FR2609192A1 - Dishwasher automatic control circuit - Google Patents

Abstract

The invention relates to a dishwasher automatic control circuit. It relates to a circuit which automatically controls a water supply solenoid valve S, a heating device H, a wash pump WP and an emptying pump DP on the basis of signals given by level sensors SW1, SW2, a sensor L for washing conditions and an absolute humidity sensor HS. Control is provided by a microcomputer, and the dishwasher is controlled by pressing only a single button, whatever the washing conditions. Application to dishwashers.

Description

 The present invention relates to an automatic dishwasher control circuit, having an absolute humidity sensor and a lavace sensor associated therewith, and more specifically it relates to a circuit intended to ensure a fully automatic washing-drying operation in such a dishwasher, in a suitable time.

 A dishwasher is a device that cleans dirty dishes by washing with water and detergent. In general, it performs a series of treatment steps: draining, introducing water, washing, draining, rinsing, draining and drying.

 Conventional dishwashers have faults not only because the user has to set and enter a washing time depending on the degree of soiling of the dishes, but also because the user, when he is not familiar with such a dishwasher, does not order a complete washing of the dishes when it sets a time less than that necessary for the full washing, or causes a waste of electrical energy when it sets a longer time than necessary, since the proper setting of a full wash time is difficult.

 The subject of the invention is an improved system intended for the automatic implementation of a series of steps for adjusting a washing time which depends on the degree of soiling of the dishes, up to a step of drying of washed dishes, using a microcomputer which receives signals from an absolute humidity sensor and a washing sensor.

Other characteristics and advantages of the invention will emerge more clearly from the description which follows, given with reference to the appended drawings in which
Figure 1 is a section of the dishwasher according to the invention
FIG. 2 is a time diagram representing the input or output signals of the microcomputer of FIG. 3
FIG. 3 is a diagram of a circuit according to an embodiment of the invention
FIG. 4 is a time diagram representing the input or output signals from the microcomputer of FIG. 3, under normal washing conditions; and
FIG. 5 is a time diagram representing the input or output signals of the microcomputer of FIG. 3, when washing fatty dishes.

We refer to Figure 1; the dishwasher according to the invention comprises an absolute humidity sensor HS, a supply solenoid valve S, a heating device H, a washing sensor L, a washing pump WP, a drain pump DP, switches SW and 5W of detection
i 2 tion of water level and a basket DS of dishes.

 Reference is now made to FIG. 3 which represents the entire diagram of the circuit of this embodiment of the invention.

 In this embodiment of the present invention, a microcomputer 6 is used for controlling the system. More precisely, this microcomputer 6 controls data entry via a keyboard 8, a section 3 for detecting washing conditions, a section 4 for detecting absolute humidity, a section 5 of temperature detection, and of section 7 of water level detection, and it transmits control signals to a section 1 of piloting which plays the rattle of a charging circuit of the microcomputer 6.

The piloting section 1 includes a device H for heating the water in the dishwasher, a solenoid valve
S used for introducing water into the dishwasher, a WP dishwashing pump, a DP drain pump used for discharging the water contained in the dishwasher to the outside, relay RY to
RY used to control its operation,
4 transistors Q2 to Q for controlling relays RY to RY,
5 i LED photoemissive LEDs that indicate visual
i 4 ment the operation of each of the relays, and of the polarization resistors R to R
2 13
A usual DC power supply 2 includes a switching transistor Q1, a Zener diode
ZD, a smoothing capacitor C and a two-wave rectifier BR.

The washing conditions detection section 3 includes switching transistors Q6 to Q, polarization resistors R to R, a sensor L intended for
14 21 detect the washing conditions, capacitors C and
2 C of coupling and a rocker FF intended to ensure a
3 conformation.

On the other hand, the absolute humidity detection section 4 includes an absolute humidity HS sensor which consists of a free thermistor and a sealed thermistor, filled with completely dry air, operational amplifiers OP and OP intended for a
i 2 - cricuit voltage follower, an operational amplifier
OP intended for a comparator of the output voltage of a
4 operational amplifier OP at the voltage determined by
3 resistors R and R28, and resistors R to R
27 28 29 33 calibration of the balance of the HS absolute humidity sensor.

The temperature detection section 5 comprises a thermistor TH intended to be used for detecting the water temperature, an operational amplifier OP intended for a voltage follower circuit and
5 operational amplifiers OP and OP intended for
6 7 comparators with hysteresis characteristics.

Section 7 of water level detection includes switches 5W1 and SW of water level detection and
2 of the voltage reduction resistors R and R '.

42 42
Reference is now made to FIGS. 2 to 5 for the description of the operation of the embodiment described above.

When a "normal wash" or "deep wash" button is selected, the microphone output signal O
4 computer c, as shown in the timing diagram in Figure 4, goes high.

Thus, the transistor Q5 for controlling the relay RY
4 is put in the conducting state and therefore the DP drain pump works. When draining is almost complete, the SW water level detection switch will
2 begins to open and causes the input signal I of the microcomputer 6 to go low. Thus, the signal from the
6 microcomputer output O 6 jumps high and the
2 RY relay contacts close when the winding of the
2 relays RY is energized. When the RY relay contacts
2 2 are closed, the solenoid valve S operates under the control of the AC network current transmitted via the contacts, and water then enters the dishwasher through the solenoid valve S.

This water supply continues until the input signal I of the microcomputer 6 jumps to the state
4 high after closing the 5W1 water level detection switch.

When the input signal I from the microcomputer 6
4 goes high, the signal from the microphone's output O
2 computer 6 goes from high to low state, the contacts of relay RY open because the winding of relay 2 is no longer energized, and the solenoid valve S closes.

Then when the signal from the microphone output O
3 computer 6 goes high, winding RY is
3 excited and the WP wash pump works and starts washing the dishes.

 On the other hand, when a "greasy wash" key on the keyboard 8 was initially selected, the washing is carried out after heating the water transmitted to the dishwasher to a predetermined degree due to the operation of the HT heating device. which is controlled by the signal from the output O of the microcomputer 6 as shown in FIG. 5. Two fatty wash keys on the keyboard 8 can be used, that is to say a "normal fatty wash" key and a touch of "deep fat wash". Two different temperatures are preset for two buttons and the user can select one or other of the buttons depending on the amount of grease or oil sticking to the dishes.

When washing takes place, the water in the dishwasher becomes dirty. Thus, the light emitted by the photoemissive diode L which constitutes the washing sensor L
D hardly reaches the lens of phototransistor L and
TR this one thus stops driving. Thus, the input signal D of the rocker FF goes to a high state and the signal of the output Q of the rocker FF, which is connected to the input 15 of the microcomputer 6, goes to the low state. When a determined time has elapsed after the input I signal
5 of microcomputer 6 has gone low, the signal of output O of microcomputer 6 has gone low and the
3 washing may stop.

 Then, the steps for emptying and introducing water, as described above, follow in the correct order and the rinsing step begins as shown in FIG. 5 under the control of the microcomputer 6.

Furthermore, the phototransistor L of the
TR wash L is sensitive to light from the light emitting diode L and goes into the conductive state so that
D the signal from input I of microcomputer 6 goes to
5 again high.

 Rinsing continues for a preset time.

When the rinsing is finished, the signal of the output O of the microcomputer 6 goes high and
4 thus the draining continues until the switch
SW for water level detection closes as described above. When the emptying is finished, the signal of the output O of the microcomputer 6 goes to the high state and thus the heating device H starts to operate so that it dries the washed dishes. This drying continues until the output signal from section 4 of absolute humidity detection goes high.

The HS absolute humidity sensor, which consists of a free thermistor and a sealed thermistor, forms a bridge circuit with resistors R and R as shown in Figure 3. Two
23 24 output signals of the bridge circuit are amplified by the OP and OP voltage follower amplifiers and the diff
The difference between the two output signals is then amplified by the operational amplifier OP. The output signal of the OP amplifier is compared with the determined voltage
3 by resistors R and R and by the amplifier
27 28 operational OP whose output signal reaches the
4 very of the microcomputer 6.

 During the drying step, the humidity comes into contact with the surface of the absolute humidity sensor HS and thus, the resistance value of a free thermistor becomes greater than that of an enclosed thermistor.

 During drying, the humidity of the surface of the absolute humidity sensor HS is gradually removed due to the operation of the heating device H and consequently the difference between the two output voltages of the bridge circuit decreases.

 Thus, when the value of the resistance of the free thermistor is almost equal to that of the enclosed thermistor, the drying is finished under the control of the microcomputer 6. At this time, the dishes are completely washed.

Resistors R to R are intended to be
29 33 used for setting the initial state of the HS absolute humidity sensor. The reason why the two comparators OP and OP are used in section 5 of
6 7 temperature detection is the improvement of the washing performance by adjusting the two different temperatures of the washing water according to the amount of oil or grease hanging on the dishes.

 The foregoing description shows that the invention gives the advantages necessary for carrying out a fully automatic washing-drying, following the manipulation of a single button, without wasting electrical energy, by adjusting a suitable washing time ensured by an automatic system.

 Of course, various modifications can be made by those skilled in the art to the circuits which have just been described only by way of nonlimiting examples without departing from the scope of the invention.

Claims (5)

 1. automatic dishwasher control circuit, having a microcomputer as a control member, said circuit being of the type which comprises  a diet,  a control device (1) intended to receive control signals from the microcomputer,  the control device (1) comprising a device (it) for heating the water inside the dishwasher, a solenoid valve (S) for water supply, a pump (WP) for washing dishes, a pump ( DP) for water drainage, four relays (RY -RY) for controlling their  1 4 operations, and four relay control transistors,  a device (L) for detecting the washing conditions during a washing operation,  a device for detecting the temperature of the washing water during a washing or rinsing operation,  a device (HS) for detecting the absolute humidity inside the dishwasher, intended to allow the end of a drying operation,  a keyboard (8) having keys corresponding to normal washing, deep washing, normal fatty washing and deep fatty washing operations, and  a level detection device (sil, SW)  2 of water comprising two water level detection switches intended for controlling the supply and draining of water,  characterized in that the automatic washing-drying operation is carried out by manipulation of a single key on the keyboard.  2. Circuit according to claim l, characterized in that the control device (1) further comprises four photoemissive diodes (LED -LED) visual indication  i 4 Lely the operation of the heating device, the solenoid valve, the washing pump and the drain pump.  3. Circuit according to claim l, characterized in that the washing concision detection device comprises a washing sensor (L) comprising a photoemissive diode (L) and a phototransistor (L), intended for  D TR detect the washing conditions, switching transistors, and a conformation rocker (FF), the output signal of the rocker being transmitted to the microcomputer.  4. Circuit according to claim l, characterized in that the device (HS) for absolute humidity detection comprises an absolute humidity sensor itself comprising a free thermistor and an enclosed thermistor, constituting a bridge circuit with resistors , two voltage follower circuits (OP, OP) intended for amplifier  2 proud two output signals from the bridge circuit, a differential amplifier (OP) intended to amplify the difference  3 between the two output signals of the voltage follower circuits, and a voltage comparator (OP) intended for  4 compare the output signal of the differential amplifier with a predetermined value.  5. Circuit according to claim l, characterized in that the temperature detection device comprises a thermistor (TH) intended to detect the temperature of the water, a circuit (OP) voltage follower and two compara  5 teurs (OP6, OP) with hysteresis characteristics.