toilet bowl. The transfer tank is designed and connected in such a way that, after the flushing process, suction compound is sucked out of the toilet bowl using a negative pressure applied to the transfer tank.

Vacuum toilets are used, for example, as toilets in vehicles (e.g. rail vehicles, airplanes, water vehicles, buses, etc.) and offer the possibility of sucking suction mass out of the toilet bowl into a transfer tank with the help of a vacuum and then finally passing it on to a waste water reservoir .

Such a vacuum toilet is known, for example, from DE 20 202 101 760 U1. The vacuum toilet includes a toilet bowl, a transfer tank, and a flush tank. The flushing water tank is designed and connected in such a way that when the toilet is actuated, a flushing process is triggered, in which, with the help of an overpressure applied in the flushing water tank by a compressed air source, flushing water is conveyed from this via a first flushing water line into the toilet bowl. The transfer tank is designed and connected in such a way that, following the flushing process, suction mass is sucked out of the toilet bowl into the transfer tank using a negative pressure applied to the transfer tank. In such a vacuum toilet, impurities can accumulate in the accumulate in the transfer tank, which eventually even lead to a blockage of the vacuum toilet.

It is therefore the object of the present invention to provide a vacuum toilet in which the contamination in the transfer tank is reduced in order to prevent the vacuum toilet from becoming clogged.

This problem is solved by a vacuum toilet with the features of claim 1 . Advantageous embodiments are defined in the dependent claims.

According to the present invention, there is a second flushing water line fed by the first flushing water line. This second rinsing water line has a controllable valve that can release or block the rinsing water flow in the second rinsing water line.

When the controllable valve opens the second flushing water line, flushing water is conveyed into the transfer tank and the transfer tank is flushed.

In the context of the present invention, the term “suction mass” is understood to mean the mass that is removed from the toilet bowl when it is flushed. The suction mass can contain flushing water as well as faeces and other components.

The second flushing water line preferably branches off from the first flushing water line via a connection in the form of a T-piece. The flushing water flows from the first flushing water line z. B. into the vertical branch of the T-piece shape and divides into two flushing water streams in the T-piece shape, by one flushing water stream, which continues to form the flushing water stream of the first flushing water line, e.g. B. through the left horizontal branch, and the second rinse water stream, which is the rinse water stream of the second flushing water line flows out through the right horizontal branch of the tee shape.

The transfer tank preferably has a rinsing nozzle with a plurality of nozzle openings that is fed by the second rinsing line. This rinsing nozzle device in the transfer tank ensures that as many as possible and ideally all areas of the inner wall of the transfer tank are rinsed.

In one embodiment of the present invention, the first flushing water line is also provided with a controllable valve. The two controllable valves on the flushing water lines can be controlled independently of one another. This allows the flow of flushing water to be routed in different ways. If the valve of the first flush water line is open and the valve of the second flush water line is closed, flush water can flow from the flush water tank into the toilet bowl but not into the transfer tank. If the valve of the first flush water line is closed and the valve of the second flush water line is open, flush water can flow into the transfer tank but not into the toilet bowl. If both valves are open, flushing water can flow into the transfer tank and into the toilet bowl.

In a further embodiment of the present invention, the controllable valve of the second flushing water line is designed as a 3/2-way valve. As a result, either flushing water can flow from the first flushing water line into a continuation of the first flushing water line into the toilet bowl or from the first flushing water line via the second flushing water line into the transfer tank.

The controllable valves are preferably solenoid valves. Further preferred embodiments relate to an electronic control device that the vacuum toilet has. This control device is programmed to control the compressed air source and the controllable valve of the second flushing water line in such a way that the transfer tank is flushed under predefined conditions.

In one embodiment of the present invention, the control device is set up to check the number of flushing processes of the toilet bowl after the last flushing of the transfer tank as a predefined condition. After a predetermined number of flushing processes, the control device controls the compressed air source and the controllable valve on the second flushing water line in such a way that a separate flushing process is carried out for the transfer tank.

In an alternative embodiment of the present invention, the control device is set up to check the number of flushing processes of the toilet bowl after the last flushing of the transfer tank as a predetermined condition. After a predetermined number of flushing processes, the control device controls the compressed air source and the controllable valve on the second flushing water line in such a way that the transfer tank is flushed at the same time as the next flushing process of the toilet bowl.

As a preferred alternative, the control device is set up to check the elapse of a predetermined regular time interval as a predetermined condition. After this time interval has elapsed, the control device controls the compressed air source and the controllable valve of the second flushing water line in such a way that the transfer tank is flushed. In a further alternative embodiment of the present invention, the control device is set up to check, as a predefined condition, whether there is a frost emptying signal for the vehicle. The frost emptying signal is triggered before the train closes, for example, in order to empty all water-carrying pipes and containers. If this signal is present, the control device controls the compressed air source and the controllable valve of the second flushing water line in such a way that the flushing water that is drained is used to flush the transfer tank. This ensures that the transfer tank is cleaned before the vacuum toilet is not used for a longer period of time in order to prevent deposits from solidifying in the transfer tank.

The invention is explained below with reference to an exemplary embodiment shown in the figures. Show it :

Figure 1 shows a schematic structure of the vacuum toilet with a controllable valve on the second flushing water line,

FIG. 2 shows a schematic structure of the vacuum toilet with a controllable valve on the second flushing water line and a controllable valve on the first flushing water line,

Figure 3 shows a schematic structure of the vacuum toilet with a controllable valve on the second flushing water line, which is designed as a 3/2-way valve.

A vacuum toilet is described below with reference to FIGS. The vacuum toilet includes a toilet bowl 10 , a transfer tank 12 and a flush water tank 14 . The flushing water tank 14 has a fill level sensor B02 which is coupled to a valve Q06. If the filling level sensor B02 indicates that there is not enough rinsing water in the rinsing water tank 14, the valve Q06 is opened and the rinsing water tank 14 is filled via a rinsing water line 20 coming from a fresh water reservoir.

The flushing water tank 14 is designed and connected in such a way that a flushing process is triggered when the toilet is actuated. In this case, compressed air is conducted via a compressed air line 22 coming from the compressed air source 21 via a flushing valve Q01 and a valve 24 into the interior of the flushing water tank 14 . As a result, flushing water is conveyed from the flushing water container 14 into the toilet bowl 10 via a first flushing water line 16 . At the end of the flushing process, the supply of compressed air to the flushing water tank 14 is stopped, whereupon the setting of the valve 24 changes. There is then still overpressure in the flushing water tank 14 . Due to the changed setting of the valve 24, the ventilation line 26 is accessible, via which the overpressure prevailing in the flushing water tank 14 can be released.

The transfer tank 12 is designed and connected in such a way that after the flushing process, the inlet valve Q05 is opened and suction mass is sucked out of the toilet bowl 10 into the transfer tank 12 using a vacuum applied to the transfer tank 12 . The inlet valve Q05 is then closed again and an overpressure is generated in the transfer tank 12 . The outlet valve Q04 is then opened and the suction mass located in the transfer tank 12 is conveyed by the overpressure applied to the transfer tank 12 into a waste water reservoir connected to the transfer tank 12 . The vacuum or the overpressure in the transfer tank 12 is controlled via the pressure valve Q02 and the vacuum valve Q03. A second flushing water line 18 is connected in such a way that it is fed through the first flushing water line 16 . The second flushing water line 18 has a controllable valve Q07 which can release or block the flow of flushing water in the second flushing water line 18 . When the controllable valve Q07 opens the second flushing water line 18, flushing water is conveyed into the transfer tank 12 and the transfer tank 12 is flushed.

The second flushing water line 18 branches off from the first flushing water line 16 via a connection in the form of a T-piece 17 . The flushing water of the first flushing water line 16 flows z. B. into the vertical branch of the T-piece shape 17 and is divided into two flushing water streams in the T-piece shape 17 by one flushing water flow, which continues to form the flushing water flow of the first flushing water line 16, e.g. B. through the left horizontal branch, and the second flushing water flow, which forms the flushing water flow of the second flushing water line 18, flows out through the right horizontal branch of the T-piece mold 17.

FIG. 2 shows an embodiment of the present invention in which the first flushing water line 16 is also provided with a controllable valve Q08. The two controllable valves Q07 and Q08 can be controlled independently of one another. This allows the flow of flushing water to be routed in different ways. If the valve of the first flush water line Q08 is opened and the valve of the second flush water line Q07 is closed, flush water can flow from the flush water tank 14 into the toilet bowl 10 but not into the transfer tank 12 . If the valve of the first flush water line Q08 is closed and the valve of the second flush water line Q07 is open, flush water can flow into the transfer tank 12 but not into the toilet bowl 10 . If both valves Q07 and Q08 are open, flushing water can flow into the transfer tank 12 and into the toilet bowl 10.

FIG. 3 shows a vacuum toilet in which the controllable valve of the second flushing water line Q07 is designed as a 3/2-way valve. As a result, either flushing water can flow from the first flushing water line 16 in a continuation of the first flushing water line into the toilet bowl 10 or from the first flushing water line 16 via the second flushing water line 18 into the transfer tank 12 .

Claims

Protection claims Vacuum toilet with a toilet bowl (10), a transfer tank (12) and a flushing water tank (14), wherein the flushing water tank (14) is designed and connected in such a way that when the toilet is actuated, a flushing process is triggered, in which, with the aid of a flushing water tank (14) by means of an overpressure applied by a compressed air source (21), flushing water is conveyed from this via a first flushing water line (16) into the toilet bowl (10), and the transfer tank (12) is designed and connected in such a way that following the flushing process Suction mass is sucked out of the toilet bowl (10) into the transfer tank (12) with the aid of a negative pressure applied to the transfer tank (12), characterized in that a second flushing water line (18) fed through the first flushing water line and having a controllable valve (Q07) Flushing water is pumped into the transfer tank (12) when the controllable valve (Q07) connects the second flushing water line (18) opens to flush the transfer tank (12) . Vacuum toilet according to Claim 1, characterized in that the second flushing water line (18) branches off from the first flushing water line (16) via a connection in the form of a T-piece (17). Vacuum toilet according to claims 1 and 2, characterized in that the transfer tank has a through the second rinsing line fed rinsing nozzle with a plurality of nozzle openings arranged in a distributed manner. Vacuum toilet according to Claims 1, 2 and 3, characterized in that the first flushing water line (16) is also provided with a controllable valve (Q08) and the two controllable valves can be controlled independently of one another, so that when the valve of the first flushing water line (Q08 ) is open and the valve of the second flush water line (Q07) is closed, flush water can flow from the flush water tank (14) into the toilet bowl (10) but not into the transfer tank (12), and when the valve of the first flush water line (Q08) is closed and the valve of the second flush water line (Q07) is open, flush water can flow into the transfer tank (12) but not into the toilet bowl (10), and when both valves are open, flush water into the transfer tank (12) and into the toilet bowl (10) can flow. Vacuum toilet according to Claim 1, characterized in that the controllable valve of the second flushing water line (Q07) is designed as a 3/2-way valve which either flushes water from the first flushing water line (16) into a continuation of the first flushing water line into the toilet bowl (10) conducts or conducts flushing water from the first flushing water line (16) via the second flushing water line (18) into the transfer tank (12). Vacuum toilet according to the preceding claims, characterized in that the controllable valves are solenoid valves. Vacuum toilet according to the preceding claims, characterized in that it has an electronic control device that is programmed to prepare - 11 - is to control the compressed air source (21) and the controllable valve of the second flushing water line (Q07) in such a way that the transfer tank (12) is flushed under predefined conditions. Control device according to Claims 4 and 7 or 5 and 7, characterized in that the control device is set up to check the number of flushing processes of the toilet bowl (10) after the last flushing of the transfer tank (12) and after a predetermined number as a predetermined condition of rinsing processes to control the compressed air source (21) and the controllable valve on the second rinsing water line (Q07) in such a way that a separate rinsing process for the transfer tank (12) is carried out. Control device according to Claims 1, 4 and 7, characterized in that the control device is set up to check, as a predetermined condition, the number of flushing processes of the toilet bowl (10) after the last flushing of the transfer tank (12) and after a predetermined number of flushing processes to control the compressed air source (21) and the controllable valve on the second flushing water line (Q07) in such a way that a flushing process for the transfer tank (12) is carried out at the same time as the next flushing process for the toilet bowl (10). Control device according to Claims 1, 4 and 7 or 1, 5 and 7, characterized in that the control device is set up to check the expiry of a specified regular time interval as a specified condition and to activate the compressed air source (21) and the controllable valve when it expires to control the second rinsing water line (Q07) in such a way that a rinsing process for the transfer tank (12) is carried out. Control device according to Claims 1, 4 and 7 or 1, 5 and 7, characterized in that the control device is set up to check as a predetermined condition whether a frost emptying signal is present and, if the signal is present, the compressed air source (21) and the controllable valve of the to control the second rinsing water line (Q07) in such a way that a rinsing process for the transfer tank (12) is carried out with the rinsing water that is discharged.