Patent Publication Number: US-7913433-B2

Title: Measures for keeping a degree of contamination of a steam generator including its contents below a predetermined maximum

Description:
The present invention relates in general to a method for determining a moment during operation of a device having a steam generator at which a degree of contamination of a steam generator including its contents exceeds a predetermined maximum. 
     A well-known example of a device having a steam generator is a steam ironing device which comprises a steam iron having a soleplate for contacting objects to be ironed. The steam generator may be arranged inside the steam iron, but may also be arranged in a separate stand. In the latter case, the steam generator is larger and the steam production of the steam generator is higher. 
     For sake of clarity, it is noted that the term “steam generator” should be understood such as to cover all possible devices or elements of devices which are capable of heating water to steam. Well-known examples of a steam generator are a steam chamber arranged inside a steam iron and a boiler. 
     During operation of the steam ironing device, the water in the steam generator is heated, as a consequence of which scale is formed in the steam generator. This scale formation causes problems, as it may occur that scale particles are displaced from the steam generator to the steam iron, and land on an object to be ironed, causing stains on this object. Furthermore, over time, the water in the steam generator gradually gets contaminated with ions. This phenomenon is caused by the fact that during operation of the arrangement, only water is evaporated, while most of the other components which are present in the water stay behind. In a steam generator containing contaminated water, a foaming effect occurs during heating of the water, which disturbs a continuous supply of steam by the steam generator, and which may cause the steam generator to supply hot water along with the steam. 
     It is noted that during normal operation of the steam ironing device, measures are taken to assure that the steam generator always contains a predetermined minimum amount of water, so that it is possible to have a continuous steam production. Therefore, during operation, the steam generator is never completely emptied, and the water gets more and more contaminated with ions. 
     The extent to which the formation of scale takes place is related to a characteristic of the water referred to as hardness of the water. Water hardness is a quantity which is determined by a concentration of polyvalent cations in the water, in particular a concentration of calcium ions and magnesium ions. Waters having high hardness values are referred to as hard waters, whereas waters having low hardness values are referred to as soft water. 
     The extent to which the contamination of the water with ions takes place is related to a characteristic of the water referred to as total dissolved salt concentration, or, in short TDS concentration. TDS concentration is a quantity which is determined on the basis of a measurement by weight of dissolved materials in a given volume of water. 
     In order to reduce the influence of the scale formation and the increase of the TDS concentration on the performance of the steam ironing device, measures are taken to reduce the water hardness and/or the steam generator is rinsed from time to time. Basically, a reduction of the water hardness involves a replacement of calcium ions and magnesium ions while using ion exchange resin, whereas rinsing of the steam generator leads to a removal of scale particles. The TDS concentration is reduced by filling the steam generator with fresh water after a rinsing process has taken place. 
     In EP 1 045 932, a steam iron with an indicator for indicating calcification is disclosed. The steam iron is provided with a timer for measuring an accumulated time of use of the iron since a set starting point, and a control unit for activating the indicator when the accumulated time exceeds a predetermined threshold level. 
     The timer measures the times of use of the steam iron. The accumulated time of use is taken as a measure of the amount of scale deposited in a steam chamber and steam vents of the steam iron. When the accumulated time of use exceeds a threshold, the calcification indicator is activated to warn a user of the steam iron that a self-clean action, during which the steam chamber is rinsed with cold water, is to be performed. According to one possibility, the accumulated time of use is corrected with a weighting factor which is dependent of the hardness of the water to be steamed. According to another possibility, the threshold level for activating the indicator is made dependent on the hardness of the water. The softer the water, the longer an interval between two self-clean actions can be. 
     It is an objective of the present invention to provide a method which is suitable to be used for determining a moment at which the contamination of the steam generator and its contents, for example an amount of formed scale and/or a TDS concentration, has exceeded a predetermined maximum, and which is more accurate than the known method in which the accumulated time of use is measured, whether a correction factor is applied or not. The objective is achieved by means of a method, comprising the steps of keeping account of a value of an accumulated amount of water that has been supplied to the steam generator since a set starting point; and comparing the found value to a predetermined threshold value in order to check whether the found value is above the threshold value. 
     When the method according to the present invention is applied in a steam ironing device, the moment at which a rinsing process of the steam generator needs to be performed may easily be determined on the basis of a determination of a total amount of water that has been supplied to the steam generator since a set starting point, which is the start of a first use after a preceding rinsing process has been performed, for example. Furthermore, in case the steam ironing device comprises an ion exchange cartridge, it is possible to determine the moment at which the ion exchange resin is exhausted by applying the method according to the invention. 
     The present invention is based on the insight that the contamination of the water in the steam generator and the amount of scale is closely related to the total amount of water that has been supplied to the steam generator since a preceding cleaning action and/or a preceding exchange of an ion exchange cartridge. Therefore, it is possible to take the total amount of water that has been supplied to the steam generator as an accurate measure for the condition of the water and the amount of scale deposit. The threshold for the total amount of supplied water is associated with a maximum allowable contamination of the water and a maximum allowable amount of scale deposit in the steam generator. When it appears that the value of the accumulated amount of water is above the threshold value, it is concluded that a degree of contamination of the steam generator and its contents has exceeded an allowable maximum. 
     In many practical situations, the water is supplied to the steam generator by means of a water pump. In such situations, it is preferred if the value of the accumulated amount of water is determined on the basis of characteristics of the operation of the pump. In particular, it is preferred if the value of the accumulated amount of water is determined on the basis of set values of a flow rate and a pulse rate of the pump. It is relatively easy to realize this preferred way of carrying out the method according to the present invention in practice, as it is possible to make use of a controller for controlling the pump. 
     It is also possible that an electro-valve or the like is applied for controlling a supply of water to the steam generator. In such a case, it is advantageous if the value of the accumulated amount of water is determined on the basis of characteristics of the operation of the electro-valve. 
     Application of the method according to the present invention yields even more accurate results if the threshold level is determined in dependence of the water hardness. Therefore, preferably, the method further comprises the steps of determining a hardness of the water at the starting point; and setting the threshold value for the accumulated amount of water in dependence of the found water hardness, on the basis of a predetermined relation between the water hardness and the threshold value. Any known method for determining the water hardness may be applied. The predetermined relation between the water hardness and the threshold value may for example be laid down in the form of a look-up table that is stored in a micro-controller or the like. In a similar manner, the threshold level may be determined in dependence of the TDS concentration, or in dependence of both the water hardness and the TDS concentration. 
     Once it has been determined that the contamination of the steam generator and its contents is above an allowable maximum, various actions may be taken. In the first place, it is possible that a device of which the steam generator is part comprises an indicator, and that the indicator is activated in order to warn a user of the device that it is time to perform a rinsing process an/or exchange an ion exchange cartridge. The indicator may be realized in any suitable way, and preferably comprises a light. In the second place, it is possible that the device of which the steam generator is part comprises supplying means for supplying anti-foaming agent to the water that is intended to be used for steaming, and that these means are activated. 
     Furthermore, the present invention relates to a steam ironing device, comprising a steam generator and contamination sensing means for determining a moment during operation of the device at which a degree of contamination of the steam generator and its contents exceeds a predetermined maximum. 
     The present invention also relates to a steam ironing device, comprising a steam generator; a steam iron; and supplying means for supplying anti-foaming agent to the water that is intended to be used for steaming. By means of a supply of anti-foaming agent, it is achieved that a cleaning process of the steam generator and its contents, for example a rinsing process, may be performed less regularly. 
     In a practical embodiment, the steam supplying device comprises a water tank and a water pump for displacing water from the water tank to the steam generator. Preferably, in such an embodiment, the supplying means are adapted to introducing anti-foaming agent at an inlet of the pump, or, in other words, at a suction side of the pump, i.e. a side of the pump which is connected to the water tank. In this way, there is no need for a separate pump for generating a flow of anti-foaming agent towards the steam generator. 
    
    
     
       The present invention will now be explained in greater detail with reference to the Figures, in which similar parts are indicated by the same reference signs, and in which: 
         FIG. 1  diagrammatically shows a steam ironing device according to a first preferred embodiment of the present invention; 
         FIG. 2  diagrammatically shows a steam ironing device according to a second preferred embodiment of the present invention; 
         FIG. 3  diagrammatically shows an iron according to a first preferred embodiment of the present invention; 
         FIG. 4  diagrammatically shows an iron according to a second preferred embodiment of the present invention; 
         FIG. 5  diagrammatically shows a first steam ironing device comprising a steam generator and supplying means for supplying anti-foaming agent to the water that is intended to be used for steaming; and 
         FIG. 6  diagrammatically shows a second steam ironing device comprising a steam generator and supplying means for supplying anti-foaming agent to the water. 
     
    
    
       FIG. 1  diagrammatically shows a steam ironing device  1  according to a first preferred embodiment of the present invention, which will hereinafter also be referred to as first steam ironing device  1 . The steam ironing device  1  comprises a steam iron  10  having a soleplate  11  for contacting objects to be ironed. The steam iron  10  serves for supplying heat and steam to the objects to be ironed, wherein the soleplate  11  serves for supplying the heat, and wherein a steam generator  15  serves for generating and supplying the steam. In the shown example, the steam generator  15  is located in the steam iron  10 . 
     During operation of the steam ironing device  1 , water is supplied to the steam generator  15 . In the steam generator  15 , water is converted to steam under the influence of heat. For the purpose of supplying water to the steam generator  15 , the steam ironing device  1  comprises water supplying means  20  having a water tank  21  for containing water, a water pump  22  for forcing water to flow from the water tank  21  to the steam generator  15 , and a water hose  23  for conducting the water from the pump  22  to the steam generator  15 . 
     The steam ironing device  1  comprises a microprocessor  30 , which, among other things, is adapted to controlling the pump  22 . For example, the microprocessor  30  is connected to sensing means (not shown) for sensing a water level in the steam generator  15 . In case it appears that the water level is at a predetermined minimum, the microprocessor  30  activates the pump  22  to displace water from the water tank  21  to the steam generator  15 . In  FIG. 1 , an interaction between the microprocessor  30  and the pump  22 , which may be realized through electrical signals, is diagrammatically depicted by means of a dot and dash line. 
     Inside the water tank  21 , an ion exchange cartridge  40  is arranged for reducing the hardness of the water contained by the water tank  21 . The ion exchange cartridge  40  comprises ion exchange resin, which is capable of reducing a concentration of calcium ions and magnesium ions in the water. From the moment the ion exchange cartridge  40  is placed in the water tank  21 , the ion exchange resin performs its function of softening the water until a moment at which the ion exchange resin is exhausted. According to an important aspect of the present invention, the microprocessor  30  is capable of determining the moment at which the ion exchange resin is exhausted on the basis of characteristics of the operation of the pump  22  and a determined hardness of the water. 
     When a new ion exchange cartridge  40  is placed in the water tank  21 , the microprocessor  30  activates a hardness detection sensor  35  to measure the hardness of the water. In  FIG. 1 , an interaction between the microprocessor  30  and the hardness detection sensor  35 , which may be realized through electrical signals, is diagrammatically depicted by means of a dot and dash line. 
     The lifetime of the ion exchange cartridge  40  and the associated total amount of water that can be treated by the cartridge  40  are dependent of the water hardness. For example, a specific ion exchange cartridge  40  is able to treat 30 liters of hard water having a hardness of 15° dH, while the same cartridge  40  is able to treat only 25 liters of hard water having a hardness of 18° dH. In the microprocessor  30 , a look-up table is stored, containing combinations of water hardness and an amount of water that is allowed to be supplied to the steam generator  15  before the ion exchange cartridge  40  needs to be replaced, in other words, that is associated with an end of the lifetime of the ion exchange cartridge  40 . A value of this amount of water is also referred to as threshold value. On the basis of the outcome of the measurement of the water hardness, the microprocessor  30  determines a suitable threshold value. 
     Within the scope of the present invention, it is not necessary that a hardness detection sensor  35  is applied for the purpose of generating data regarding the water hardness. It is also possible to make use of a manually adjustable dial or the like. In such a case, a user of the steam ironing device  1  needs to be aware of the hardness of the water that is used, and needs to set the dial in accordance with this known water hardness. 
     In order to determine the amount of water that is supplied to the steam generator  15 , use is made of an electronic pulse controller which is applied for controlling the flow rate of the pump  22 . The pulse controller is capable of transmitting information regarding the flow rate and a set pulse rate to the microprocessor  30 , which continuously calculates the accumulated amount of water passing through the pump  22  and compares the value of the calculated amount of water to the threshold value. As soon as it appears that the value of the calculated amount of water is above the threshold value, it is concluded that the ion exchange cartridge  40  needs to be replaced, and the microprocessor  30  transmits an associated signal. For example, the steam ironing device  1  is equipped with an indicator light  31 , which is activated by the microprocessor  30  as soon as the value of the calculated amount of water appears to be above the threshold value. In  FIG. 1 , an interaction between the microprocessor  30  and the indicator light  31 , which may be realized through electrical signals, is diagrammatically depicted by means of a dot and dash line. By means of an activation of the indicator light  31 , the user of the steam ironing device  1  is warned that replacement of the ion exchange cartridge  40  is required. When the ion exchange cartridge  40  is replaced, the memory of the microprocessor  30  gets cleared from data concerning the previous cartridge  40 , and the above-described method comprising the steps of measuring the water hardness and determining the amount of water that is supplied to the steam generator  15  is repeated. 
     The same method which is used for determining a moment at which the ion exchange cartridge  40  needs to be replaced is also suitable to be used for determining a moment at which the steam generator  15  needs to be rinsed in order to remove scale particles. For the purpose of determining a suitable threshold value for the total amount of water that is to be supplied to the steam generator  15 , the microprocessor  30  contains a look-up table containing combinations of water hardness or TDS concentration, and an amount of water that is allowed to be supplied to the steam generator  15  before the steam generator  15  needs to be rinsed, in other words, that is associated with a maximum allowable amount of scale deposit in the steam generator  15 . When the threshold value is determined in dependence of the TDS concentration, it is important that the steam ironing device  1  comprises a suitable sensor. 
     In a preferred way of carrying out the method according to the present invention, the water hardness can be measured in terms of a concentration of specific ions, namely the concentration of calcium ions (Ca 2+  ions). The concentration of calcium ions is very useful as an indication of the water hardness in fresh water samples. Even though the water hardness is also determined by the presence of other ions such as magnesium ions (Mg 2+  ions) in the water, the concentration of calcium ions alone is still a reliable indicator of the water hardness, as the calcium ions normally constitute the pre-dominate hardness ions. By using membrane-based ion-selective electrodes, it is possible to measure the concentration of calcium ions on the basis of an electrical voltage output. 
     In a practical way of measuring the TDS concentration in the water, the electrical conductivity of the water is measured. For most water solutions, it is true that a higher concentration of dissolved salt leads to more ions in the water, and therefore leads to a higher electrical conductivity of the water. The electrical conductivity can be measured in any suitable way, for example by means of a two-electrode cell, wherein a voltage is applied to two flat plates immersed in the solution, and wherein the resulting current is measured. In the process, Ohm&#39;s law is applied, on the basis of which it is known that the conductance is the quotient of the current and the voltage. 
       FIG. 2  diagrammatically shows a steam ironing device  2  according to a second preferred embodiment of the present invention, which will hereinafter also be referred to as second steam ironing device  2 . 
     Like the first steam ironing device  1 , the second steam ironing device  2  comprises a steam iron  10  having a soleplate  11 , a steam generator  15 , water supplying means  20  having a water tank  21 , a water pump  22  and a water hose  23 , a microprocessor  30  for controlling the device  1  and an indicator light  31 . In  FIG. 2 , an interaction between the microprocessor  30  and the pump  22 , which may be realized through electrical signals, is diagrammatically depicted by a dot and dash line. The same applies to an interaction between the microprocessor  30  and the indicator light  31 . 
     In the second steam ironing device  2 , the steam generator  15  is arranged outside of the steam iron  10 , wherein a connection between the steam generator  15  and the steam iron  10  is established through a steam hose  12 . Furthermore, in the second steam ironing device  2 , the pump  22  is an electromechanical pump. 
     The steam generator  15  needs to be rinsed from time to time in order to remove scale particles that have been formed during operation of the steam generator  15 . The right moment for rinsing is determined on the basis of a measurement of the TDS concentration of the feed water and an associated threshold value for the value of the maximum amount of water that is allowed to be supplied to the steam generator  15  before the steam generator  15  needs to be rinsed, in other words, that is associated with a maximum allowable amount of scale deposit in the steam generator  15 . For the purpose of measuring the TDS concentration of the feed water, a TDS detection sensor  36  is arranged in the water tank  21 . In  FIG. 2 , an interaction between the TDS detection sensor  36  and the microprocessor  30 , which may be realized through electrical signals, is diagrammatically depicted by means of a dot and dash line. 
     In the microprocessor  30 , a look-up table is stored, containing combinations of TDS concentration and an amount of water that is allowed to be supplied to the steam generator  15  before the rinsing process needs to be performed, wherein a value of this amount of water constitutes a threshold value. On the basis of the outcome of the measurement of the TDS concentration, the microprocessor  30  determines a suitable threshold value. The table is drafted on the basis of the fact that when the TDS concentration of the feed water is detected, it is possible to predict the TDS concentration of the residual water in the steam generator  15  when a certain amount of water has been supplied to the steam generator  15  and has been evaporated to steam. For example, in a steam generator  15  which is initially provided with fresh feed water having a TDS concentration of 30 ppm (parts per million), the residual water is expected to have a higher TDS concentration, for example 3,000 ppm after 25 liters of water have passed through the steam generator  15  for steam generation. In case the fresh water has a higher TDS concentration, for example a TDS concentration of 75 ppm, the higher TDS concentration of 3,000 ppm is already reached when 10 liters of water have passed through the steam generator  15 . 
     In the second steam ironing device  2 , the amount of water that is supplied to the steam generator  15  is determined by counting a pulsing rate and an activation time of the pump  22 . The microprocessor  30  continuously calculates the accumulated amount of water passing through the pump  22  and compares the value of the calculated amount of water to the threshold value. As soon as it appears that the value of the calculated amount of water is above the threshold value, the microprocessor  30  activates the indicator light  31 , so that a user of the steam ironing device  2  may know that the moment for performing a rinsing process has come. 
     After the rinsing process has been performed, the memory of the microprocessor  30  is cleared from data concerning the previous time interval, and the above-described method comprising the steps of measuring the TDS concentration and the amount of water that is supplied to the steam generator  15  is repeated. 
     In an alternative embodiment of the second steam ironing device  2 , the TDS concentration of the water that is present inside the steam generator  15  is directly measured by means of a water level sensor  37  which is arranged in the steam generator  15 , and which is adapted to measuring the water level by measuring the electrical conductivity of the water. In such an embodiment, the microprocessor  30  is adapted to comparing the measured TDS concentration to a maximum allowable TDS concentration, and to activating the indicator light  31  as soon as it appears that the first concentration is higher than the latter concentration. In  FIG. 2 , an interaction between the microprocessor  30  and the water level sensor  37 , which may be realized through electrical signals, is diagrammatically depicted by means of a dot and dash line. 
       FIG. 3  diagrammatically shows a steam iron  3  according to a first preferred embodiment of the present invention, which will hereinafter also be referred to as first steam iron  3 . 
     Inside the steam iron  3 , a steam generator  15  for generating steam and supplying steam to objects to be ironed, a water tank  21  for containing fresh feed water, and an electromechanical water pump  22  for forcing the water to flow from the water tank  21  to the steam generator  15  are arranged. Furthermore, a microprocessor  30  which, among other things, serves for controlling the pump  22  is arranged inside the steam iron  3 . In  FIG. 3 , an interaction between the microprocessor  30  and the pump  22 , which may be realized through electrical signals, is diagrammatically depicted by means of a dot and dash line. 
     In the first steam iron  3 , an electronic pulse controller is applied for controlling the flow rate of the pump  22 . The pulse controller is also able to count the total amount of water that is delivered into the steam generator  15  by knowing the pulse rate. The microprocessor  30  serves for storing and calculating the total amount of water passing through the pump  22  and for comparing the found value to a value threshold associated with a maximum duration of a time interval between two processes of rinsing the steam generator  15 . As soon as it appears that the value of the total amount of water is above the threshold value, the microprocessor  30  activates an indicator, for example an indicator light  31 . In  FIG. 3 , an interaction between the microprocessor  30  and an indicator light  31 , which may be realized through electrical signals, is diagrammatically depicted by means of a dot and dash line. 
     After the rinsing process has been performed, the memory of the microprocessor  30  is cleared from data concerning the previous time interval, and the above-described method for determining a moment at which the rinsing process needs to be performed is repeated. 
       FIG. 4  diagrammatically shows a steam iron  4  according to a second preferred embodiment of the present invention, which will hereinafter also be referred to as first steam iron  4 . 
     Inside the steam iron  4 , a steam generator  15 , a water tank  21  and a water hose  23  for connecting the water tank  21  to the steam generator  15  are arranged. The steam iron  4  comprises a mechanical dosing device  24  for feeding water in a controlled manner from the water tank  21  to the steam generator  15 . In  FIG. 4 , a flow of water is diagrammatically depicted by means of an arrow. Furthermore, the steam iron  4  comprises a flow meter  38 , which is arranged between the dosing device  24  and the steam generator  15 . 
     In the second steam iron  4 , the total amount of water that is supplied to the steam generator  15  is measured by means of the flow meter  38 . When the value of the total amount of water exceeds a predetermined threshold value, an alert is activated in order to warn a user of the second steam iron  4  that it is time for a rinsing process of the steam generator  15 . Preferably, the rinsing process is performed with a relatively large amount of water, approximately 150 grams per minute. 
     Measures such as regularly performed rinsing processes or the application of an ion exchange cartridge  40  are useful in preventing undesired situations in which an amount of scale particles in the steam generator  15  and/or a TDS concentration of water that is present inside the steam generator  15  increase to such a level that during operation of the steam generator  15 , effects such as foaming of the water and the steam generator  15  letting out hot water together with the steam take place. 
     The frequency at which the rinsing processes need to take place may be reduced by applying supplying means  70  for supplying anti-foaming agent to the water that is intended to be used for steaming. A first steam ironing device  6  comprising such means  70  is diagrammatically shown in  FIG. 5 , and a second steam ironing device  7  comprising such means is diagrammatically shown in  FIG. 6 . Besides a steam generator  15  and the supplying means  70 , the shown steam ironing devices  6 ,  7  also comprise a steam iron  10  having a soleplate  11  for contacting objects to be ironed, a water supplying means  20  having a water tank  21 , a water pump  22  and a water hose  23 , and a steam hose  12 . The steam generator  15  is arranged outside of the steam iron  10 . 
     Anti-foaming agent (which may also be referred to as de-foaming agent) works either as a foam inhibitor or as a foam breaker, or as both. The agent reduces a gradient in surface tension in a liquid film between bubbles, so that the surface tension in the liquid film between the bubbles gets constant again. As a result, the liquid film between the bubbles drains more easily and breaks when it is thick. The surface tension of the water is also reduced by the incorporation of anti-foaming agent in the liquid film, the extent of the reduction depending on the concentration of the anti-foaming agent. 
     Several ways of providing the water that is intended to be used for steaming with the anti-foaming agent exist. In the first steam ironing device  6  comprising supplying means  70 , the anti-foaming agent is introduced at a suction side of the pump  22 , i.e. a side of the pump  22  which is connected to the water tank  21 . During operation of the device  6 , the pump  22  simultaneously takes in both feeding water and anti-foaming agent. A container  71  for containing the anti-foaming agent is connected to the suction side of the pump  22  through a valve  72 , which can be used to control the release of anti-foaming agent. Alternatively, the supplying means  70  may comprise another pump (not shown) for dosing anti-foaming agent to the suction side of the pump  22 . As a result of the introduction of anti-foaming agent into the water that is intended to be used for steaming, phenomena such as foaming of the water or the steam generator  15  letting out hot water together with the steam are avoided. 
     In the second steam ironing device  7  comprising supplying means  70 , the anti-foaming agent is directly introduced into the steam generator  15 . In this device  7 , the supplying means  70  comprise a pump  73  for pumping the anti-foaming agent to the steam generator  15 . This pump  73  is controlled by means of a microprocessor  30 , wherein the microprocessor  30  is programmed such as to activate the pump  73  in case it appears that the TDS concentration of the water that is present inside the steam generator  15  is higher than a maximum allowable TDS concentration. In  FIG. 6 , an interaction between the microprocessor  30  and the pump  73 , which may be realized through electrical signals, is diagrammatically depicted by means of a dot and dash line. Various possibilities for determining whether the TDS concentration has become higher than a maximum allowable TDS concentration exist, including the above-described possibility of determining a total amount of water supplied to the generator and comparing a determined value of this amount to a threshold value, wherein the threshold value may be determined in dependence of an initial TDS concentration of the water. It is noted that the valve  72  of the first steam ironing device  6  comprising supplying means  70  may be controlled in a similar manner. 
     Alternatively, the anti-foaming agent may be directly released into the water tank  21 , via a diffusion mechanism or by means of a pump, for example. The process of releasing anti-foaming agent into the water tank  21  may be activated by a user, by simply pushing a release button each time the water tank  21  is filled with fresh water. However, this process may also be performed automatically, wherein there is no need for interference of the user. 
     It has already been noted that the extent to which phenomena such as foaming of the water that is present inside the steam generator  15  and a release of hot water together with the steam occur is strongly related to the TDS concentration in the water. Therefore, it is also possible to control the supply of anti-foaming agent on the basis of an actual measurement of the TDS concentration of the water that is present inside the steam generator  15 . Research has shown that in case of a steam generator  15  operating at a pressure that is below 20 bar, the TDS concentration should be kept below 3,000 ppm in order to avoid the mentioned phenomena. 
     Preferably, during operation of the steam ironing devices  6 ,  7  comprising supplying means  70 , a regular or continuous check of the amount of anti-foaming agent that is present in the container  71  is performed, and a user of the device  7  is warned of a imminent lack of anti-foaming agent in case the container  71  contains less anti-foaming agent than an allowable minimum amount. Suitable means such as a sensor and an alert are provided for performing the functions of checking the amount of anti-foaming agent and warning the user. 
     It will be clear to a person skilled in the art that the scope of the present invention is not limited to the examples discussed in the foregoing, but that several amendments and modifications thereof are possible without deviating from the scope of the present invention as defined in the attached claims. 
     In the foregoing, several steam ironing devices  1 ,  2 ,  3 ,  4 ,  6 ,  7  are disclosed. A second steam ironing device  2 , shown in  FIG. 2 , comprises a steam iron  10 , a steam generator  15  for generating steam and supplying steam to the steam iron  10 , and means  20  for supplying water to the steam generator  15 . During operation of the device  2 , scale is formed in the steam generator  15 , and the water in the steam generator  15  gradually gets contaminated with ions. In order to clean the steam generator  15  and replace the water by fresh water, the steam generator  15  is regularly subjected to an auto-rinsing process. A moment at which this process needs to take place is a moment at which an amount of scale and/or a concentration of ions have exceeded a predetermined maximum. The amount of scale and/or the concentration of ions are indirectly monitored by keeping account of a total quantity of water that has been supplied to the steam generator  15  since a set starting point.