[0001] The present invention relates to a washing machine having a continuous water level
(CWL) sensor connected to a control unit including a microprocessor. With the term
"washing machine" we mean all kinds of domestic appliances for washing laundry and
for washing dishes as well. As far as laundry-washing appliances are concerned, the
present invention can be used for horizontal, vertical and tilted axes machines.
[0002] Modern washing machines use a CWL sensor that is able to monitor continuously the
water level inside the tub.
[0003] CWL is a sensor able to convert the pressure applied to the sensor (that is proportional
to the water level in the tub) into an electrical signal. There are few different
types of CWL. Today the most common type is piezoresistive pressure transducer, membrane
displacement sensor and inductive displacement device.
[0004] The piezoresistive pressure transducers are for instance produced and sold by Motorola,
Honeywell, Sensym, and they are designed for wide applications. This kind of sensor
combines a sensitive implanted strain gauge with advanced bulk micromachine technique,
thin film metalisation and bipolar processing in order to provide an accurate high
level analog output (voltage) that it is proportional to the applied pressure.
[0005] Membrane displacement sensors are produced for instance by Huba. This kind of CWL
sensor is conceived as a low cost device for domestic appliances (particularly dishwashers).
It is a displacement device where the deflection of a rubber membrane which results
from the pressure acting on it, it is measured by a piezoresistive force sensor (Wheatstone
bridge) obtained above an alumina substrate (by "Thick Film" technology) and on the
same substrate the signal conditioning interface is also realized (by SMD technique).
The sensor is temperature compensated and amplified for providing an analog voltage
output.
[0006] Inductive displacement sensor are produced for instance by ELBI / Bitron. This kind
of sensor is conceived as a low cost device for domestic appliances. It is an inductive
displacement device (sensitive devise) using an inductance coil circuit measuring
the deflection of the rubber membrane (by a metal pivot connected with the rubber
membrane), that results from the pressure acting upon it.
[0007] The above known sensors combine a sensitive device with a microprocessor integrated
in the same package to provide an accurate high level analog output that it is proportional
to the applied pressure. The CWL sensor can be provided with the following different
output types or it can be provided with multiple type of output: frequency, analog
voltage output, PWM (pulse width modulation).
[0008] Washing machines are usually provided with electrical heater for heating tap water
loaded in the machine in order to improve washing results. Such heaters (electrical
resistances) are designed for working in a fully submerged condition. The demand of
water saving (as a consequence of energy saving) has prompted appliance producers
to design washing machines which use a reduced amount of water in each washing cycle.
This water reduction increases the risk of heater failure, i.e. a damage to the heater
which can also cause risk of fire. It is well known in the art that a heater failure
occurs when the water in the tub or in the water circuit of the washing machine decreases
under a certain level. When the water decreases under a certain level the heater becomes
totally or partially dry and, as a consequence, inside the heater the temperature
increases rapidly and the life of the heater is dramatically reduced.
[0009] Another risky situation can occur when the water level in the tub increases above
a certain level. This situation is known as "overflow" and it can cause a spilling
of water outside the washing machine.
[0010] Normally in a washing machine the heater and the discharge pump are operated by the
control unit of the machine to which dedicated pressure switches (of the type on/off
and calibrated for certain fixed levels of water) are connected.
[0011] The control unit of washing machine using a continuos water level (CWL) sensor comprises
usually a microprocessor or equivalent control system electronic device that is connected
with the CWL sensor in order to allow the control unit to use the correct amount of
water and consequently to achieve better performances and to optimize energy consumption.
[0012] The use of a continuous water level sensor in combination with pressure switches
(which provide for instance signals as far as minimum and maximum water levels are
concerned) is certainly preferable from the point of view of safety, but it is quite
expensive. For cost reasons it is preferred to use only one technology, i.e. a technology
based on pressure switches only or a technology based on a CWL sensor only.
[0013] In the case a CWL sensor is used, the control unit is not 100% safe since its microprocessor,
in case of total or partial failure, cannot guarantee that the water level does not
go under or upper the minimum and maximum value respectively.
[0014] The main object of the present invention is to provide a washing machine that can
operate the heater independently from the microprocessor of the control unit in order
to guarantee the heater reliability and safety. Another object of the present invention
is to provide a washing machine that can operate the discharge pump independently
from the microprocessor in order to prevent water overflow.
[0015] According to the invention, such problem is solved thanks to the features reported
in the appended claim.
[0016] In order to guarantee a certain performance the applicant has developed a technical
solution for washing machines using a CWL sensor able to guarantee also the reliability
of the heater and to prevent the overflow in case a fault of the control unit or its
microprocessor occurs.
[0017] The invention will be described below, with reference to the attached drawing, in
which:
- figure 1 shows schematically a block diagram of a portion of the control circuit of
a washing machine using a CWL sensor, in which the CWL sensor has one analogue output;
- figure 2 shows a block diagram according to a second embodiment of the invention,
in which the CWL sensor has a PWM or square-wave output and an analogue output;
- figure 3 shows a block diagram according to a third embodiment of the invention, in
which the CWL sensor has only a square-wave PWM output;
- figure 4 shows a block diagram according to a fourth embodiment of the invention,
in which the CWL sensor has a square-wave frequency output
- figure 5 shows an electronic circuit according to the invention and used to operate
the drivers for the electrical heater and for the discharge pump; and
- figure 6 shows the output characteristic of a typical CWL sensor, which is able to
provide an analogue voltage output proportional to the applied pressure.
[0018] According to the present invention, a CWL sensor 10 is normally operated with pipeline
connection that it is connected with air trap device (not shown) that it is connected
with the tub (not shown). The CWL sensor 10 can be assembled in order to be in direct
contact with the media (water) without any pipeline. CWL sensor can be also assembled
directly on the printed circuit board (PCB) to reduce the harness cost, and it can
be of a very simple type (basic pressure transducer) where an addition amplifier is
required to be operated by the microprocessor and comparators.
[0019] According to the invention, the simple and low cost electronic circuit connected
to the CWL sensor 10 and to the microprocessor 12 is able to operate directly the
drivers of the heater and of the discharge pump even if a microprocessor fault occurs.
[0020] With reference to figure 1, the control circuit comprises two comparators, respectively
14 and 16, with fixed thresholds acting independently and in parallel with the microprocessor
12. The voltage output 10a of the CWL sensor 10 connected with the microprocessor
12 is connected in parallel with the two comparators 14 and 16. The comparator outputs
14a and 16a are able to operate independently or in parallel with the microprocessor
12. Therefore, in case of failure of the microprocessor 12, the comparators 14 and
16 can drive the heater and/or the discharge pump independently from the microprocessor.
The first comparator 14 compares the output value 10a of the CWL sensor 10 with a
fixed threshold 14b related to a minimum water level for a safe function of the heater.
[0021] The second comparator 16 compares the output value 10a of the CWL sensor 10 with
a fixed threshold 16b related to a maximum water level above which the discharge pump
is switched on. The fixed thresholds (voltage references) are characteristics of each
washing machine.
[0022] Figure 2, in which for the same or similar components the same reference numerals
are used, shows the control circuit where the continuous water level sensor 10 has
two outputs. In addition to the analogue output 10a, a square-wave output 10b is directly
connected to the microprocessor 12 by pulsed width modulation PWM digital output signal
(typically a timer event counter). The second output 10a is, as in the embodiment
of figure 1, an analog output (voltage) connected to the comparators 14 and 16.
[0023] Figure 3 shows a block diagram similar to figure 1 where the continuous control of
the water level through the CWL sensor is performed with a single output. A square-wave
PWM output 10b of the sensor 10 is directly connected to the microprocessor 12 by
PWM digital output and this signal is integrated by means of a resistor and a capacitor
22 which together perform the function of an integrator 24 in order to obtain analog
signal 26 (voltage) to be connected with the comparators 14 and 16. This solution
is normally used with PWM signals or could be used with high frequency signals.
[0024] Figure 4 shows a block diagram similar to figure 3 where the continuous control of
the water level through the CWL sensor is performed with a single output. A square-wave
frequency output 10b is directly connected to the microprocessor digital input and
this signal is also connected with a device 28 usually called frequency to voltage
converter (for example a component known with the name LM2907 manufactured by National
Semiconductor). This electronic component 28 is able to provide a voltage signal proportional
to the input frequency. This voltage output signal is connected with the comparators
14 and 16.
[0025] Figure 5 shows an example of the electronic circuit used to operate the driver for
the heater and for the pump. It is based on dual voltage comparators using the LM393
component that it is an 8-pin integrated circuit and it is a very popular component
with inside two open collector comparators that is sensible to the applied input voltage.
[0026] The first comparator (component LM 393 U1A in figure5) is used for checking the "Level
0". A fixed voltage is established by a voltage divider connected to the inverter
(-) inputs. When the voltage coming from the continuos water level (CWL) sensor, that
it is connected with the non inverting comparator (+) input, is under the fixed voltage
value applied on the inverter input, the output of the comparator is low, and this
means that the output voltage is equivalent to the GND.
[0027] In the case the voltage coming from the continuous water level (CWL) sensor increases
its value and this voltage value is above the fixed reference voltage, an output comparator
commutation is expected. In fact the output switches to high, and this means that
the output voltage is equivalent to the VCC voltage. This information is able to operate
directly the heater relay (heater is switched off) independently from the decision
taken by the microprocessor.
[0028] The second comparator (LM 393 U1B in figure 5) is used for checking the condition
of "Overflow". The above behavior of the component LM 393 U1A is substantially identical
for the LM 393 U1B component that is used to operate the discharge pump driver. The
only difference is the required different reference fixed voltage value, obtained
by the voltage divider, connected to the inverter (-) inputs of the comparator. This
reference voltage value has to be higher than the previous reference voltage value
applied to the inverter input of the LM 393 U1A comparator.
[0029] Even if in the present description reference is made to certain specific water level
values, on the same basic principle other defined water levels could be defined and
used different from a water level linked to a safe function of the heater and to a
water overflow prevention.
1. Washing machine having a continuous water level (CWL) sensor connected to a control
unit including a microprocessor or the like, characterized in that the control unit comprises comparator means suitable for comparing the value from
the CWL sensor with a predetermined threshold value, such comparator means acting
independently and/or in parallel with the microprocessor.
2. Washing machine according to claim 1, comprising a water heater, characterized in that said comparator means comprises a comparator suitable for comparing the value of
the CWL sensor with a threshold value indicative of a condition in which the water
heater is submerged and for driving the water heater only if the value from the CWL
sensor is higher than the threshold value.
3. Washing machine according to claim 1, comprising a discharge pump, characterized in that said comparator means comprises a comparator suitable for comparing the value of
the CWL sensor with a threshold value indicative of a water overflow and for driving
the discharge pump if the value from the CWL sensor is higher than the threshold value.
4. Washing machine according to claims 2 and 3, characterized in that said comparator means comprises a first comparator suitable for comparing the value
of the CWL sensor with a first threshold value indicative of a condition in which
the water heater is submerged and for driving the water heater only if the value from
the CWL sensor is higher than the first threshold value, and a second comparator suitable
for comparing the value of the CWL sensor with a second threshold value indicative
of a water overflow and for driving the discharge pump if the value from the CWL sensor
is higher than the second threshold value.
5. Washing machine according to claim 4, characterized in that the CWL sensor has an analogue output.
6. Washing machine according to claim 5, characterized in that the analogue output is connected to the microprocessor through three parallel connections,
the first one being a direct connection, the other two including the interposition
of the first and of the second comparator.
7. Washing machine according to claim 4, characterized in that the CWL sensor has a PWM or square-wave output.
8. Washing machine according to claim 7, characterized in that the PWM or square-wave output is connected to the microprocessor through three parallel
connections, the first one being a direct connection, the other two including the
interposition of the first and of the second comparator and of a integrator device
between the CWL sensor and the two comparators.
9. Washing machine according to claim 4, characterized in that the CWL sensor has two output, a first one being a PWM or square-wave output connected
directly to the microprocessor, a second one being an analogue output connected indirectly
to the microprocessor with the interposition of the comparators.
10. Washing machine according to claim 4, characterized in that the CWL sensor has a square-wave frequency output.
11. Washing machine according to claim 10, characterized in that the square-wave frequency output is connected to the microprocessor through three
parallel connections, the first one being a direct connection, the other two including
the interposition of the first and of the second comparator and of a frequency to
voltage converter between the CWL sensor and the two comparators.
12. Washing machine according to any of the preceding claims, characterized in that the CWL sensor is a device able to convert the water level into an electrical signal.