Patent Description:
In a conventional electrical appliance used for washing, processing parameters are detected by means of multiple independent sensors, e.g. water level sensors, water temperature sensors, water turbidity sensors, etc. Different sensors are used to measure different processing parameters of the electrical appliance, such as water level height, water temperature, water turbidity, etc..

These sensors are each installed at different positions on the electrical appliance, and connected to a control board of the electrical appliance by means of dedicated electrical cables and connectors. A processor is provided on the control board to read and process signals from the sensors, in order to ensure correct operation of the electrical appliance.

For example, patent document <CIT> has disclosed an optical turbidity sensor for a washing machine, which turbidity sensor is used to detect water turbidity.

<CIT> has disclosed a washing machine which has an improved water level sensor. The water level sensor is used to detect the water level height in a drum, is installed above the drum, and is provided with an air chamber and pipeline for connecting the sensor to the water.

<CIT> discloses an encapsulated cluster of turbidity sensor, temperature sensor, conductivity sensor and magnetic sensor for a water-bearing machine.

In KR <NUM> B1 a sensor apparatus is disclosed, capable of being used to detect at least two processing parameters of an electrical appliance used for washing, wherein one of two sensor units is a water level sensor unit.

One or more of the following shortcomings are associated with a conventional electrical appliance used for washing which is constructed in the manner described above:.

Furthermore, signals between sensor and control board are generally analogue signals. Since the electrical cables used to connect the sensor to the control board are long, analogue signals might suffer interference from electromagnetic noise. Thus it is necessary for a solution for filtering interference signals to be provided on the control board; this increases the cost of the electrical appliance further. Moreover, in certain situations, the impedance of long electrical cables and the electromagnetic noise introduced thereby cannot be completely filtered, leading to a reduction in sensor precision.

The object of the present invention is to provide a sensor apparatus, and an electrical appliance used for washing and equipped with the sensor apparatus, which can overcome one or more of the shortcomings mentioned above.

To this end, the present invention provides a sensor apparatus, capable of being used to detect at least two processing parameters of an electrical appliance used for washing, the sensor apparatus comprising: at least two sensor units, used to detect different processing parameters and including a water level sensor unit; a signal processor unit, which is electrically connected to the at least two sensor units, acquires and processes signals from the at least two sensor units, and outputs digital signals; a housing, which accommodates the at least two sensor units and the signal processor unit, wherein the water level sensor unit comprises a water pressure detector and a deformation amount detector, the water pressure detector comprising a deformable device which deforms due to water pressure applied thereto, the deformation amount detector being able to detect a deformation amount of the deformable device, and send a deformation amount signal to the signal processor unit.

Preferably, besides the water level sensor unit, the other of the at least two sensor units comprise(s) one or more of the following sensor units: a water temperature sensor unit, a water hardness sensor unit, a water turbidity sensor unit, a drum position sensor unit, a load weight sensor unit and a load imbalance sensor unit.

Preferably, the deformable device is a deformable diaphragm. Preferably, the deformable diaphragm is made of metal foil or rubber or silicone rubber.

Preferably, the water level sensor unit comprises a water pressure detector, a spring and a spring deformation amount detector, wherein the water pressure detector transmits water pressure to the spring, the spring deforms due to water pressure, and the spring deformation amount detector can detect a deformation amount of the spring, and send a deformation amount signal to the signal processor unit. Preferably, the water pressure detector is a bellows structure with a bottom.

Preferably, besides the water level sensor unit, the other of the at least two sensor units comprise(s) a water hardness sensor unit, the water hardness sensor unit comprising at least two electrodes, the at least two electrodes being made of an electrically conductive material and pointing towards a region outside the housing, and being used to detect the electrical conductivity of water.

Preferably, besides the water level sensor unit, the other of the at least two sensor units comprise(s) a water temperature sensor unit, the water temperature sensor unit comprising a temperature detector and a protective casing, the protective casing being fixed to the housing and oriented towards a region outside the housing, with the temperature detector being disposed inside the protective casing. Preferably, the temperature detector is an NTC temperature detector. Preferably, the protective casing is made of a thermally conductive material.

Preferably, besides the water level sensor unit, the other of the at least two sensor units comprise(s) a load imbalance sensor unit, the load imbalance sensor unit detecting acceleration and motion of a loaded moving component of the electrical appliance, and sending a motion-related parameter value obtained to the signal processor unit. Preferably, the load imbalance sensor unit is a MEMS accelerometer.

Preferably, besides the water level sensor unit, the other of the at least two sensor units comprise(s) a water turbidity sensor unit, the water turbidity sensor unit comprising a light emitter, a light receiver and protective covers, wherein the light emitter and light receiver are each located in one protective cover, and the light emitter, light receiver and protective covers are arranged in such a way that light emitted by the light emitter sequentially passes through the protective cover accommodating the light emitter, water, and the protective cover accommodating the light receiver, and then arrives at the light receiver. Preferably, two or more light emitter/light receiver pairs are provided. Preferably, the protective covers are installed on the housing as independent components, or are made integrally with the housing.

Preferably, besides the water level sensor unit, the other of the at least two sensor units comprise(s) a water temperature sensor unit and a water hardness sensor unit, the water hardness sensor unit comprising at least two electrodes, wherein the at least two electrodes are fixed to the housing, are made of an electrically conductive material and point towards a region outside the housing, and are capable of detecting the electrical conductivity of water, and the water temperature sensor unit comprises a temperature detector disposed inside one of the at least two electrodes.

Preferably, the signal processor unit outputs digital signals to a control system of the electrical appliance in a wired or wireless manner by means of a connector. Preferably, the connector is connected to the control system of the electrical appliance via a bus electrical cable.

Preferably, the signal processor unit is able, on the basis of a signal from one of the at least two sensor units, to compensate a signal of one or more other of the at least two sensor units.

Preferably, the sensor apparatus comprises a printed circuit board, with the signal processor unit being disposed on the printed circuit board.

The present invention also provides an electrical appliance used for washing and equipped with the sensor apparatus described above.

Preferably, the electrical appliance is a washing machine. Preferably, the sensor apparatus is installed at the bottom, or at the bottom of one side, of an outer drum of the washing machine. Preferably, the sensor apparatus is installed on a connecting apparatus, connecting the outer drum to a water drainage apparatus, of the washing machine, in a position close to the bottom of the outer drum of the washing machine.

Preferably, the electrical appliance is a dishwasher. Preferably, the sensor apparatus is installed at the bottom, or at the bottom of one side, of an inner chamber of the dishwasher. Preferably, the sensor apparatus is installed on a connecting apparatus, connecting the inner chamber to a water drainage apparatus, of the dishwasher.

Other features of the present invention will be made obvious by the following explanation of demonstrative embodiments which makes reference to the accompanying drawings.

Various embodiments of the present invention are described below with reference to the accompanying drawings. These embodiments are intended to illustrate the present invention, which is not limited to these embodiments.

A washing machine is taken as an example hereinbelow to describe an electrical appliance used for washing. It should be understood that the present invention is not limited to a washing machine, but may be applied in other types of electrical appliance used for washing, such as a dishwasher, etc..

<FIG> is a structural schematic diagram of a first embodiment of a sensor apparatus according to the present invention.

In a first embodiment of a sensor apparatus, the sensor apparatus <NUM> comprises a housing <NUM>, a water temperature sensor unit <NUM>, a water level sensor unit <NUM>, a signal processor unit <NUM>, a printed circuit board <NUM> and a connector <NUM>. The printed circuit board <NUM> is supported by the housing <NUM>, and the signal processor unit <NUM> is disposed on the printed circuit board <NUM>.

The water temperature sensor unit <NUM> comprises a temperature detector <NUM> and a protective casing <NUM>. The protective casing <NUM> is fixed to the housing <NUM>, and may be made of a metal material. In the case where the sensor apparatus is installed on a washing machine, the protective casing <NUM> is oriented so as to face towards the inside of a washing machine drum, and comes into direct contact with water during operation of the washing machine. The temperature detector <NUM> is disposed inside the protective casing <NUM>, and is electrically connected to the signal processor unit <NUM>, so as to transmit detected water temperature signals to the signal processor unit <NUM>. The temperature detector <NUM> may be an NTC temperature detector.

The water level sensor unit <NUM> comprises a water pressure detector <NUM> and a deformation amount detector <NUM>. The water pressure detector <NUM> comprises an elastically deformable device, such as a silicone rubber diaphragm or a metal deformation piece. The elastically deformable device is disposed on the housing <NUM>, and in the case where the sensor apparatus is installed on a washing machine, the deformable device can come into direct contact with water, so as to deform due to water pressure. When the water level height in the washing machine drum changes, the water pressure will change, thereby causing a change in the amount of deformation of the water pressure detector <NUM>. The deformation amount detector <NUM> may be disposed directly on the printed circuit board <NUM>, and can detect the amount of deformation of the water pressure detector <NUM>, and transmit a deformation amount signal of the water pressure detector <NUM> to the signal processor unit <NUM>. Based on the amount of deformation of the water pressure detector <NUM>, the signal processor unit <NUM> can obtain a corresponding water level.

The connector <NUM> is disposed on the housing <NUM>, and has one end connected to the printed circuit board <NUM>, and another end connected to a control system of the washing machine via an electrical cable, preferably a bus electrical cable, so as to transmit processed digital signals. Optionally, the other end of the connector <NUM> is provided with a wireless transmission apparatus, to wirelessly transmit digital signals to the control system of the washing machine.

In a first embodiment of the sensor apparatus, the water level sensor unit <NUM> and water temperature sensor unit <NUM> are disposed on one side of the housing, while the connector <NUM> is disposed on the other side of the housing which is opposite the water level sensor unit <NUM>. Optionally, the housing comprises a first housing component and a second housing component, which first housing component and second housing component can be fitted together to form a closed unit. The first housing component is constructed to have at least two step faces, wherein the water level sensor unit <NUM> and water temperature sensor unit <NUM> are installed on the first step face, and the second step face can serve as a mounting face for fixing the sensor apparatus to the water machine. The second housing component may be constructed as a cover of the housing.

The signal processor unit <NUM> receives water temperature signals and water level signals from the water temperature sensor unit <NUM> and water level sensor unit <NUM>, subjects the received signals to processing and then conversion to digital signals, and transmits the digital signals to the control system of the washing machine via the connector <NUM>.

Different water pressures will be produced by the same water level height if the water temperature changes by a certain amount. Thus, preferably, after obtaining water temperature data from the water temperature sensor unit <NUM>, the signal processor unit <NUM> can subject signals from the water level sensor unit <NUM> to compensation and correction according to a predetermined algorithm, so as to obtain more precise water level data.

During operation of the washing machine, the water temperature sensor unit <NUM> and water level sensor unit <NUM> detect the water temperature and water level height respectively, and send the detected data to the signal processor unit <NUM>. The signal processor unit <NUM> processes the inputted signals, and transmits the processed digital signals to the control system of the washing machine via the connector <NUM>. The control system of the washing machine then performs the next operational step according to received parameter values.

<FIG> is a structural schematic diagram of a second embodiment of a sensor apparatus according to the present invention. In the explanation of the second embodiment, drawing labels identical to those in the first embodiment are given to elements which have corresponding functions, and a detailed explanation thereof is omitted for the sake of simplicity.

In the second embodiment of the sensor apparatus, the sensor apparatus <NUM> comprises a housing <NUM>, a water level sensor unit <NUM>, a water hardness sensor unit <NUM>, a signal processor unit <NUM>, a printed circuit board <NUM> and a connector <NUM>. The printed circuit board <NUM> is supported by the housing <NUM>, and the signal processor unit <NUM> is disposed on the printed circuit board <NUM>.

The water hardness sensor unit <NUM> comprises a first electrode <NUM> and a second electrode <NUM>. The first electrode <NUM> and second electrode <NUM> are made of an electrically conductive metal material, and fixed to the housing <NUM>. In the case where the sensor apparatus is installed on a washing machine, the first electrode <NUM> and second electrode <NUM> are oriented so as to face towards the inside of the washing machine drum, come into direct contact with water during operation of the washing machine, are electrically connected to the signal processor unit <NUM>, and are used for detecting the electrical conductivity of the water, so as to obtain a water hardness value.

In the second embodiment of the sensor apparatus, a water pressure detector <NUM> is disposed in the middle of a first step face of the housing, and the first electrode and second electrode are disposed on two sides of the water pressure detector <NUM> respectively, thereby forming a symmetric and compact sensor apparatus structure.

Optionally, in the water hardness sensor unit, the number of electrodes is not limited to two; more than two electrodes may be provided.

During operation of the washing machine, the water hardness sensor unit <NUM> and water level sensor unit <NUM> detect the water hardness and water level height respectively, and send the detected data to the signal processor unit <NUM>. The signal processor unit <NUM> processes the inputted signals, and transmits the processed digital signals to the control system of the washing machine via the connector <NUM>. The control system of the washing machine then performs the next operational step according to received parameter values.

<FIG> is a structural schematic diagram of a third embodiment of a sensor apparatus according to the present invention. In the explanation of the third embodiment, drawing labels identical to those in the preceding embodiments are given to elements which have corresponding functions, and a detailed explanation thereof is omitted for the sake of simplicity.

In the third embodiment of the sensor apparatus, the sensor apparatus <NUM> comprises a housing <NUM>, a water level sensor unit <NUM>, a load imbalance sensor unit <NUM>, a signal processor unit <NUM>, a printed circuit board <NUM> and a connector <NUM>. The printed circuit board <NUM> is supported by the housing <NUM>, and the signal processor unit <NUM> is disposed on the printed circuit board <NUM>.

The load imbalance sensor unit <NUM> is disposed on the printed circuit board <NUM> and electrically connected to the signal processor unit <NUM>. The load imbalance sensor unit <NUM> is used for detecting acceleration and motion of a washing machine outer drum during operation of the washing machine, and sends an obtained parameter value (such as speed, acceleration etc.) associated with motion to the signal processor unit <NUM>, so as to obtain a load imbalance state. Preferably, the load imbalance sensor unit <NUM> is a MEMS accelerometer.

Since the motion state of the washing machine outer drum will be affected to a certain extent by the water level height in the drum, preferably, after obtaining water level data from the water level sensor unit <NUM>, the signal processor unit <NUM> can subject signals from the load imbalance sensor unit <NUM> to compensation and correction according to a predetermined algorithm, so as to obtain more precise load imbalance state data.

During operation of the washing machine, the load imbalance sensor unit <NUM> and water level sensor unit <NUM> detect a washing machine outer drum motion parameter and water level height respectively, and send the detected data to the signal processor unit <NUM>. The signal processor unit <NUM> processes the inputted signals, and transmits the processed digital signals to the control system of the washing machine via the connector <NUM>. The control system of the washing machine then performs the next operational step according to received parameter values.

<FIG> is a structural schematic diagram of a fourth embodiment of a sensor apparatus according to the present invention. In the explanation of the fourth embodiment, drawing labels identical to those in the preceding embodiments are given to elements which have corresponding functions, and a detailed explanation thereof is omitted for the sake of simplicity.

In the fourth embodiment of the sensor apparatus, the sensor apparatus <NUM> comprises a housing <NUM>, a water level sensor unit <NUM>, a water turbidity sensor unit <NUM>, a signal processor unit <NUM>, a printed circuit board <NUM> and a connector <NUM>. The printed circuit board <NUM> is supported by the housing <NUM>, and the signal processor unit <NUM> is disposed on the printed circuit board <NUM>.

The water turbidity sensor unit <NUM> comprises a light emitter <NUM>, a light receiver <NUM> and protective covers <NUM>. The protective covers <NUM> are disposed on the housing <NUM>. The light emitter <NUM> and light receiver <NUM> are each located in one protective cover <NUM>, and electrically connected to the signal processor unit <NUM>, and the light emitter <NUM> and light receiver <NUM> are arranged to face each other. The light emitter <NUM>, light receiver <NUM> and protective covers <NUM> are arranged in such a way that a light path of light emitted by the light emitter <NUM> sequentially passes through the protective cover <NUM> outside the light emitter <NUM>, the water in the washing machine drum, and the protective cover <NUM> outside the light receiver <NUM>, and then arrives at the light receiver <NUM>. The light emitter <NUM> emits a certain amount of light, which passes through the protective cover <NUM> and then propagates through the water in the washing machine drum. When the water is relatively clear, there are fewer contaminants in the water, so the extent to which light is blocked or scattered is less; more light is able to pass through the water and arrive at the light receiver <NUM>, so a greater quantity of light is received by the light receiver <NUM>. Conversely, when the water is relatively turbid, there are more contaminants in the water, so the extent to which light is blocked or scattered is greater; less light is able to pass through the water and arrive at the light receiver <NUM>, so a smaller quantity of light is received by the light receiver <NUM>. The light receiver <NUM> sends the quantity of light received to the signal processor <NUM>, so as to determine the water turbidity according to the size of the quantity of light.

In the fourth embodiment of the sensor apparatus, a water pressure detector <NUM> is disposed in the middle of a first step face of the housing, and the light emitter <NUM> and light receiver <NUM> are disposed on two sides of the water pressure detector <NUM> respectively, thereby forming a symmetric and compact sensor apparatus structure.

Optionally, in the water turbidity sensor unit, there is no restriction to one light emitter/light receiver pair; two or more light emitter/light receiver pairs may be provided according to measurement precision requirements.

Optionally, in the water turbidity sensor unit, the protective covers which accommodate the light emitter and light receiver may be transparent, translucent or opaque. For example, in the case where infrared light is used, the protective covers might be translucent or opaque to the human eye. Optionally, the protective covers may be installed on the housing as independent components, or made integrally with the housing.

During operation of the washing machine, the water turbidity sensor unit <NUM> and water level sensor unit <NUM> detect water turbidity and water level height respectively, and send the detected data to the signal processor unit <NUM>. The signal processor unit <NUM> processes the inputted signals, and transmits the processed digital signals to the control system of the washing machine via the connector <NUM>. The control system of the washing machine then performs the next operational step according to received parameter values.

<FIG> is a structural schematic diagram of a fifth embodiment of a sensor apparatus according to the present invention. In the explanation of the fifth embodiment, drawing labels identical to those in the preceding embodiments are given to elements which have corresponding functions, and a detailed explanation thereof is omitted for the sake of simplicity.

In the fifth embodiment of the sensor apparatus, the sensor apparatus <NUM> comprises a housing <NUM>, a water level sensor unit <NUM>, a water temperature sensor unit <NUM>, a water hardness sensor unit <NUM>, a load imbalance sensor unit <NUM>, a signal processor unit <NUM>, a printed circuit board <NUM> and a connector <NUM>. The printed circuit board <NUM> is supported by the housing <NUM>, and the signal processor unit <NUM> is disposed on the printed circuit board <NUM>.

In the fifth embodiment, unlike in the first embodiment, the water temperature sensor unit <NUM> is not provided with a protective casing for a temperature detector <NUM>. Instead, a first electrode <NUM> of the water hardness sensor unit <NUM> performs the function of protecting the temperature detector <NUM>. While detecting the electrical conductivity of the water, the first electrode <NUM> protects the temperature detector <NUM> from contact with water and transmits water heat to the temperature detector <NUM>. Through such an arrangement, the number of components in the sensor apparatus is further reduced, thereby forming a compact sensor apparatus structure.

Preferably, after obtaining water temperature data from the water temperature sensor unit <NUM> and water level data from the water level sensor unit <NUM>, the signal processor unit <NUM> can subject signals from the water hardness sensor unit <NUM> and load imbalance sensor unit <NUM> to compensation and correction according to a predetermined algorithm, so as to obtain more precise water hardness and load imbalance states.

During operation of the washing machine, the water level sensor unit <NUM>, water temperature sensor unit <NUM>, water hardness sensor unit <NUM> and load imbalance sensor unit <NUM> detect water level height, water temperature, water hardness, and washing machine outer drum motion parameters respectively, and send the detected data to the signal processor unit <NUM>. The signal processor unit <NUM> processes the inputted signals, and transmits the processed digital signals to the control system of the washing machine via the connector <NUM>. The control system of the washing machine then performs the next operational step according to received parameter values.

<FIG> is a structural schematic diagram of a sixth embodiment of a sensor apparatus according to the present invention. In the explanation of the sixth embodiment, drawing labels identical to those in the preceding embodiments are given to elements which have corresponding functions, and a detailed explanation thereof is omitted for the sake of simplicity.

In the sixth embodiment of the sensor apparatus, the sensor apparatus <NUM> comprises a housing <NUM>, a water level sensor unit <NUM>, a water temperature sensor unit <NUM>, a water hardness sensor unit <NUM>, a load imbalance sensor unit <NUM>, a signal processor unit <NUM>, a printed circuit board <NUM> and a connector <NUM>. The printed circuit board <NUM> is supported by the housing <NUM>, and the signal processor unit <NUM> is disposed on the printed circuit board <NUM>.

The sixth embodiment of the sensor apparatus differs from the fifth embodiment in the construction of the water level sensor unit <NUM>. In the sixth embodiment, the water level sensor unit <NUM> comprises a water pressure detector <NUM>", a spring deformation amount detector <NUM>" and a spring <NUM>". The water pressure detector <NUM>" is disposed on the housing <NUM>, with two ends fixed to the housing <NUM>, and can freely extend and retract and transmit water pressure to the spring <NUM>". Preferably, the water pressure detector <NUM>" is a bellows structure with a bottom. The water pressure detector <NUM>" can seal the sensor, preventing water from seeping into the interior of the sensor. The spring <NUM>" has one end fixed to the bottom of the water pressure detector <NUM>", and another end fixed to the printed circuit board <NUM>. The spring <NUM>" can move in reciprocal motion between the water pressure detector <NUM>" and the printed circuit board <NUM>, extending or retracting with changes in water pressure. The spring deformation amount detector <NUM>" is disposed on the printed circuit board <NUM> and electrically connected to the signal processor unit <NUM>. The spring deformation amount detector <NUM>" detects the amount of deformation of the spring <NUM>, and transmits a deformation amount signal of the spring <NUM> to the signal processor unit <NUM>. The signal processor unit <NUM> converts the deformation amount of the spring to a water level height, then outputs a processed digital signal to the control system of the washing machine via the connector <NUM>.

Some embodiments of the sensor apparatus are described above. It should be understood that the present invention is not limited to the particular structures of these embodiments; a person skilled in the art could, after reading the description, make other amendments and modifications according to requirements. For example, a drum position detection sensor unit or load weight sensor unit etc. could also be provided in the sensor apparatus. These amendments and modifications all fall within the scope of the present invention.

Preferably, the signal processor unit <NUM> can not only compensate and correct other parameters according to water temperature and water level data, but can also compensate and correct other parameters according to drum position and load weight data, etc..

<FIG> shows schematically an example of a diagram showing signal compensation relationships among various processing parameters. It can be seen from <FIG> that the signal processor unit can compensate various parameters of water level, drum position, load weight, load imbalance state, water turbidity and water hardness according to water temperature data, compensate a load imbalance state parameter according to water level data, compensate water level and load weight according to drum position data, and compensate drum position according to load weight data. However, the present invention is not limited to the example of the signal compensation relationships in <FIG>. When the sensor apparatus of the present invention comprises a greater or smaller number of sensor units, similar compensation relationships exist among the various parameters. More precise measurements can thereby be achieved.

The structure of a washing machine equipped with a sensor apparatus according to the present invention is described below with reference to <FIG>.

<FIG> is a structural schematic diagram of a first embodiment of a washing machine according to the present invention. The washing machine of the present invention has the same components as a conventional washing machine (such as water intake system, water drainage system, etc.). These identical components are not described further here; only those features of the washing machine of the present invention which differ from a conventional washing machine are described.

As <FIG> shows, a sensor apparatus <NUM> of the present invention is installed at an opening in the bottom of a washing machine outer drum <NUM>, and is fixed by, for example, a screw-thread connection or an adhesive connection, etc. During operation of the washing machine, the sensor apparatus <NUM> comes into direct contact with water in the washing machine outer drum, such that the various sensor units detect relevant parameters, and send signals to the signal processor unit, followed by transmission to the control system of the washing machine, to ensure normal operation of the washing machine.

The sensor apparatus <NUM> is installed at the bottom of the washing machine outer drum; this is very beneficial for measurement of water level height. The present invention combines various sensor elements in the housing <NUM> in an integrated manner to form the sensor apparatus <NUM>, thereby simplifying the installation steps and internal structure of the washing machine, shortening the installation time, and reducing the use of electrical cables and connectors, thereby reducing installation costs. In addition, since the use of excessively long electrical cables is avoided, and digital signal output is employed, various processing parameters of the washing machine can be detected more precisely.

<FIG> is a structural schematic diagram of a second embodiment of a washing machine according to the present invention.

In this embodiment, the sensor apparatus <NUM> is not installed at an opening in the bottom of a washing machine outer drum <NUM>, but is installed on a connecting hose <NUM> (which connects the outer drum to a water drainage apparatus) of the washing machine outer drum, in a position close to the bottom of the washing machine outer drum. The sensor apparatus <NUM> comes into contact with water in the connecting hose <NUM>, in order to detect relevant signals. Such an arrangement can not only achieve the same technical effects and advantages as the washing machine in <FIG>, but since there is no need to additionally provide an opening for the sensor apparatus <NUM> in the outer drum <NUM> of the washing machine, a forming mould for the outer drum <NUM> is kept unchanged, and application in an existing washing machine is easy; compared with the washing machine in <FIG>, manufacturing costs are vastly reduced.

Two embodiments of the washing machine are described above. It should be understood that the present invention is not limited to the particular structures in these embodiments; a person skilled in the art could, after reading the description, make other amendments and modifications according to requirements. For example, the orientation of the sensor apparatus may be vertical, or inclined relative to a vertical direction. For example, the electrical appliance used for washing may be a dishwasher, with the sensor apparatus installed at the bottom, or at the bottom of one side, of an inner chamber of the dishwasher, or installed on a connecting apparatus (which connects the inner chamber to a water drainage apparatus) of the dishwasher.

Claim 1:
Sensor apparatus, capable of being used to detect at least two processing parameters of an electrical appliance used for washing, the sensor apparatus (<NUM>) comprising:
at least two sensor units, used to detect different processing parameters;
a signal processor unit (<NUM>), which is electrically connected to the at least two sensor units, acquires and processes signals from the at least two sensor units, and outputs digital signals;
a housing (<NUM>), which accommodates the at least two sensor units and the signal processor unit (<NUM>), wherein
the at least two sensor units include a water level sensor unit (<NUM>),
characterized in that the water level sensor unit (<NUM>) comprises a water pressure detector (<NUM>, <NUM>') and a deformation amount detector (<NUM>), the water pressure detector (<NUM>, <NUM>') comprising a deformable device which deforms due to water pressure applied thereto, the deformation amount detector (<NUM>) being able to detect a deformation amount of the deformable device, and send a deformation amount signal to the signal processor unit (<NUM>).