EP1612319A1 - Method for monitoring a drying cycle particularly for a laundry drying machine - Google Patents

Abstract

The method involves heating a relative humidity sensor, and measuring a reference value (FM) for a dry air at the outlet of the sensor. The heating of the sensor is stopped and drying airflow is released. A reference variation is calculated by difference of reference values for dry and humid airs. An end of the drying cycle is determined when a ratio of current variation (delta ) on reference variation attains a preset threshold value. The current variation (delta ) is measured between the reference value (FM) and a current value measured at the outlet of the relative humidity sensor. Independent claims are also included for the following: (A) a relative humidity sensor (B) a machine to dry cloth.

Description

The present invention relates to a method of monitoring a drying cycle.

It also relates to a relative humidity sensor used during the implementation of the method of monitoring a drying cycle according to the invention.

Finally, it aims to protect a machine for drying laundry comprising such a relative humidity sensor and adapted to implement the method of monitoring a drying cycle according to the invention.

The present invention relates to the field of drying, and more particularly to the field of drying clothes in a domestic clothes drying machine.

It is common to equip such a dryer machine with a drying cycle monitoring system for automatic detection of the end of this drying cycle.

Dry cycle monitoring systems are thus known, using a relative humidity sensor comprising a capacitive cell whose impedance varies as a function of the relative humidity of the surrounding medium.

Such a system is described in particular in document FR 2 786 556. In this document, the measurement of the moisture present in the laundry is carried out at the level of an outlet duct situated downstream of a rotating drum containing the laundry. relative to the direction of circulation of the drying air.

The air has just passed through the laundry and its moisture content reflects that which is in the laundry to dry.

In order to avoid a calibration of this sensor, and to compensate for any drift over time of measurement, a difference between the moisture content of the laundry and the humidity level of the outside air is constantly measured. For this, a valve is associated with the sensor and periodically allows the passage of air from outside towards the sensor. This outside air makes it possible to dry the sensor, the measurement then carried out at the terminals of this sensor corresponding to a measurement of a moisture content of a dry air.

Such a system has the disadvantage of associating with the electronic part of the sensor, mechanical elements constituted in particular by the valve allowing alternately to communicate or isolate the drying air circulation duct with the outside air.

The present invention aims to solve the aforementioned drawbacks and to provide a relative humidity sensor and a method of monitoring a drying cycle using such a sensor avoiding in particular the use of moving mechanical parts.

According to a first aspect, the present invention relates to a method of monitoring a drying cycle using a relative humidity sensor disposed in a circulation duct of a drying air flow.

• chauffage du capteur d'humidité relative ;
• mesure d'une valeur de référence pour un air sec en sortie du capteur d'humidité relative ;
• arrêt du chauffage du capteur d'humidité relative ; et
• mise en circulation du flux d'air de séchage.

According to the invention, this method of monitoring a drying cycle comprises the following steps:

• heating of the relative humidity sensor;
• measuring a reference value for dry air at the output of the relative humidity sensor;
• stopping the heating of the relative humidity sensor; and
• circulation of the drying air flow.

By heating the relative humidity sensor, the output measurement of this sensor corresponds to a relative humidity rate of a relatively dry air.

It is thus possible to obtain a reference value for dry air.

By heating the relative humidity sensor, it is no longer necessary to contact this sensor with the outside air to obtain a reference value for dry air.

The calibration of the relative humidity sensor can thus be obtained by simple heating of this sensor and the method of monitoring a drying cycle can thus be implemented solely by the control of electronic power means.

• mesure d'une valeur de référence pour un air humide en sortie du capteur d'humidité relative ; et
• calcul d'un écart de référence par différence des valeurs de référence mesurées pour un air sec et un air humide.

According to one embodiment of the invention, this method of monitoring a drying cycle also comprises the following steps:

• measuring a reference value for moist air at the outlet of the relative humidity sensor; and
• calculation of a reference difference by difference of the reference values measured for dry air and humid air.

A reference difference between the values corresponding to dry air, containing about 5% relative humidity, and moist air containing about 95% relative humidity, is then calculated.

The use of a reference deviation makes it possible to dispense with the absolute calibration of the sensors. The reference difference is indeed specific to each relative humidity sensor.

• calcul d'un écart courant entre la valeur de référence mesurée pour un air sec et une valeur courante mesurée en sortie du capteur d'humidité relative ;
• comparaison dudit écart courant et de l'écart de référence ; et
• détermination d'une fin de cycle de séchage lorsque le rapport de l'écart courant sur l'écart de référence a atteint une valeur de seuil prédéterminée.

According to one embodiment of the invention, this method of monitoring a drying cycle also comprises the following steps:

• calculating a current difference between the reference value measured for a dry air and a current value measured at the output of the relative humidity sensor;
• comparing said current difference and the reference difference; and
• determining an end of the drying cycle when the ratio of the current deviation to the reference deviation has reached a predetermined threshold value.

By comparing a current deviation and the reference deviation, it is possible to relatively control the remaining moisture in the laundry to be dried, and thus to overcome a calibration of the sensor.

According to another embodiment, the method of monitoring a drying cycle further comprises, before the step of measuring a reference value for moist air, a regulation step during which the heating of the sensor relative humidity is implemented when the difference between the reference value for a dry air and the current value measured at the output of the sensor is greater than a prefixed value.

This regulation step makes it possible to dry the relative humidity sensor at the beginning of the drying cycle, in order to avoid any phenomenon of condensation on this sensor, distorting the relative humidity measurements of the drying airflow circulating in the duct.

Indeed, the relative humidity sensor is no longer periodically ventilated as in the state of the prior art, condensation phenomena at the beginning of a drying cycle can be observed. The saturation of the relative humidity sensor and the formation of water droplets do not make it possible to obtain a satisfactory measurement of the relative humidity actually present in the drying air flow.

This regulation step thus makes it possible to dry the sensor if necessary since the measured current value becomes very small compared to the reference value for dry air.

According to another embodiment of the invention, the predetermined threshold value for determining an end of a drying cycle depends on a drying rate requested by a user and / or a duration between the beginning of the cycle. drying time and an instant at which the current value measured at the output of the relative humidity sensor has reached a predefined threshold value.

Indeed, the duration set to reach a predefined threshold of a relative humidity, is directly dependent on the amount of elements to be dried.

When the method of monitoring a drying cycle is carried out in a dryer, the end of a drying cycle can be determined from a predetermined threshold value which depends directly on the amount of drying. linen to dry.

Alternatively, or simultaneously, this predetermined threshold value may also depend on an instruction from the user who wishes to obtain a more or less dry cloth.

According to a second aspect, the present invention relates to a relative humidity sensor comprising a capacitive cell, the impedance of the capacitive cell varying as a function of the relative humidity of the medium surrounding said sensor and the capacitive cell being associated with an oscillating circuit. on an electronic map.

According to the invention, this relative humidity sensor comprises heating means arranged near the capacitive cell.

These heating means make it possible to dry the relative humidity sensor and thus to achieve a measurement corresponding to a reference dry air.

According to one embodiment of the invention, the heating means are arranged between the electronic card and a plate for fixing the capacitive cell on the electronic card.

The integration of the heating means at the level of the attachment plate of the capacitive cell makes it possible to directly heat the sensor capacitive cell, and thus to prevent the appearance of condensation on this sensor, detrimental to a correct measurement of the sensor. relative humidity in the drying airflow.

According to a third aspect, the present invention relates to a laundry drying machine comprising a rotating drum for receiving laundry to be dried and a dryer air circulation conduit in communication with the drum. This laundry drying machine comprises a relative humidity sensor according to the invention, disposed in the drying air circulation circuit, downstream of the drum relative to the direction of circulation of the drying air.

It also relates to a dryer machine comprising means adapted to implement the method of monitoring a drying cycle according to the invention.

This dryer has similar characteristics and advantages to those described above in connection with the method of monitoring a drying cycle and the relative humidity sensor according to the invention.

Other features and advantages of the invention will become apparent in the description below.

• la figure 1 est un schéma de principe illustrant une machine à sécher le linge conforme à l'invention ;
• la figure 2 est un schéma illustrant le montage d'un capteur d'humidité relative conforme à l'invention ;
• la figure 3 est un schéma de principe illustrant une carte électronique comportant un capteur d'humidité relative conforme à l'invention ;
• la figure 4 est une courbe théorique illustrant le principe du procédé de suivi d'un cycle de séchage conforme à l'invention ; et
• la figure 5 est une courbe illustrant les mesures réalisées en sortie d'un capteur d'humidité relative pour la mise en oeuvre du procédé de suivi d'un cycle de séchage conforme à un mode de réalisation de l'invention.

In the accompanying drawings, given as non-limiting examples:

• Figure 1 is a block diagram illustrating a laundry drying machine according to the invention;
• Figure 2 is a diagram illustrating the mounting of a relative humidity sensor according to the invention;
• Figure 3 is a block diagram illustrating an electronic card comprising a relative humidity sensor according to the invention;
• FIG. 4 is a theoretical curve illustrating the principle of the method of monitoring a drying cycle according to the invention; and
• FIG. 5 is a curve illustrating the measurements made at the output of a relative humidity sensor for implementing the method of monitoring a drying cycle according to one embodiment of the invention.

We will now describe with reference to Figure 1, a drying machine adapted to implement the invention.

This machine may be a household clothes drying machine or a washer-dryer adapted to dry the laundry after washing thereof.

Conventionally, such a machine for drying laundry comprises a drum 10 consisting of a cylindrical tank for receiving laundry. This drum is rotated to ensure permanent brewing of the laundry. A drying air circulation duct 11 is placed in communication with the drum 10. A fan 12 makes it possible to circulate the drying air in the duct 11 in the direction of the arrows in FIG. 1.

It is thus possible to define a portion of duct 11a upstream of the drum and a portion of duct 11b downstream of the drum, relative to the direction of circulation of the drying air.

Upstream of the drum 10, a heating resistor 13 is conventionally disposed in the drying air circulation duct in order to heat the air before it enters the drum.

A relative humidity sensor 20 is disposed in the drying air circulation duct, downstream of the drum 10. This relative humidity sensor is thus placed in the drying air stream, which has just passed through the laundry. placed in the drum. The measurement of the relative humidity achieved at this air flow is therefore directly representative of the moisture contained in the laundry placed in the drum 10.

It will be recalled that the relative humidity corresponds to the volume of water contained in the air relative to the maximum volume of water that the air could contain at this temperature.

Thus, the relative humidity does not directly give the quantity of water vapor but only a ratio between the state of the air considered and that of the air saturated at the same temperature, and to a lesser extent of influence. at the same pressure.

The relative humidity sensor is illustrated in greater detail in FIGS. 2 and 3.

This relative humidity sensor 20 comprises a capacitive cell 21 whose impedance varies as a function of the relative humidity of the medium surrounding the sensor.

The capacitive cell 21 is associated with an oscillating circuit on an electronic card 23. The oscillating circuit is an astable circuit based on 555 making it possible to convert the variable capacitance of the capacitive cell into a frequency. This frequency, measured at the electronic card 23, manages the drying cycle as will be described later with reference to Figures 4 and 5.

By way of nonlimiting example, a capacitive cell 21 may be a HUMIREL HS 1101 sensor.

On the electronic card 23 is also mounted a negative temperature coefficient resistor (NTC resistance) which allows to control the temperature of the laundry and to prevent overheating thereof.

A microcontroller 26 is also mounted on the power card 23 to allow management of the automation of the machine. This microcontroller 26 receives in particular at the input the value of the frequency representative of the relative humidity measured at the level of the relative humidity sensor 20.

Heating means 24 are arranged near the capacitive cell 21.

In this exemplary embodiment, the heating means 24 are arranged between the electronic card 23 and a fixing plate 21a of the capacitive cell on the electronic card 23.

Conventionally, this capacitive cell 21 may comprise fixing studs 22 for fixing and electrical connection to the power electronic card 23. The heating means are constituted in this embodiment of electrical resistors 24 arranged between the sole 21 a and the electronic card 23, between the fixing studs 22 of the capacitive cell 21.

Of course, the number of electrical resistors is not limiting. In this example, these resistors, two in number, provide a total power of the order of 1 W, each of the resistors providing 0.5 W.

The resistors 24 are in this embodiment connected in parallel. They have a minimal bulk and are plated under the sole 21a of the capacitive cell 21, the assembly being embedded in a thermal grease, such as a silicone grease, facilitating the transmission of heat towards the capacitive cell 21.

The control of these resistors 24 can be achieved by means of the microcontroller 26 via a triac.

Thus, thanks to the heating in the vicinity of the relative humidity sensor 20, the frequency measured at the output of this sensor corresponds to a frequency associated with a relatively dry air.

Indeed, thanks to the positioning of the resistors 24 directly in contact with the sole 21a of the sensor, the temperature of the capacitive cell 21 is kept permanently higher than that of the surrounding air. This temperature difference makes it possible to avoid any phenomenon of condensation and formation of water droplets on the capacitive cell, hindering the obtaining of a measurement of relative humidity in the flow of drying air flowing in the duct 11. .

Thanks to the arrangement of these resistors 24 in direct contact with the capacitive cell 21, a correct drying of this sensor is obtained. to obtain a reference value for dry air, having a relative humidity of the order of 5%.

In addition, the temperature rise can be carried out very rapidly so that stabilization of the sensor measurements is achieved quickly for a relatively low heating power.

The principle of a method for monitoring a drying cycle using a relative humidity sensor as described above with reference to FIGS. 2 and 3 will now be described with reference to FIG.

As previously described, a frequency is measured at the output of this sensor 20 which is directly inversely proportional to the relative humidity contained in the air surrounding the sensor 20.

Thus, during a laundry drying cycle, the frequency measured at the output of the sensor 20 increases as the laundry dries. In order to overcome a calibration of the sensor, the method of monitoring a drying cycle is implemented by comparing a reference difference with a current difference between a measured frequency value at the output of the sensor. relative humidity and a measured reference value for dry air.

A way of obtaining a reference value for dry air and a reference value for moist air at the outlet of the relative humidity sensor will be described later with reference to FIG. The reference deviation Δr is calculated by difference of the measured frequency for dry air F _M and the frequency measured for moist air F _m .

In practice, the very dry air corresponds to an air having a relative humidity of the order of 5%, and a very humid air corresponds to an air having a relative humidity rate substantially equal to 95%.

Comparing a current difference Δ calculated from a frequency F measured at the output of the sensor and the measured frequency for a dry air F _M, with .DELTA.R reference deviation is used to determine the end of a cycle drying when this ratio has reached a predetermined threshold value.

FIG. 4 shows different predetermined threshold values which depend on a drying rate requested by a user: TH, very humid, H, wet, PH, little wet, S, dry and TS, very dry.

The level of humidity desired by the user depends on the subsequent use of the laundry, light moisture may for example to iron more easily.

A mass of laundry is considered to be dry when stored in an atmosphere at 60% relative humidity. A remaining moisture content is defined by the difference between the mass of wet laundry and the mass of laundry considered dry, this difference being itself divided by the mass of laundry considered dry. The different thresholds, illustrated in Figure 4, are thus defined by the remaining moisture content: 12% for very wet, 6% for wet, 3% for little wet, 0% for dry and -3% for very dry.

However, the relative humidity seen at the sensor 20 placed in the circulation duct 11 of the machine may vary depending on several parameters. In particular, it can vary depending on the amount of laundry, which can be between 0.5 and 5 kg dry mass, or the spin speed, or to a lesser extent the voltage of the supply electric dryer.

The amount of laundry placed in the drum 10 has a significant influence on the moisture seen by the sensor. Indeed, if the drum is completely filled, the air at the drum outlet will be completely passed through the laundry and will be heavily loaded with moisture.

On the contrary, if the drum contains only very few clothes, the air seen by the sensor will be much drier, than in the previous example, although the laundry may still be wet.

It is therefore interesting to be able to vary the threshold value used to determine the end of a drying cycle also taking into account the amount of laundry.

Indeed, when the drum contains only a small amount of laundry, the air is low moisture and thus poorly reflects the actual moisture present in the laundry to dry.

In practice, the measurement of a duration between the beginning of the drying cycle and an instant at which the frequency measured at the output of the relative humidity sensor has reached a predefined threshold value is used.

The beginning of the drying cycle corresponds to the moment at which the heating of the relative humidity sensor is started.

If a large amount of laundry is placed in the drum, the time to reach this preset threshold value will be long, compared to that which would be measured for a small amount of laundry.

The predetermined threshold value used to determine the end of a drying cycle will then directly depend on this measured duration during the drying cycle, which itself depends directly on the amount of laundry.

A drying cycle is now described with reference to FIG. 5, using the relative humidity sensor previously described in a machine for drying clothes.

FIG. 5 shows the value of the frequency F delivered by the relative humidity sensor 20 over time.

The method of monitoring a drying cycle firstly makes it possible to obtain a reference frequency F _M for dry air by drying of the relative humidity sensor 20.

Thus during a phase A as illustrated in FIG. 5, the relative humidity sensor is heated thanks to the heating resistors 24 previously described. By increasing the temperature of the soleplate 21a of the sensor, the relative humidity of the air surrounding the sensor is decreased. The sensor once dried by the heater outputs a stable value frequency, which corresponds to a reference value F _M for dry air.

The frequency F _M thus corresponds to a maximum value of the frequency, associated with a dry air having a relative humidity of the order of 5%. In practice, the measurement of the frequency F _M is performed when the variation of the measured frequency F at the output of the sensor is less than 0.25 Hz per second. Similarly, when the variation of the measured frequency is less than 0.25 Hz per second, the heating of the humidity sensor 20 is stopped at the end of the phase A of FIG.

Then, the drying air stream is circulated in the sheath 11. The highly humid air from the drum arrives in the sheath so that moisture is very important inside the sheath portion 11 b downstream of the drum 10.

The sensor 20 placed in this portion 11b of the sheath is sensitive to condensation. Water droplets form on its surface so that the frequency measured at the output of the relative humidity sensor 20 tends to drop to zero as shown in FIG. 5.

In order to avoid this phenomenon, a regulation step is carried out, during which the heating of the relative humidity sensor 20 is momentarily reactivated. Thus, the resistors 24 are put into operation when the difference between the reference frequency F _M for a dry air and the current value of the frequency F measured at the output of the relative humidity sensor 20 is greater than a prefixed value.

This prefixed value may be equal, for example, to 1300 Hz.

This regulation phase makes it possible to maintain the value of the frequency F measured at the output of the relative humidity sensor 20 above a certain threshold, in order to avoid the saturation of this sensor.

When the difference between the value F _M of the frequency associated with dry air and the current value F of the measured frequency is stabilized and less than 1300 Hz, the step of regulating phase B is interrupted.

A phase C is then used to measure a reference value for moist air at the outlet of the relative humidity sensor.

As illustrated in FIG. 5, in practice, once the control phase is no longer required, the relative humidity sensor is heated again to dry it out.

When the measured value F at the output of the sensor is substantially stable and begins to increase, signifying that the drying of the laundry has just been initiated, the value of the frequency F at the output of the relative humidity sensor is measured to obtain a value of reference F _m corresponding to moist air, that is to say about 95% relative humidity.

A calculation step can then be implemented to calculate a reference deviation Δr by difference of the maximum frequency F _M and the minimum frequency F _m measured respectively for dry air and moist air: $$\mathrm{.DELTA.R}={\mathrm{F}}_{\mathrm{M}}-{\mathrm{F}}_{\mathrm{m}}$$

Then, a phase of monitoring the evolution of this difference is implemented in a phase D as illustrated in FIG.

In practice, a current difference Δ is calculated between the reference value F _M measured for a dry air and a current value F measured at the output of the relative humidity sensor, which is directly connected to the humidity present in the flow of drying air during the drying cycle.

This current difference Δ is compared with the reference deviation Δr so that the determination of an end of the drying cycle is carried out when the ratio of the current difference Δ on the reference deviation Δr has reached a value of predetermined threshold as previously explained with reference to FIG. 4.

As non-limiting examples, for a load of 5 kg, if the frequency measured for dry air F _M is approximately equal to 6450 Hz, and the frequency measured for moist air F _m is approximately equal to 5500 Hz , the reference deviation Δr is equal to 950 Hz.

• Très humide : Δ = 0,89 Δr
• Humide : Δ = 0,84 Δr
• Sec : Δ = 0,73 Δr
• Très sec : Δ = 0,63 Δr

The Applicant has found experimentally that the threshold values associated with each remaining moisture content may be equal to:

• Very humid: Δ = 0.89 Δr
• Wet: Δ = 0.84 Δr
• Sec: Δ = 0.73 Δr
• Very dry: Δ = 0.63 Δr

These detection threshold values are purely indicative and depend in particular on the relative humidity sensor used, the type of laundry, the quantity of laundry to be dried, etc. The detection threshold values are for example between 0, 5 and 0.9.

By comparing the current deviation Δ and the reference deviation Δr, it is possible to dispense with an absolute calibration of the relative humidity sensor 20.

Thanks to the present invention, it is possible to heat the relative humidity sensor at the beginning of a drying cycle in order to obtain a reference value corresponding to a dry air and to allow the detection of the end of the drying cycle. from this reference value. In addition, the phenomenon of condensation can be reduced by avoiding the appearance of significant temperature difference between the sensor and the surrounding air, by heating the sensor during the control phase described above.

Of course, many modifications can be made to the embodiment described above without departing from the scope of the invention.

In particular, the heat calibration method of the relative humidity sensor could be used in other applications than a clothes dryer.

Indeed, by heating this sensor, it is possible to calibrate at any time and adjust its measurement automatically.

Claims (13)

Process for monitoring a drying cycle using a relative humidity sensor (20) arranged in a duct (11) for circulating a drying air flow, characterized in that it comprises the following steps : heating the relative humidity sensor (20); measuring a reference value (F _M ) for dry air at the outlet of the relative humidity sensor; - stopping the heating of the relative humidity sensor; and - circulation of the drying air flow. Monitoring method according to claim 1, characterized in that it further comprises the following steps: measuring a reference value (F _m ) for moist air at the outlet of the relative humidity sensor; and - calculation of a reference difference (Δr) by difference of the reference values measured for dry air and humid air. Monitoring method according to claim 2, characterized in that it further comprises the following steps: calculating a current difference (Δ) between the reference value (F _M ) measured for dry air and a current value (F) measured at the output of the relative humidity sensor; comparing said current difference (Δ) and the reference difference (Δr); and determination of an end of the drying cycle when the ratio of the current deviation on the reference deviation has reached a predetermined threshold value. Monitoring method according to one of claims 2 or 3, characterized in that it further comprises, before said step of measuring a reference value for moist air, a control step during which the heating of the relative humidity sensor (20) is implemented when the difference between the reference value (F _M ) for dry air and the current value (F) measured at the output of the relative humidity sensor is greater than a prefixed value. Monitoring method according to one of claims 1 to 4, characterized in that the measured value at the output of the relative humidity sensor is a frequency converted by an oscillating circuit associated with a capacitive cell (21), the impedance of the capacitive cell varies according to the relative humidity of the surrounding medium. Monitoring method according to claim 5, characterized in that the heating of the humidity sensor is stopped when the variation of the measured frequency is less than 0.25 Hz per second. Monitoring method according to claims 4 and 5, characterized in that the control step is interrupted when the difference between the reference value (F _M ) for dry air and the measured current value (F) is stabilized and less than 1300 Hz. Monitoring method according to claim 3, characterized in that said predetermined threshold value for the determination of an end of drying cycle depends on a drying rate requested by a user and / or a duration between beginning of the drying cycle and an instant at which the current value measured at the output of the relative humidity sensor has reached a predefined threshold value. Relative humidity sensor comprising a capacitive cell (21), the impedance of the capacitive cell (21) varying as a function of the relative humidity of the medium surrounding said sensor, and the capacitive cell being associated with an oscillating circuit on a card electronic device (23), characterized in that it comprises heating means (24) arranged close to said capacitive cell (21). Relative humidity sensor according to claim 9, characterized in that it comprises heating means (24) arranged between the electronic card (23) and a fixing plate (21 a) of said capacitive cell (21) on the electronic card (23). Relative humidity sensor according to one of Claims 9 or 10, characterized in that the heating means (24) consist of one or more electrical resistances of total power equal to about 1W. Machine dryer comprising a rotatable drum (10) for receiving the laundry to be dried and a conduit (11) for circulating drying air in communication with the drum, characterized in that it comprises a humidity sensor relative (20) according to one of claims 9 to 11, disposed in said duct (11b) for drying air circulation, downstream of the drum (10) relative to the direction of circulation of the drying air. Drying machine, characterized in that it comprises means adapted to implement the method of monitoring a drying cycle according to one of claims 1 to 8.

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