The invention relates to a sensing device and a method of using such a device. In particular, the invention relates to a sensing device capable of determining a temperature of a liquid, preferably a washing liquid, and an electrical conductivity of said liquid at said temperature.
Sensing devices for determining an electrical conductivity and temperature can be used for the monitoring of (dish)washing processes in order to e.g. determine the concentration of detergent available for the (dish)washing process and to re-dose (fill) detergent if required. Although the electrical conductivity is a measure for the concentration of detergent, the temperature is measured as well, since the electrical conductivity is temperature-dependant.
U.S. Pat. No. 4,733,798 describes a method and apparatus for controlling the concentration of wash water in a ware washing machine, in which the conductivity of the ware washing solution is measured, as well as the temperature, in order to compensate for the apparent concentration changes solely associated with changes in temperature of the washing solution.
EP 1 704 810, in the name of the present applicant, describes a self-contained and wireless monitoring device, e.g., for monitoring a washing process inside a relatively small industrial dishwashing machine, which device monitors the electrical conductivity and temperature of the washing liquid. The temperature sensor in the monitoring device is physically isolated from the liquid in the sense of being encapsulated by a material that protects the sensor against the harsh chemical environment wherein the monitoring device operates during dishwashing. The disclosed monitoring device uses a stored threshold value of the electrical conductivity below which the detergent concentration in the washing liquid is considered too low and a user is alerted.
A problem in determining the amount of detergent by measuring the electrical conductivity and temperature, is that the quality, in particular the electrical conductivity, of water without detergent varies from one geographical region to another. This variation may be larger than the influence of the addition of detergent. In order to compensate for this variation to determine a reliable threshold value, it is desirable to obtain information on the electrical conductivity and the temperature at which that electrical conductivity of the washing liquid without dissolved detergent was determined. Users of the sensing devices, however, frequently immerse the sensing device in the washing liquid almost simultaneously with adding the detergent to the liquid. Whereas the electrical conductivity of the water can be measured quickly, the associated temperature cannot as a result of the physical encapsulation of the temperature sensor in the sensing device.
Therefore, a need exists in the art for a sensing device that is capable of quickly and accurately determining a temperature of a liquid and an electrical conductivity at that temperature.
It is an object of the invention to provide such a sensing device. This object is realised by a sensing device as defined in claim 1 and a method as defined in claim 15.
The invention allows to determine both the electrical conductivity and the temperature of the essentially detergent free liquid. The electrical conductivity is measured substantially instantly, preferably within 30 seconds from the immersion in the liquid, more preferably within 20 seconds, still more preferably within 15 seconds, and most preferably within 10 seconds for determining the electrical conductivity. The electrical conductivity may be measured by measuring the electrical resistance. It is noted that within these time limits, instead of a single measurement, multiple measurements may be performed. These multiple measurements may be averaged to determine the electrical conductivity of the essentially detergent free liquid. Since the temperature sensor is physically isolated from the liquid, the temperature of the water for which the electrical conductivity has been substantially instantly measured is determined by evaluating temperature measurement data during only a fraction of the temperature response characteristic of the sensor between an initial temperature and an intermediate temperature. The time related to this evaluated fraction is chosen such that detergent has not yet significantly dissolved in the liquid. It is not necessary to wait until the sensor reaches the temperature of the liquid, at which temperature the conductivity of the liquid was measured, since the temperature response characteristics enable a quick and accurate determination of the liquid temperature. Consequently, both the electrical conductivity and the temperature related to that electrical conductivity can be determined quickly and reliably.
An embodiment of the invention is defined in claims 2 and 16. This further temperature may be a reference temperature at which the electrical conductivity of the detergent dissolved in said liquid is known, and which temperature is close to the actual washing temperature, or is the actual washing temperature.
A further embodiment of the invention is defined in claims 3 and 15. It has been established that for such fractions of the temperature interval, the temperature of the liquid can be determined accurately by extrapolation in a sufficiently quick manner.
Another embodiment of the invention is defined in claims 4 and 16. This embodiment corresponds to practical application situations of the sensing device, wherein the sensing device is at room temperature and the liquid is approximately 40-60° C.
Still other embodiments of the invention are defined in claims 5-7 and 16-18. By selecting a fixed temperature change properly, a short timing measurement can be made with a high accuracy for determination of the temperature of the liquid associated with the instantly measured electrical conductivity.
In the embodiment as defined in claims 8 and 19, a measure is defined for the situation wherein the sensing device for the first time is immersed in a liquid already containing dissolved detergent. A threshold determined on the basis of the thus obtained electrical conductivity is not reliable. When the sensing device is later immersed in a liquid substantially free from dissolved detergent, the originally stored electrical conductivity is replaced by the determined appropriate electrical conductivity for establishing a reliable threshold.
The embodiment of the invention as defined in claims 9 and 20 is advantageous in that the threshold indicative of shortage of detergent is established automatically. In case the temperature of the liquid for which the electrical conductivity was determined instantly is substantially equal to the actual temperature of the dishwashing process, the instantly determined electrical conductivity may be used instead of the corrected electrical conductivity. The stored data concerning the electrical conductivity of a detergent dissolved in the liquid may be simply a constant value, as well as more complex data, such as a curve fit, and may depend on multiple factors, e.g., the chemical constitution of the detergent.
The embodiment of the invention as defined in claims 10-12, 21 and 22 provides a suitable sensing device capable of alerting a user of shortage of detergent in a washing liquid of a dishwashing machine.
The invention will hereafter be described on the basis of the accompanying drawings, schematically showing an embodiment of the invention. It will be clear that the invention is in no manner limited by these examples of embodiments.
In the figures:
It is noted that washing liquid typically remains within a washing machine after completion of a washing cycle for several cycles. The monitoring device can be provided in the washing machine before a (series of) washing cycle(s), simply by putting (disposing) it in the washing liquid.
In
The processor 7 serves, among other things, for processing conductivity measurement data from the electrodes 5 and temperature measurement data from the temperature sensor 3.
Storage means 4 contain a number of temperature response characteristics of the temperature sensor 3, which response characteristics will be described in more detail below with reference to
The processor 7 is arranged such that it activates itself upon detection that the sensing device 1 is immersed in liquid, via a substantial instant measurement of the electrical conductivity between the electrodes 5, and starts to determine the electrical conductivity on the basis of the measurement data of said conductivity sensor. As an example, the measurement is performed five times, with intervals of approx. 2.3 seconds, and the measured conductivities are subsequently averaged to determine the electrical conductivity of the substantially detergent free liquid. Furthermore, the processor 7 evaluates the temperature measurement data of the temperature sensor 3 measured in a fraction of the temperature interval between an initial temperature and an intermediate temperature that is below the temperature of the liquid after immersion of the sensing device 1 in the liquid, and thereby determines the temperature of the liquid using the stored temperature response characteristics in the storage means 4. As a result of the temperature interval measured being only a fraction of the temperature interval between the initial temperature of the sensing device 1 and the liquid surrounding it, the determination of the liquid temperature can be made quickly as will be explained hereafter.
The actual washing temperature is not necessarily identical to the temperature of the liquid at the moment of immersion of the sensing device 1, for instance because the water may be a little colder than an ideal washing temperature, due to, e.g., the addition of cold detergent-free water in order to compensate for a loss of water during drainage of the washing water at the end of the previous washing cycle. Therefore, the storage means 4 contains correction data concerning a temperature dependence of the electrical conductivity of a detergent free liquid, and the processor 7 is arranged for correcting the determined electrical conductivity on the basis of the correction data to determine a corrected electrical conductivity at a further temperature. The further temperature represents a washing temperature. The correction data contains in the present embodiment a formula having as input data the temperature of the water with substantially dissolved detergent and as output data the electrical conductivity of the water at the further temperature.
In the shown embodiment of the invention, the correction data consists of a number of curves, whereby each such curve relates, for detergent-free water having a given hardness, the conductivity of that water to its temperature.
In the sensing device 1, the processor 7 is arranged for storing in said storage means 4 a measured and/or determined electrical conductivity value, and for replacing said stored value by another measured electrical conductivity value if, in a later washing session, said other measured electrical conductivity value is lower than the stored value. By means of this replacement, it is guaranteed that the electrical conductivity of detergent-free water is measured in the cleanest water in which the sensing device 1 was emerged since its first measurement, and thus that the stored conductivity is the best value to represent the water hardness in the region wherein the dishwasher is installed.
The processor 7 of the sensing device 1 further is arranged for determining a threshold value for the electrical conductivity, such that the threshold value indicates a shortage of detergent in the liquid. For said determination of the threshold value, the processor 7 uses data of the electrical conductivity of a detergent dissolved in the liquid, which data is stored in the storage means 4. If the temperature of the washing liquid is substantially equal to the temperature for which the electrical conductivity was determined, the threshold is determined by summing the conductivity of the detergent and the conductivity of the washing liquid. If the temperature of the washing liquid is substantially different from the temperature for which the electrical conductivity was determined instantly (i.e. the further temperature differs from the temperature of the liquid), the threshold is obtained by summing the conductivity of the detergent and the corrected electrical conductivity.
The processor 7 is further arranged such that, after determining a value of the electrical conductivity of detergent-dissolved washing liquid, it provides an alarm signal to a RF-transmitter 9, which on its turn transmits a signal, using an antenna 10. The latter signal then is received by a receiver (not shown), which flashes a light and/or produces an audible beep-signal in order to prompt an operator of the washing machine to replenish detergent. In an alternative embodiment, also not shown, the receiver is part of a self-contained automatic dosing unit positioned at the washing machine, and activates this unit. In an alternative embodiment, two-way communication between the sensing device 1 and a receiver/transmitter is possible, for instance, for asking the sensing device 1 whether the amount of detergent is still sufficient, and to obtain an answer thereupon. Alternative suitable embodiments with regard to signailing are described in European patent application EP 1 704 810 of the applicant that is incorporated in the present application by reference.
In
The characteristics A, B and C were obtained by immersing a sensing device 1 in water and measuring the thermal response of the device. Alternatively, they may be obtained in other ways, e.g., by mathematical modelling and numerical simulation of the thermal response of the device. The representation of the characteristics A, B and C in the storage means 4 may be any format suitable for storing, for instance a mathematical formula or a numerical table.
Using said temperature response characteristics A, B and C, the processor 7 determines the temperature of the washing water as follows. First, after immersion of the device 1 in the water, it measures a fixed temperature rise using the temperaLure sensor 3, and measures the amount of time this takes in the processor 7. In
Obviously, if a time Δt′ or Δt″ is determined, the temperature of the liquid is determined as 40° C. or 60° C., respectively.
Next, in step 230, the conductivity of the water, which water is meant to be essentially detergent-free, is calculated, with a correction for its temperature on the basis of correction data that comprise a temperature dependence of the electrical conductivity of the water. In step 240, a set point is determined as the sum of the corrected conductivity and a conductivity of detergent dissolved in water of the same temperature as the determined water temperature. The conductivity of the detergent dissolved in water is the conductivity at 60° C., which is a temperature near or at the washing temperature and for which standard conductivity values are known in the art. In an alternative embodiment, the conductivity of detergent dissolved in water is obtained from a table that lists the conductivity at a number of temperatures near the washing temperature.
In step 250, an alarm signal is triggered if the measured conductivity is lower than the set point, which result in the flashing emission of red light with a high intensity by a led, as indicated by step 260. In the same step 250, the led will be activated to emit green light, as indicated by step 270. This serves the purpose of indicating that a sufficient amount of detergent is present in the washing water. The step 250 is followed by step 280, in which step the electrical conductivity of the water is determined again. In normal use, this second measurement takes place in water with detergent dissolved therein. The temperature of the water is also determined again, this time without extrapolation. The steps 250 and 280 are repeated at a regular interval during a dish-washing cycle (indicated by arrow 290). Once the device is taken out of the water, preferably after the washing cycle has been completed, the device goes from an active mode to a sleep mode (this transition is not shown in
In
The shown examples are given only for illustrative purposes, and are not to be taken as limitative. For instance, the circuit of
Number | Date | Country | Kind |
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06123860.6 | Nov 2006 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US07/84229 | 11/9/2007 | WO | 00 | 5/7/2009 |