EA024506B1 - Circuit configuration for operating a household appliance, household appliance comprising this configuration, and method for operating a household appliance - Google Patents

Abstract

The invention relates to a circuit configuration for operating a household appliance, such as washing and/or drying machine, having an electric drive motor, and to a method allowing proper operation of a household appliance after an AC power supply Uhas failed. The circuit configuration (1) comprises a motor control unit (6) and a main control unit (18). The motor control unit (6) is supplied with electrical energy Uwith the aid of a motor supply circuit (7). The motor supply circuit (7) comprises an intermediate circuit capacitor (14) for storing electrical voltage. The main control unit (18) is supplied with electrical energy Uby a main supply unit (19). After the AC power supply Ufails, the main control unit (18) is supplied with electrical energy Ufrom the intermediate circuit capacitor (14). Uncontrolled shutoff of the main control unit (18) and the motor control unit (6) can thereby be avoided.

Description

The invention relates to a circuit device for controlling a household appliance, such as a washing and / or drying machine, having an electric drive motor, as well as to a household appliance with such a circuit device. In addition, the invention relates to a method for properly controlling a household appliance in the event of a possible disappearance of an alternating supply voltage at the input of a circuit device of a household appliance.

State of the art

In this case, we are talking about a household appliance, such as a washing and / or drying machine, which contains an engine control unit for controlling an electric machine, as well as a main control unit for supplying control commands to the engine control unit. In such household appliances, the engine control unit and the main control unit are powered by separate power circuits, for example, by separate power supplies. These power schemes have a different structure; The power circuit for the engine control unit includes, as a rule, an intermediate link capacitor that smooths the rectified voltage. A similar power supply circuit for the engine control unit is described, for example, in the publication DOO 2005/060064 A1.

Patent application No. 102008044378 A1 describes a circuit device for controlling a household appliance, in which the control device remains connected to the power connector through the door contact even when the power supply to the mains is cut off. For this, a switch is provided, which is closed for a period during which the door of the household appliance remains locked.

Patent application EP 1768251 A1 describes an inverter circuit for activating a brushless DC motor, which is equipped with an integrated energy recovery unit for supplying a driver stage and a driver stage through an intermediate capacitor in case of a power outage.

Patent application I8 2008/0155294 describes an office device, such as a printer or copier, equipped with an additional energy storage device in the form of a special charging capacitor, which continues to power the device in case of a power outage.

SUMMARY OF THE INVENTION

The objective of the invention is to find a solution that allows one circuit device to work properly with the engine control unit and the main control unit, in particular, after the disappearance of the alternating voltage from the mains.

According to the invention, this problem is solved by a circuit device, a household appliance and a method with the features disclosed in the respective independent claims. Advantageous embodiments of the invention are disclosed in the dependent claims and in the following description.

A circuit device for controlling a household appliance, such as a washing and / or drying machine, having an electric drive motor described by the invention, comprises a circuit input of an alternating supply voltage. In addition, it contains an electric motor control unit for a household appliance. The motor power circuit can be connected to the circuit input via an electrical switch and is capable of supplying a first operating voltage to the engine control unit. The first operating voltage may power the engine control unit. The power supply circuit of the engine contains an intermediate capacitor, which accumulates electricity. In addition, the circuit device contains a main control unit for controlling a household appliance and supplying control signals (via control commands) to the engine control unit. In addition, the main control unit activates an electrical switch and thereby can connect the motor power circuit to the circuit input. In addition, a main power supply is connected to the circuit input, which produces a second operating voltage, which can be fed to the main control unit. The main control unit is additionally connected to the motor power supply circuit, and the motor power supply circuit is capable of generating from the energy stored in the intermediate link capacitor a third operating voltage for supplying the main control unit.

The invention exploits the fact that the motor power circuit typically contains an intermediate link capacitor that accumulates an electric charge. The invention provides for the use of the electric charge accumulated in the intermediate capacitor to power the main control unit, in particular by generating a third operating voltage. In the event of a short-term interruption in the supply of alternating supply voltage (for example, when choosing a household appliance program, briefly turning off and turning on a household appliance made by the user using the main switch, or turning off the mains), the main power supply unit stops supplying operating voltage to the main control unit. In the prior art, with such a short-term disappearance of the alternating supply voltage, the engine control unit is still supplied with electric power, in particular, from the intermediate capacitor, while the main control unit is stopped. Thus, after the restoration of AC voltage

- 1 024506 power supply, the main control unit and the engine control unit are in various operating states; the main control unit is rebooted (reset), but the engine control unit is not. Thus, in the prior art, there are problems when restarting a home appliance program that has already started to run; programs must again be synchronized in the main control unit and in the engine control unit. The present invention solves precisely this problem, in particular, by supplying the main energy control unit accumulated in the intermediate link capacitor. In case of disconnection of the alternating supply voltage, the voltage of the intermediate capacitor can power both the main control unit and the engine control unit, that is, the main control unit and the engine control unit will be reset (reset) at the same time. As a result, the operating states of the main control unit and the engine control unit after restoration of the alternating supply voltage will be the same.

A further advantage of the invention is that after turning off the AC supply voltage, the main control unit will have a certain time to start predefined processes. In particular, the main control unit may initiate a controlled shutdown of the engine control unit in accordance with a predetermined algorithm. In addition, the main control unit may be switched off, in particular, appropriately in accordance with a predetermined algorithm. This will avoid errors that occur at the level of technology after an accidental reboot (reset) of the main control unit and the engine control unit. Thus, the main control unit, due to the presence of the third operating voltage from the intermediate capacitor, can initiate a controlled and conscious shutdown of the engine control unit and / or the main control unit.

Another advantage of the circuit device is that the testing costs during the development of a household appliance can be minimized, since the influence of different reset times of the engine control unit and the main control unit no longer takes place and, accordingly, does not need to be studied.

Preferably, the third operating voltage is numerically equal to the second operating voltage. In this case, the main control unit is supplied with a constant voltage of the same rating even after disconnecting the alternating supply voltage.

The third operating voltage can be generated, for example, by a blocking current transformer. In this case, such a blocking current transformer will relate to the motor power circuit. This embodiment is particularly advantageous, in particular, for those circuit devices in which a voltage isolation is provided between the engine control unit and the main control unit, that is, the engine control unit and the main control unit belong to different reference potentials. As a rule, such a voltage isolation is achieved due to the fact that the motor power circuit contains a bridge rectifier that rectifies an alternating supply voltage. Thus, a voltage isolation is created between the engine control unit and the main control unit; in this case, the main control unit sends control signals with control commands to the engine control unit via a data line that does not affect voltage isolation. Such a data line may be formed, for example, by an optocoupler or a protective impedance. After disconnecting the AC supply voltage, the main control unit can send control commands on the data line to the engine control unit. These commands initiate a controlled shutdown of the engine control unit according to a predefined protocol.

The engine control unit and the main control unit can recognize the disconnection of the alternating supply voltage, in particular, by stopping the supply of operating voltages. After disconnecting the AC supply voltage, only the electrical voltage accumulated in the intermediate capacitor remains available. Such energy stored in the intermediate capacitor must be effectively distributed between the engine control unit and the main control unit. Since the main control unit is the main control device of the household appliance, it takes a longer time to perform certain processes in the household appliance after disconnecting the AC supply voltage. Therefore, in one embodiment, the engine control unit, having detected a disconnection of the alternating supply voltage, is independently disconnected from the first operating voltage and, thereby, switches to standby mode independently. In this mode, the engine control unit consumes very little power (or does not consume it at all), as a result of which the energy stored in the intermediate link capacitor can be fully used by the main control unit. In this case, the time available for the main control unit to perform certain actions in the household appliance after switching off the AC voltage is doubled.

As already mentioned, the main control unit, having detected a disconnection of the alternating supply voltage, can initiate certain actions in the household appliance that guarantee the proper operation of the household appliance after restoring the alternating supply voltage. For example, if the main control unit detects a disconnection of the AC supply voltage, it may save fault data in the memory device. Such malfunction data may include information about the running program of the household appliance, the execution of which was interrupted with the AC voltage turned off. These malfunctions may include, for example, an indication of the stage at which the execution of the program was interrupted due to disconnection of the AC supply voltage. In this case, after restoring the supply of alternating voltage, the program can be started from this stage and completed properly. Preferably, the main control unit comprises read-only memory. In this case, the main control unit can save the fault data after recognizing the disconnection of the AC supply voltage, and this data can subsequently be analyzed during maintenance or contacting the service technicians. Such fault data may include, for example, the moment the AC voltage was turned off and / or the designation of the program selected at the time the AC voltage was turned off, etc.

The household appliance described by the invention, such as a washing and / or drying machine, comprises a circuit device described by the invention or its preferred embodiment.

The method described by the invention ensures the proper operation of a household appliance in the event of a possible disconnection of an alternating supply voltage at the input of a circuit device of a household appliance. The main control unit is powered by constant voltage from the main power supply connected to the input of the circuit device. The main control unit closes the electrical switch, as a result of which the intermediate capacitor, which is part of the motor power circuit, is charged with a constant electric voltage. Thus, the engine control unit is powered by a constant voltage from the intermediate capacitor. After disconnecting the alternating supply voltage, the main control unit is supplied with electric energy from the intermediate capacitor.

Preferred embodiments of the circuit device described by the invention and, in particular, their advantages apply equally to the household appliance described by the invention and the method described by the invention.

Other features of the invention are disclosed in the claims, in the drawings and in the description of the drawings. The above signs and combinations of signs, as well as signs and combinations of signs mentioned below in the description of the drawings and / or drawings, can be used not only in these combinations, but also in other combinations and / or separately, without going beyond the scope of the invention .

List of drawings

Preferred embodiments of the invention are discussed in detail in the description below based on the accompanying drawings, in which:

FIG. 1 - circuit device according to one embodiment of the invention; FIG. 2 is a power supply unit of an engine power circuit in a circuit device according to FIG. one.

Information confirming the possibility of carrying out the invention

The circuit device 1 shown in FIG. 1, serves to drive a synchronous motor 2 with excitation from permanent magnets installed in the washing machine. The synchronous motor 2 drives the washing drum of the washing machine. To activate the synchronous motor 2, the circuit device 1 contains an inverter 3, which includes six transistors 4. The inverter 3 can provide alternating voltage for each of the three windings 5 of the synchronous motor 2.

The inverter 3 is activated by the engine control unit 6, which is, for example, a microprocessor. Thus, the engine control unit 6 controls the synchronous motor 2 using the inverter 3.

The engine control unit 6 is supplied with a first operating voltage and ₁ , which is provided by the engine control circuit 7, in particular with respect to the first reference potential 8. The first operating voltage and ₁ can be, for example, 5 or 3.3 V, but can also be from 1 up to 2 V.

The motor power supply circuit 7 contains a bridge rectifier 9, the primary side of which can be connected on one side by an electric switch 10, in this case made in the form of a relay, to the first input connector b of the circuit input 11, and the other side is connected to the second input connector N of the circuit input 11 The second input terminal N represents the second reference potential. The secondary side of the bridge rectifier 9 is connected on one side through the protective circuit of the starting impulse current 12 to the pole 13 of the intermediate circuit, and on the other side to the first reference potential 8. The pole 13 of the intermediate circuit is connected via the intermediate capacitor 14 to the first reference potential 8; in parallel with the intermediate capacitor 14, a power supply unit 15 is turned on, which produces the first operating voltage and ₁ .

If an alternating supply voltage υ _{Ν is} applied to the circuit input 11, then the bridge rectifier 9 (with the relay 10 closed) produces a rectified voltage, which is subsequently smoothed by the intermediate capacitor 14. The rectified voltage builds up in the capacitor 14

- 3,024,056 intermediate links. From this voltage accumulated in the intermediate capacitor 14, the power supply unit 15 produces a first operating voltage and ₁ , as well as an additional constant operating voltage and _in . Additional constant operating voltage _and can feed, for example, specifies the inverter device 3. This additional constant operating voltage _and is, for example, 15 V, in particular with respect to the first reference potential supply 8. The unit 15 may comprise, for example, switching power supply e.g. voltage divider. These components can produce, in particular, the first operating voltage υι and an additional constant working voltage u _in from the voltage accumulated in the intermediate capacitor 14.

The protective circuit 12 of the starting pulse current contains an ohmic resistance 16 and a relay 17, which can be activated by the engine control unit 6. The relay 17 can bypass the ohmic resistance 16. In particular, the protective circuit of the starting impulse current serves to protect the motor supply circuit 7 and the inverter 3 from current peaks that occur when the relay 10 is closed.

The washing machine comprises a main control unit 18, which controls the programs or processes of the washing machine and is, for example, a microprocessor. The main control unit 18 also controls the engine control unit 6, and in particular, by supplying appropriate control signals with control commands to the engine control unit 6. These control signals are transmitted via a data line (not shown in the drawing) to the engine control unit 6. Since the engine control unit 6 relates to the first reference potential 8 and the main control unit 18 relates to the second reference potential Ν, the control signals must be transmitted via a protective impedance or an optocoupler.

To power the main control unit 18, a main power supply unit 19 is provided, which is connected to the circuit input 11. The main control unit 19 may comprise, for example, a power supply unit or a switching power supply unit. It produces a second operating voltage υ ₂ , in particular, at the output 20 and relative to the second reference potential Ν. The output 20 of the main control unit 19 is connected through a diode 21 to the power input 22 of the main control unit 18. The diode 21 serves to rectify the second operating voltage υ ₂ . The second operating voltage and ₂ is, for example, 5 or 3.3 V, but can be from 1 to 2 V. Thus, the main control unit 18 is powered by a second operating voltage υ ₂ , which is generated relative to the second reference potential Ν. The commissioning of the motor control unit 6, the inverter 3 and, therefore, the synchronous motor 2 is carried out by closing the relay 10. In this case, the relay 10 is activated by the main control unit 18, and the main control unit 18 closes the relay 10 to turn on the synchronous motor 2.

If the main control unit 18 was powered only by the second operating voltage υ ₂ , then it would be turned off shortly after disconnecting the alternating supply voltage υ _Ν . However, after turning off the alternating voltage υ _{Ν of the} power supply, the engine control unit 6 can be supplied with electricity further (for about 30 s), namely, from the intermediate capacitor 14. The engine control unit 6 could also work further, while the main control unit 18 is already performing a reset. To avoid such an unfavorable development, the power supply unit 15 additionally produces a third operating voltage υ ₃ , which can supply the main control unit 18 and is numerically equal to the second operating voltage υ ₂ , that is, for example, 5 or 3.3 V. This is the third operating voltage the voltage υ _{3 is} produced by the power supply unit 15 from the electricity stored in the intermediate capacitor 14. The third operating voltage υ _{3 is} produced relative to the second reference potential Ν, that is, the voltage isolation between the engine control unit 6 and the main control unit 18 is maintained. In order to produce a third operating voltage υ3, the power supply unit 15 may comprise a blocking current transformer, the primary side of which is connected to the first reference potential 8, and the secondary side to the second reference potential Ν. The power supply unit 15 generates a third operating voltage υ ₃ at the output 23, which is connected through a diode 24 to the power input of the main control unit 18. Diode 24 serves to rectify the third operating voltage υ3.

In FIG. 2 shows an example of a power supply unit 15 of a motor power circuit 7. The power supply unit 15 comprises a blocking current transformer 26 and a switching circuit 27. One side of the first winding 28 of the transformer 26 is connected to the intermediate pole 13, and the other side can be connected by the switching circuit 27 to the first reference potential 8. The first operating voltage υι is generated on the second winding 29. and an additional constant operating voltage υ _Β, in particular relative to the first reference potential 8. in addition, the transformer 26 comprises a secondary winding 30, which generates a third operating voltage ix υ ₃ for the main control unit 18. Moreover, one side of the additional winding 30 is connected to the output 23, and the other side to the second reference potential Ν. The third operating voltage υ _{3 is} rectified by the diode 31 and is supplied to the capacitor 32.

The switching circuit 27 includes a first winding 28 with respect to the first reference potential 8 and thereby initiates the generation of current pulses in the first winding 28, these pulses being transmitted to the second winding 29 and the additional winding 30. Thus, energy can be transmitted. In addition, the switching circuit 27 has feedback on the first operating voltage υ ₁ , in particular, on the wire 33. Thus, the operating voltage υ ₁ and υ ₃ , as well as additional

- 4 024506 constant operating voltage Iv, controlled by a switching circuit 27 depending on the feedback value of the first operating voltage υ ₁ .

The generation of the third operating voltage and ₃ for the main control unit 18 allows you to prevent a situation in which the main control unit 18 will turn off uncontrollably after detecting a disconnection of the alternating supply voltage υ _Ν . After turning off the alternating supply voltage υ _Ν , the main control unit 18 will be powered by the third operating voltage υ ₃ , which is produced from the electricity stored in the intermediate capacitor 14. This allows the main control unit 18 to initiate the execution of certain processes after disconnecting the AC voltage υ _Ν power.

In particular, the main control unit 18 can send control signals via the data line to the engine control unit 6 that initiate a controlled shutdown of the engine control unit 6 in accordance with a predetermined protocol. After detecting the disconnection of the alternating voltage υ _Ν power, the engine control unit 6 can independently enter standby mode, in which it does not consume energy. In this case, the energy stored in the intermediate capacitor 14 is only used to power the main control unit 18, and the main control unit 18 can be powered longer after disconnecting the alternating supply voltage υ _Ν .

Thus, various actions are provided after turning off the alternating voltage υ _Ν power. The engine control unit can switch to standby mode immediately after turning off the alternating voltage υ _Ν power. Alternatively, the engine control unit 6 may still be powered by the first operating voltage υ1 after turning off the alternating supply voltage υ _Ν , and the engine control unit 6 may be turned off simultaneously with the main power unit 18. Thus, the engine control unit 6 and the main control unit 18 will be in the same operating states after restoration of the alternating supply voltage υ _Ν , and they will not need to be synchronized. The simultaneous shutdown of the engine control unit 6 and the main control unit 18 can also be initiated by the main control unit 18 itself.

In addition, the main control unit 18 comprises a read-only memory 25. After turning off the alternating voltage υ _{Ν of the} power supply, the main control unit 18 can store fault data in the memory 25, in particular, information about the running program of the washing machine, interrupted by disconnecting the alternating voltage υ _{Ν of the} supply . After the restoration of the alternating supply voltage υ _Ν , the main control unit 18 can analyze this fault data and continue operating the washing machine based on this fault data. Such fault data may also be useful to the service department performing the maintenance of the washing machine. They will allow you to analyze errors that occur during the operation of the washing machine. During maintenance of the washing machine, these fault data can be read from memory 25 and analyzed.

Essentially, a circuit device 1 has been developed that allows for proper operation of the washing machine after turning off the alternating voltage υ _{Ν of the} supply. In particular, the main control unit 18 is supplied with electric energy from the intermediate capacitor 14, specifically after turning off the alternating supply voltage υ _Ν . Thus, uncontrolled shutdown of the main control unit 18 and the engine control unit 6 is prevented. After disconnecting the alternating voltage υ _{Ν of the} power supply, the engine control unit 6 and the main control unit 18 can be controlled to be switched off, and they will no longer need to be synchronized after the restoration of the alternating voltage υ _{Ν of the} supply.

List of reference signs.

- circuit device

- synchronous motor,

- inverter

- transistors,

- windings

- the engine control unit,

- engine power circuit,

- the first reference potential

- bridge rectifier,

- switch

- circuit input

- protective circuit of the starting pulse current,

- the pole of the intermediate link,

- intermediate capacitor,

- Power Supply,

- ohmic resistance,

- 5,024,506

- relay

- main control unit,

- main power supply,

- exit,

21, 24 - diodes,

- power input

- Memory device,

- transformer

- switching circuit

- first winding,

- second winding,

- additional winding,

- diode,

- capacitor

- the wire,

B - input connector

N is the second reference potential, and ₁ , ₂ , and ₃ are operating voltages, and _in is a constant operating voltage, υ _Ν is an alternating supply voltage.

Claims (9)

CLAIM 1. A circuit device (1) for controlling a household appliance, such as a washing and / or drying machine, having an electric motor (2) of a drive, comprising a circuit input (11) of an alternating voltage (υ _Ν ) supply; an electric motor control unit (6) (2); a power supply circuit (7) for the engine (2) connected to the circuit input (11) via an electric switch (10) capable of supplying to the engine control unit (6) a first operating voltage (υ ₁ ) and containing an intermediate capacitor (14) designed for the accumulation of electricity; a main control unit (18) for controlling a household appliance and supplying control signals to an engine control unit (6), as well as activating an electric switch (10); the main power supply unit (19), which is connected to the circuit input (11) and produces a second operating voltage (υ ₂ ), which feeds the main control unit (18), the main control unit (18) and the engine control unit (6) decoupled voltage and are connected by a data line that does not affect the specified voltage isolation, the main control unit (18) is connected to the motor power circuit (7), and the motor power circuit (7) is able to generate an intermediate link from the energy stored in the capacitor (14) the third operating voltage (υ ₃ ) for power supply to the main control unit (18). 2. The circuit device according to claim 1, in which the motor power supply circuit (7) comprises a blocking current transformer (26) producing a third operating voltage (υ3). 3. The circuit device according to claim 1 or 2, in which the engine control unit (6) is configured to independently disconnect from the first operating voltage (υ1) when an AC voltage is disconnected (υ _Ν ) and thereby switch to standby mode on its own . 4. The circuit device according to one of the preceding claims, wherein the main unit (18) control configured to store in the memory device when detecting disconnection of alternating voltage (υ _Ν) feeding the fault data including information about the running program of the household appliance, the performance of which was interrupted by turning off the alternating voltage (υ _Ν ) of the supply. 5. A household appliance, such as a washing and / or drying machine, comprising a circuit device (1) according to one of the preceding paragraphs. 6. A method for controlling a household appliance according to claim 5 under conditions of a possible disconnection of an alternating voltage (υΝ) of power at the circuit input (11) of the circuit device (1), comprising the following steps: power supply to the main unit (18) for direct voltage control (υ2) from the main power unit (19) connected to the circuit input (11); closing the electric switch (10) with the main control unit (18), thereby charging the intermediate capacitor (14), which is part of the engine power supply circuit (7) (2), and supplying an electric constant voltage (υ ₁ ) to the block (6) engine control (2); - 6 024506 power supply to the main control unit (18), isolated from the voltage with the engine control unit (6), electric energy (and ₃ ) from the intermediate capacitor (14) after disconnecting the alternating voltage (υ _Ν ) of the power supply; transmission of control signals from the main control unit (18) to the engine control unit (6) via a data line that does not affect the indicated voltage isolation between these units (6) and (18). 7. The method according to claim 6, in which to the main control unit (18) after turning off the alternating voltage (υ _Ν ) of the power supply, a constant voltage (υχ) is supplied from the blocking current transformer (26). 8. The method according to claim 6 or 7, in which the engine control unit (6), upon detecting a disconnection of the alternating voltage (υ _Ν ) of the power supply, is put into standby mode. 9. A process according to one of claims 6-8, wherein in the memory of the main unit (18) controls detection disable AC voltage (υ _Ν) power stored fault data including information about the running program of the household appliance whose execution was interrupted with disconnection of alternating voltage (υ _Ν ) power.