DE102004033130A1 - Automatic flushing control for urinal has electrodes to monitor the concentration in the water trap and the concentration in the overflow - Google Patents

Abstract

An automatic flushing control for a urinal has a pair of electrodes (1, 3) in the water trap to monitor the concentration of impurities in the water and with a third electrode (2) at the overflow to monitor the change in impurity concentration during the flushing process. The flushing process is stopped when the impurity concentration falls to a clean reference level. A timing control ensures that the flushing process does not exceed a programmed interval.

Description

The The invention relates to a method for controlling the flushing of a Urinals by measuring the degree of soiling of the odor trap Liquid.

From the DE 101 11 210 A1 For example, there is known a method for controlling the flushing of a urinal by measuring the conductance of the liquid in the trap with at least two electrodes, one of which is located as a reference electrode on the inlet side of the odor trap and the other on the outlet side over the overflow level. During use of the urinal, the reversal point of the conductance between the two electrodes is determined by increasing to falling values and subsequently a flushing process is triggered. For this method, the knowledge of the absolute value of the conductance between the two electrodes is not necessary, because the decrease of the conductance after previous increase indicates the end of use. The duration of the subsequent rinsing process determines a timer, which is set to a predetermined value. In addition, the known method may also evaluate a change in conductivity between the reference electrode and a third electrode located upstream of the level of the reference electrode and below the overflow level, eg, to initiate a flush when the liquid level on the inlet side of the odor trap is due to evaporation has fallen below a minimum level necessary for proper functioning.

With his fixed flushing time the known method is not found in practice Realities just. In particular, a water pressure that is higher leads as the for the dimensioning of the flushing time and thus the amount of water assumed minimum pressure, to an unnecessary additional consumption on water. Conversely, it comes at low water pressure and / or too small a line cross section as well as a renewed one Use of the urinal before completion of the flushing process to an insufficient flushing, with the consequence of hygienic problems, an odor nuisance and longer term also the formation of urine stone.

Of the Invention is based on the object, a method of the introductory to provide specified genus that automatically optimizes the rinsing time.

These Task is inventively achieved in that the degree of contamination of the liquid measured, the measured value corresponds to a reference value corresponding to a clean liquid compared and the rinsing process is terminated when the measured value of the degree of contamination about is equal to the reference value.

Of the The core of the proposed method is thus, the rinsing time in dependence to measure the degree of contamination of the liquid in the odor trap. This ensures that the flushing time always to the local Adapts to conditions, so the design of the urinal basin and the consequent need for rinse water, water pressure fluctuations, to the user behavior and the user frequency, so that under all circumstances a hygienic flushing is ensured without having more water than in each Individual case is necessary consumed.

Of the Pollution degree can in particular by measuring the conductance between a first as a reference electrode on the inlet side of the Odor-sealed arranged electrode and a second electrode be determined (claim 2).

there the second electrode may be beyond the overflow level of the odor trap be arranged on the outlet side (claim 3). Between this Electrode and the reference electrode is the usage-dependent change of the guide value, apart from certain special cases. Thereby simplifies the processing and evaluation of the measured values.

When Criterion for a finished use of the urinal may change the conductance between the reference electrode and the second electrode from rising to falling values are used (claim 4).

Prefers can the flushing process after a given delay time are triggered after use of the urinal (claim 5).

to Measurement of the degree of contamination during the flushing is the conductance between the reference electrode and the second electrode preferably measured several times in succession. (Claim 6). With increasing duration of flushing draw closer the measured conductivities increasingly approach the reference value reaching the flushing process is ended. It is useful the clock of the successive Leitwertmessungen with a predetermined Delay Time after the beginning of the flushing, d. H. opening of the solenoid valve in the water inlet, increased.

The reference value can be factory or be predefined by input to the controller, for example, during the initial installation of the urinal. However, for optimum adaptation to the local conditions, it is better if the reference value is set approximately equal to the conductance of clean water between the reference electrode and the second electrode (claim 7). This Referenzleitwert can be determined and stored, for example, in a programming mode of the control once after installation of the urinal. Another possibility is to determine the reference conductance by periodically repeated measurements with unused urinal and save.

At the best, however, is between the reference electrode and the second Electrode during a previous flush Last measured conductivity plus a tolerance value stored as a new reference conductance (claim 8th). This ensures that even sudden changes in the quality of the local Fresh or rinsing water Is taken into account and the duration of the flushing process adapts to this. The increase of respective current or new reference value by a tolerance value Make sure it is not due to measurement tolerances or a Deterioration of quality of the rinse water (corresponding to an increase its conductivity) come to continuous flushing operations can.

Instead of beyond the overflow level The second electrode can also be on the inlet side of the odor trap above the reference electrode but below the overflow level be arranged (claim 9). In this arrangement of the second electrode are the for the state of use and the flushing process though significant conductance changes less pronounced, qualitatively the same as in the case of the arrangement of the second Electrode beyond the overflow level.

Especially may be appropriate a combination of one (two th) electrode beyond the overflow level the odor trap on its outlet side and a (third) Electrode on the inlet side of the odor trap above the reference electrode and below the overflow level, because this allows by evaluating both the conductance between the reference electrode and the electrode beyond the overflow level and the conductance between the reference electrode and the electrode this is the overflow level to detect deviating states from the normal state of the urinal. Examples are the trigger a flush too when only a small amount of urine or a cleaning agent is introduced, recognizable by the fact that the conductance between the reference electrode and the electrode beyond the overflow level remains low, however, the conductance between the reference electrode and the electrode on this side of the overflow level rises and the triggering a rinse with lack of water in the odor trap because of long-term non-use and evaporation.

The Method according to the invention will be exemplified with reference to the drawing explained. It shows:

1 to 6 the use - dependent liquid levels and the time - dependent course of conductance in the odor trap of a urinal, which after the DE 101 11 210 A1 flushed with known methods,

7 the time-dependent course of the conductance at a fixed flush duration that matches the local conditions

8th the course of the conductance at fixed, but for the local circumstances too long flushing time

9 the time-dependent course of the conductance with two short successive uses of the urinal and fixed purging duration

10 a comparison of the time-dependent course of the conductance at a fixed, but for the local conditions too short flushing time and according to the invention even adaptive flushing duration

11 the same comparison, but with two short successive uses, the second use is made after the beginning of the flushing

12 the same comparison, but at the beginning of the second use even before the beginning of a rinsing process, and

13 the time-dependent course of the conductance in a development of the method by additional automatic determination of a reference value.

In the 1 to 6 is a generally conventional odor trap of a urinal shown. In the water-filled part there is a usually always wetted electrode 1 hereinafter referred to as the reference electrode. Beyond the overflow level Ü is a second electrode 2 normally not wetted when the urinal is unused. This side of the overflow Ü and above the reference electrode 1 is another, usually constantly wetted electrode 3 arranged. The electrodes 1 to 3 are connected to a control circuit, not shown, the conductance between the reference electrode and the first and evaluates the second electrode in the manner described in more detail below and depending on the results of a likewise not shown, conventional solenoid valve for the purpose of flushing the urinal opens and closes. In the diagrams, that is between the reference electrode 1 and the electrode 2 measured conductance as conductance 2 that is between the reference electrode 1 and the electrode 3 Measured conductance as conductance 3 designated.

In the case of 1 the urinal is unused until time t ₁ . Accordingly, the conductance 2 until time t ₁ below the measuring limit and the conductance 3 corresponds essentially to that of clean tap water between the reference electrode 1 and the third electrode 3 ,

According to 2 increases until the time t _2, the liquid level due to the amount of urine supplied to the overflow level. Accordingly, the conductance increases 3 while the conductance 2 remains low.

According to 3 becomes the electrode 2 wetted from the time t ₂ . Accordingly, the conductance begins 2 to rise while the conductance 3 continues to rise.

4 shows the condition toward the end of the use of the urinal, when the amount of urine supplied decreases. Accordingly, the increases in the conductivities are flattening 2 and 3 from. After use at time t ₃ exists between the reference electrode 1 and the second electrode 2 only a thin liquid film. Accordingly, the conductance has 2 reaches its maximum at time t ₃ and starts according to 5 from t ₃ to fall again while the conductance 3 essentially persisting at its constant high level.

This time t ₃ determines the controller, not shown, for. B. based on the reversal point of the course of the conductance 2 , and opens after an empirically determined delay time at time t _4, the usual solenoid valve until time t ₅ , ie for a fixed predetermined time during which the odor trap according to 6 essentially completely filled with water. Because of the renewed complete wetting of the second electrode 2 the conductance increases 2 from the time t ₄ briefly again. That being said, the guide values are falling 2 and 3 until the time t _s and beyond again to their initial values. For the conductance 2 this is close to the zero value according to the dashed curve, as soon as between the electrode 2 and the reference electrode 1 no moisture film is left.

The in 1 to 6 shown procedure is basically from the DE 101 11 210 A1 known.

The diagram according to 7 shows in an enlarged and more detailed representation the course of the conductance 2 during use of the urinal by a user A from t ₁ to t _3, t ₄ followed by a delayed start of the irrigation and flushing time t _x of t ₄ to t. ₅ Shortly after t ₁ , the beginning of the urine entry, the water, which was displaced over the overflow but still clean, wets the initially dry electrode 2 , As a result, the conductance increases 2 from (near) zero, first to the value L _s of clean water, stays briefly at that value and continues to increase according to the increasingly mixed with urine water. The flushing time t _x has been set at the factory as a precaution to a value that ensures sufficient flushing at a presumed minimum water pressure and for the most commonly used urinal basins.

In the case of 7 the assumed parameters are met exactly, so that at time t _s sufficiently rinsed, ie the value L _g just reached again. This fixed purge time t _x has according to 8th The consequence of this is that, in the case of a water-saving urinal basin and / or a higher than the assumed minimum water pressure, the flushing time t _x is too long by a time Δt because, like the course of the conductivity 2 shows, after t _x - Δt in the trap only clean water is. The water consumed during Δt is thus wasted. Not shown here is the opposite case, which occurs when the sink needs above average amount of water for a clean rinse or the water flow is too low due to low water pressure or line cross section. Then the set flushing time t _{x is} too short to ensure after the use of the urinal again a hygienic condition, see also 10 and their explanation.

Another problem occurs when shortly after a user A, a user B approaches the urinal while the flushing process initiated by the user A is still running. This case is in 9 shown. As a result of the additional urine input by the user B, which the controller does not recognize as such during the fixed rinse time, the urinal is not completely rinsed cleanly at the end of the rinse time, so the conductance 2 only to the residual value L _R > L _S has dropped.

The adaptive flushing method proposed here avoids these inconveniences. 10 shows in the case of a user A in the upper diagram the case of flushing with a fixed flushing time t _x , but z. B. too low water pressure. After use and flushing of the urinal, the water in the odor trap is still contaminated to some degree, as can be seen from the residual conductivity L _R. The lower diagram, however, according to the invention is an off evaluation of the conductance measurements continued after the start of the flushing. For this purpose, the measuring clock can be increased after an empirically determined time delay from the beginning of the purging, as indicated symbolically by "measurement 1", etc. Only when at least one measurement, here the "measurement n" results in a conductance value which is equal to a reference value, does the controller terminate the purging process by closing the solenoid valve at time t ₆ . Therefore, in the assumed case, the purge time is t _x + t _y in the same ratios as in the upper diagram the time interval t _y longer than t _x. The reference value L _S is here assumed equal to the value for clean water. In both diagrams is in addition to the course of the conductance 2 between the first electrode 1 and the second electrode 2 dotted the course of the conductance 3 between the reference electrode 1 and the third electrode 3 shown.

11 shows for the same usage situation as 9 , ie users A and B, also the juxtaposition of a rinse with fixed set rinse time t _x and with itself according to the invention self-adapting rinse time t _x + t _y . Instead of L _R2 or L _R3 as in the upper diagram, the guide values are 2 and 3 (dotted) according to the lower diagram on the clean water corresponding values dropped.

12 shows the same situation and juxtaposition as 11 with the difference that the user B enters urine even during the delay time that has started to run with the end of the user A's recognition of the controller's control, even before the controller has opened the solenoid valve.

That on the basis of 10 to 12 explained adaptive flushing method based on the fact that the controller measures the current conductance at least during the flushing at short intervals and the flushing process by closing the solenoid valve only when the current conductance, which may be in particular the average of eg the last three measurements equal is the reference value. Because the conductivity of fresh water differs greatly from place to place, the reference value must be preset to the highest expected value or - depending on the type of signal processing in the control - to a slightly higher value to ensure that Even under unfavorable conditions, ie at high conductivity of the fresh water at a certain place, a triggered flushing is also terminated. However, this means that in places with low conductivity of the fresh water, the rinse is stopped too soon. In a preferred development of the proposed method, this is avoided by the control itself determining the reference conductance value applicable for the respective place of use.

In this case, according to 13 The very low conductivity of spring water is preset at the factory as the first reference value L _SW . During commissioning, the controller initiates a flushing process and continuously measures the conductance values at given intervals. If the last measured master value or the average value of the last measured master values within a given tolerance range reaches the set reference value L _SW , then the flushing process is ended.

If the measured conductances do not reach the reference value L _SW but remain constant within the tolerance range during some measurements, the last, possibly averaged, measured value is defined and stored as the new reference value L _SO . At the same time, the rinsing process is ended. Similarly, if the quality of the local fresh water deteriorates, the controller will proceed in the direction of higher conductance values.

To be on the safe side, the controller only allows a maximum purge time independent of the result of the conductance measurements. If the measurements do not lead to constant values within this maximum purging time, the control initiates, after subsequent measurement of eg three (approximately) equal values, a new purging with the value of the last three measurements as a new reference value L _SO .

improves the quality of fresh water in the direction of lower conductance values, then the reference value also adjusted, and then if after a flush and before reusing the urinal, e.g. three consecutive Conductance measurements provide the substantially same value, the but lower than the current reference value.

The adjusted reference value L _SO can according to 13 based on a measurement of the conductance between the reference electrode and the electrode 2 be determined and regardless of a conductance measurement between the reference electrode and the electrode 3 , The controller terminates the purging as soon as one of the conductivity values 2 or 3 has fallen to a value corresponding to the reference value. In general, however, this is the guiding value 2 ,

Claims (9)

Method for controlling the flushing of a urinal by measuring the degree of soiling of the liquid in the odor trap, characterized in that the degree of contamination of the liquid is measured, the measured value compared with a reference value corresponding to a clean liquid and the rinsing process is terminated when the measured value of the degree of contamination is approximately equal to the reference value. Method according to claim 1, characterized in that that the degree of pollution by measuring the conductance between a first as a reference electrode on the inlet side of the odor trap arranged electrode and a second electrode is determined. Method according to claim 2, characterized in that that the second electrode beyond the overflow level of the odor trap is arranged on the outlet side. Method according to claim 2 or 3, characterized that as a criterion for a completed use of the urinal the change of the conductance between the reference electrode and the second electrode from rising to falling values. Method according to one of claims 1 to 4, characterized that the flushing process after a predetermined delay time is triggered after use of the urinal. Method according to one of claims 2 to 5, characterized that the conductance between the reference electrode and the second electrode multiply successively measured. Method according to one of claims 2 to 6, characterized that the reference value is approximately equal to the conductance of clean water between the reference electrode and the second electrode. Method according to one of claims 2 to 7, characterized that between the reference electrode and the second electrode while a previous flush Last measured conductivity plus a tolerance value is stored as a new reference value. Method according to claim 2 and / or according to one of the claims 4 to 7, characterized in that the second electrode on the Inlet side of the odor trap above the reference electrode, however below the overflow level is arranged.