DE3744558A1 - CONTROL CIRCUIT FOR A DISHWASHER - Google Patents

Abstract

The control has a microcomputer 1 which is responsive to entry of data from a key input means 7 and a temperature detecting means 4 to control driving means 5; the control also including means 8 for displaying the process selected by the key input means 7 and an initialising circuit 3 for holding the microcomputer inputs at required levels during power-on and power-off to prevent malfunction. The driving means 5 includes a heater for heating the washing water and for drying the washed tableware, a washing pump for washing tableware, a water feeding valve for controlling the water feeding and a draining pump for draining water in the washer. The control circuit enables the washer not only to carry out a complete washing and drying process by pushing the key for normal washing, strong washing, rinsing or drying but also to promote effective washing by the precise control of the microcomputer. <IMAGE>

Description

The invention relates to a control circuit for a tableware Dishwasher, which is particularly designed so that it not only makes it possible to wash the dishes after washing them dry, but also a malfunction of one as a control part related microcomputers can prevent.

The demand for dishwashers is due to the rising living standards have steadily increased in recent times gen. These dishwashers should not only be used alone work as dishwashers, but also as dryers.

In conventional dishwashers, it is difficult to to achieve the desired rinsing effect, as this mechani Use the timer. Because these machines the temperature of the rinse water can not control exactly, it is still impossible to effectively rinse in warm water.

These conventional dishwashers still have that Disadvantage that they can not dry if they are too drying dishes and that it is for the Users not only difficult, the progress of the work ganges to track optically, but is even impossible that Set the flushing time precisely to achieve the desired result achieve.

The invention is intended to provide a control circuit for a Ge Dishwasher can be created, it is the dishes dishwasher allowed to dry dishes as well effective rinsing and a visual display of the process every operation allowed.  

The invention is intended in particular to provide a control circuit be created for a dishwasher that prevent changes that the microcomputer used as a control part detention works when the main energy source is on or off is switched.

The following is a special with the drawing ders preferred embodiment of the invention be closer wrote. It shows

Fig. 1 is a sectional view of a dishwasher is ne according to an embodiment of OF INVENTION dung,

Fig. 2 is a perspective view of the dishwashing machine is provided in Fig. 1,

Fig. 3, in a schematic block diagram of an embodiment of the control circuit according to the invention,

Fig. 4 is a circuit diagram of from 3 illustrated execution example in FIG.

Fig. 5 is a waveform diagram for explaining the operation of the in Fig. 4 shown Before preparation part,

Fig. 6 is a waveform diagram for conventional preparation circuits before, and

Fig. 7 is a flowchart of the operation of the microcomputer in the embodiment shown in Fig. 3.

As shown in FIGS . 1 and 2, the dishwasher according to an embodiment of the invention Ge comprises a washing pump WP for washing the dishes, a rotary wing, a plate frame, a water inlet valve V , which controls the water inlet in the dishwasher, a drain pump DP for pumping the water to the outside and a heater H for heating up the water supplied through the water inlet valve V and for drying the washed dishes.

In FIGS. 3 and 4, a preferred embodiment of the control circuit according to the invention.

A microcomputer 1 performs all processing or control tasks of the system.

A conventional energy supply part 2 supplies the entire circuit with a regulated DC voltage and a regulated DC current.

A preparation part 3 is designed so that it prevents malfunction of the microcomputer when the power supply is first applied to the microcomputer 1 or the power supply fails or is switched off.

A temperature detector part 4 comprises a thermistor TH , Wi resistors R ₆ to R ₈ and an analog / digital converter. This part 4 heats the washing water to a predetermined temperature of about 60 ° C and keeps the temperature inside the dishwasher dishwasher stable while the dishes are being dried.

A driver part 5 comprises a relay RY for operating the heater H , Triacs T ₁ to T ₃ for operating the flushing pump WP , water supply valve a buzzer BZ , which gives an acoustic signal when each operation ends or via a key in the key input part 7 information will give.

The door detector part 6 determines whether the door switch DR of the dishwasher is open or closed.

The key input part 7 contains keys for normal rinsing, heavy rinsing, rinsing and drying.

In the key input part 7 two water level detector gate switch ESW and a float switch FSW are also provided.

A display part 8 visually shows the work process that is selected via the respective key in the key input part 7 .

One of the light emitting diodes LED ₁ to LED ₄ lights up during the normal rinsing process, during the heavy rinsing process, during rinsing or during the drying process. Furthermore, one of the light emitting diodes LED ₅ to LED ₈ lights up in the same way as one of the first four diodes LED ₁ to LED ₄ , which indicates the predetermined time in which each of the above-described operations takes place.

In Fig. 4 resistors R ₁ to R ₃₀ , transistors Q ₁ to Q ₁₅ , a Zener diode ZD , diodes D ₁ to D ₆ , capacitors C ₁ to C ₉ and a conventional frequency detector part 9 are Darge.

The following is the operation of the above embodiment described for example.

When the power supply is switched on for the first time, a DC voltage V _{1 is applied} to the microcomputer by a conventional power supply part 2 in the manner shown in FIG. 5. If a P-MOS, ie, a P-channel metal oxide semiconductor microcomputer is used, it may malfunction unless its reset terminal INIT is held high for a given time interval from Δ T until the Voltage at its power supply input V _{CC reaches} the normal voltage level V _DD .

Even if the power supply fails or is switched off, the reset connection INIT of the P-MOS microcomputer must be kept at a high level for a given time interval of Δ T beforehand.

Fig. 6 shows three conventional preparation circuits to prevent the microcomputer from malfunctioning. These circuits have the disadvantage that, due to faults in a Zener diode or in a capacitor, they can not only deliver the desired effect only inadequately, but are also not able to take countermeasures against a malfunction of the microcomputer in particular , if the main energy source is repeatedly switched on and off within a short time.

As shown in Fig. 4, the input voltage V _{1 is divided} across the smoothing capacitor C ₁ by the resistors R ₂ and R ₃ in the preparatory part 3 and the divided voltage V _{2 is applied} to the base of the transistor Q ₂ . Thus, the transistor Q ₂ turns on while, in contrast, the transistor Q ₃ blocks, so that its collector comes to a high potential until the divided voltage V ₂ to the voltage level VDD + VQ ₂ BE after application of the normal voltage V _DD to the power supply input V _{CC of} the Mikrocom computer 1 rises. Under these circumstances, when the divided voltage V ₂ becomes equal to the voltage VDD + VQ ₂ BE , the transistor Q ₂ turns off and the transistor Q ₃ turns on, so that the collector of the transistor Q ₃ , which is connected to the INIT reset circuit of the microcomputer 1 is connected to the level never reached. A malfunction of the microcomputer 1 when the power supply is first switched on is thus avoided. The preparation part 3 according to the invention works in the same manner as described above when the power supply fails or is switched off.

After the microcomputer 1 has reached normal operating conditions, it waits for key inputs from the key input part 7 .

When the normal rinse or heavy rinse button is selected, the microcomputer 1 operates as shown in the flowchart of FIG . First, the output signals O ₃ and O _{4 of} the microcomputer 1 come to a high level and switch on the triacs T ₂ and T ₃ . The water inlet valve V accordingly opens and delivers water into the dishwasher, at the same time the water in the dishwasher is pumped out through the work of the drain pump DP . This removes the rest and the water remaining in the dishwasher before washing the dishes.

Depending on which operation is selected, the microcomputer 1 will then change its work. If, for example, a normal flushing process is selected, the drainage and the water supply are carried out in the manner described above over a given time interval and the specified normal flushing time of approximately 25 minutes in the memory is started. Then the process is ended in that the output signal O _{4 of} the microcomputer 1 comes to a never drig level while the water supply continues. When the water entering the dishwasher reaches a given height, the float switch FSW is closed so that the input signal IN _{4 of} the microcomputer 1 jumps to a high level, and accordingly the output signal O ₃ comes to a low level. In this way, the water supply valve V interrupts the water supply.

At this time, the output signal O _{2 of} the Mikrocom computer 1 comes to a high level, the triac T ₁ switches on and the washing pump WP is thereby put into operation to wash the dishes. The output signal O _{1 of} the microcomputer 1 also comes to a high level or a low level depending on the water temperature information coming from the temperature detector part 4 . For example, if the temperature of the rinse water is below about 60 ° C, then the output signal O _{1 of} the microcomputer 1 is at a high level, the relay RY is energized and the heater H is thereby operated. If the temperature is above 60 ° C, the work of heater A is switched off because the output signal O _{1 has} a low level. The reason that the dishes are washed in warm water is because the washing efficiency is higher.

After the rinsing time specified in the microcomputer 1 has elapsed, rinsing is carried out.

After rinsing, the output signals O ₁ to O _{4 of} the microcomputer 1 come to a low level and the heater H , the rinsing pump WP , the water supply valve V and the drain pump DP in the driver part 5 are switched off for about 2 seconds. This was done for the purpose of letting the swirling water come to rest so that it can then run off evenly.

After 2 seconds have passed, the output signal O _{4 of} the microcomputer 1 jumps to the high level, the triac T ₃ switches on and the drain pump DP is thereby put into operation. After a given time interval for the drain, the water inlet valve V opens to allow water intake and water drainage so that food residues and dirty water are removed from the dishwasher.

Then the output signals O ₃ and O _{4 of} the microcomputer 1 jump to a low level and the water inlet and outlet are interrupted, thereby eliminating any water turbulence. The water is then pumped out by the drain pump DP . After completion of this pumping, the output signal O _{3 of} the microcomputer 1 jumps to the high level and water is fed into the dishwasher until the float switch FSW closes. When the float switch FSW closes, the water supply is ended and then a rinse in cold water follows for a given time interval, which is predetermined by the microcomputer 1 . At this point, the off output signal O ₄ of the microcomputer 1 at a high level maintained, while the other output signals O ₁ to O ₃ remain at a low level.

After completing the rinse aid in cold water, the run from, the water supply and heating the water to about 60 ° C, the output signal O _{2 of} the microcomputer 1 comes to a high level and rinsing is carried out in warm water for a given time interval. After completion of the Klarspü lens, the output signal O _{4 of} the microcomputer 1 jumps to a high level and the drain pump DP begins to work.

After the entire rinsing process is complete, a drying process follows. At this time, the state of the output signal O _{1 of} the microcomputer 1 is controlled as a function of the input signal from the temperature detector part 4 . When the temperature in the dishwasher is above 60 ° C, the heater H is turned off, while when it falls below 60 ° C, the heater H is turned on, causing the temperature in the dishwasher to rise to about 60 ° C is held.

After the drying process over a given time interval vall is complete, all operations are from rinsing finished drying.

Two ESW water level detector switches act as safety switches to interrupt another water supply during the introduction of the water if the FSW float switch is not working properly.

If the door is opened during operation of the dishwasher, the door switch DR is switched off, as a result of which the energy supply to the heater H , the washing pump WP and the water inlet valve V is interrupted, in order to avoid a danger to the user. The Türde tektorteil 6 also outputs high-level signals to the microcomputer 1 so that it can perceive men opening the door.

The frequency detector part 9 is connected to the AC power supply line and outputs a signal with a rectangular waveform and a frequency of 60 Hz as a timing signal to the microcomputer 1 .

As described above, the scarf according to the invention tion designed so that they not only automatically fill up carries out constant rinsing and drying process, in which the User only the button for normal rinsing, the strong one Rinse, rinse or drying must press, but that they also have an effective rinsing process over an accurate Control of each operation supported, the spe  The advantage is that the Mikrocom malfunctions puters is avoided.

Claims (6)

1. control circuit for a dishwasher with egg nem microcomputer as a control part, characterized by an energy source,
a preparation device ( 3 ) between the energy source and a reset connection of the microcomputer ( 1 ),
a temperature detector device ( 4 ) for the washing water during a washing or rinsing process or for the interior of the dishwasher during a drying process,
a driver device ( 5 ) which is connected to the microcomputer ( 1 ) and receives control signals therefrom, the driver device ( 5 ) a relay (RY) for operating a heater (H) , three triacs (T ₁ - T ₃ ) for operation a flushing pump (WP) , a water inlet valve (V) and a drain pump ( DP) and switching transistors that control the triacs (T ₁ - T ₃ ) and the relay (RY) ,
a key input device ( 7 ) with keys for normal rinsing, heavy rinsing, rinsing and drying,
a door detector device ( 6 ) which outputs a detector signal for an open door to the microcomputer ( 1 ) when the door is opened during the work of the dishwasher, and
a device ( 8 ) which optically indicates the operation selected by the respective key in the key input device ( 7 ). 2. Control circuit according to claim 1, characterized in that the preparation device ( 3 ) divider resistors (R ₂ , R ₃ ) and two switching transistors (Q ₂ , Q ₃ ) which work in opposite directions, the base of a transistor (Q ₂ ) with the divider resistors (R ₂ , R ₃ ) connected ver, while the collector of the other transistor (Q ₃ ) is connected to the reset terminal of the microcomputer ( 1 ). 3. Control circuit according to claim 1, characterized in that the temperature detector device ( 4 ) has a thermistor (TH) , divider resistors (R ₆ - R ₉ ) and an analog / digital converter as an interface to the microcomputer ( 1 ). 4. Control circuit according to claim 1, characterized in that the driver device ( 5 ) further comprises a buzzer (BZ) which provides an acoustic signal when each operation is ended, or when a key in the key input device ( 7 ) gives information . That the key input means (7) has a float switch (FSW) has 5. A control circuit according to claim 1, characterized in that for controlling the water inflow and two water level detector switch (ESW), which operate as Si cherheitsschalter when the float switch (FSW) during water inflow not works properly. 6. Control circuit according to claim 1, characterized in that the display device ( 8 ) four light emitting diodes (LED ₁ - LED ₄ ) for displaying normal rinsing, heavy rinsing, rinsing and drying and another four light emitting diodes (LED ₅ - LED ₈ ) to display the specified times for the completion of normal rinsing, heavy rinsing, rinsing and drying each because.