FI84877C - Device for remote control of the fan motor in a vacuum cleaner from the suction handle - Google Patents

Abstract

In known devices of this type, only the power of the blowing motor can be controlled. The intention of the new arrangement is also to allow an indication of a necessary filter change whilst maintaining a twin-core control line embedded in the suction hose. For this purpose, an adjustable resistance element (8) with a light diode (9) is switched in series on the handle (1) of the suction hose (2). By periodic short-circuiting of this series circuit, voltage pulses are produced which are converted by means of a peak value rectifier (17) into a continuous direct voltage, by means of which the pulse length of the control pulses generated by a comparator (23) is determined. The power stage of the blowing motor (5) is controlled by the control pulses of the comparator (23). By means of a pressure switch, which is actuated at a certain degree of filling of the filter bag, the periodic short-circuiting of the series circuit of the resistance element (8) and the light diode (9) is interrupted. Illumination of the light diode (9) is effected by the now continuously present voltage. <IMAGE>

Description

3 1 84877

Device for remote control of a vacuum cleaner fan motor from the suction hose handle

The invention relates to a device for remotely controlling the fan-5 motor of a vacuum cleaner from the handle of a suction hose according to the type definition of claim 1.

Such a device is known from DE-A-3 222 458. In this known remote control device, the power of the fan motor can only be controlled by an adjustable resistor connected to the speed control circuit of the fan motor by means of a two-wire cable arranged in the handle.

A similar arrangement is known from EP 136 357, in which the supply lines of the brush motor 15 located in the nozzle of the vacuum cleaner are also used to control the speed of the fan motor of the vacuum cleaner. Switching from brush motor to speed control takes place by means of a switching member in the suction pipe, which cuts off the second conductor and connects it to a rectifier which supplies direct current to an integrator in the vacuum cleaner housing, which in turn controls the electronic drive circuit of the fan motor.

The object of the invention is to make the necessary control of the filter possible in addition to the power control of the fan motor by maintaining the two-wire control line.

The solution to the set task is achieved by the features indicated in the characterizing part of claim 1. With the periodic open and close control of the electronic switch circuit, short voltage pulses occur in the series connection of the resistance and signaling element as well as in the peak rectifier, the intensity of which depends on the resistance value set in the resistance element. The peak value rectifier converts these voltage pulses into a continuous DC voltage, the intensity of which corresponds proportionally to the intensity of the voltage pulses. This DC voltage affects the impulses from the comparator to the speed control device and thus the speed and power of the fan motor. Short voltage pulses are not enough to cause an alarm in the notification elements. Only when the pushbutton has disconnected the short-circuit for the series connection of the resistance and signaling element and through it the DC voltage is continuously present in the signaling element does the signaling take place.

The interference effects caused to the control device le by voltage fluctuations in the DC circuit can be avoided approximately by having the series connection of the resistance signal element as well as the peak rectifier connected to the control rectifier with a stable current source.

Periodic control of the semiconductor switches is achieved by connecting them together to the control output side of the operational amplifier, one control input side of which is directly connected to the other terminal of the control rectifier formed as a single-phase bridge rectifier and the other control input side Thus, a DC voltage must be pulsating on the second control input side of the operational amplifier and continuously running on the other control input side. As long as the voltage on the other control input side is lower than on the other control input side, there is a shutdown signal for the semiconductor switch on the control output side of the operational amplifier. If the value of the pulsating DC voltage rises above the voltage value given via the voltage divider on the other control input side of the operational amplifier, a through control signal for the half-wire connection occurs on the output side of the operational amplifier. Thus, the control signal necessary for the periodic control of the semiconductor switches is produced in a simple manner.

This periodic control signal can also be transferred to the fan motor speed control by connecting the input side of the 3,84877 second comparator to the output side of the operational amplifier and connecting the zener diode, the ohmic resistor and the capacitor to the input side of the comparator in parallel, the resistor and the capacitor The control signal of the operational amplifier charges the capacitor, in which case the charge of the zener diode is always set to the same voltage level. The capacitor and the resistor are separated from the rest of the circuit by a diode so that the capacitor-10 can be discharged only by a resistor. Thus, a ramp-like voltage is produced. As soon as the value of this voltage drops below the value of the voltage on the other input side of the comparator, the comparator gives a control signal to the speed control device. In order to obtain control pulses from the operational amplifier from the flow of the rectified mains voltage, the synchronization of the control signal produced by the comparator with these control pulses to the mains voltage is given by the comparator.

20 Based on an exemplary embodiment shown in the drawing, the subject matter of the application will be described in more detail below.

It shows Fig. 1 a vacuum cleaner equipped with a remote control device operating from the suction hose handle, Fig. 2 shows a circuit diagram of the remote control device.

The number 1 denotes a handle connected to the suction hose 2. The suction hose 2 is connected to the suction socket of the vacuum cleaner housing 3, in which the vacuum cleaner housing has a fan 4 with a fan motor 5. The vacuum cleaner housing 3 has a metal plate 6 containing components 30 for the remote control. The two-pronged control cable 7 attached to the suction hose A controllable resistor element 8 and a light emitting diode 9 are arranged in this handle 1 as a signaling element and are connected in series to a two-branched control line 7.

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The voltage supply of the remote control device takes place by a transformer 10 supplied from the mains voltage U. The secondary winding of this transformer 10 supplies a single-phase bridge rectifier 11 acting as a control rectifier, to the positive terminal 5 of which a separating diode 12 is connected by its anode. A smoothing capacitor 13 and a zener diode 14 connected in parallel with it are connected on the cathode side of the separation diode 12. Thus, the cathode side of the separation diode 12 has a constant voltage at constant height, whereas the DC voltage on the anode-10 side of the separation diode 12 corresponds to sine halves.

The stable current source 15 is likewise connected on its input side to the cathode side of the separation diode 12, i.e. to a smoothed DC voltage circuit. A second branch of the control line 7 and a second branch of the bridge rectifier 11 15 are connected to the output side of the constant current source 14. A peak-rectifier 17 is further connected to the input side 18 of its constant current source 15 by an input resistor 16.

between the peak value rectifier 17, the input side and the balanced-bridge converter mouth 11 is connected to the minus terminal of the first semiconductor switch 19 to 20 kuormitusväleineen. This first semiconductor switch 19 is on its control input side with a control resistor 20 on the input side of the operational amplifier 21. The operational amplifier 21 periodically controls the first semiconductor switch 19 to open and close. In order to produce fractional 25 control pulses, the operational amplifier 21 is connected on its control input side to the positive terminal of the bridge rectifier 11, in which case this connection can also take place with a voltage divider. The other control input side of the operational amplifier 21 is in a DC voltage circuit (cathode side of the separation diode 12) smoothed by a voltage divider 22 30.

The output side of the operational amplifier 21 is further fed to the second input side of the comparator 23. Between this input side and a bridge rectifier 11, the minus pole 35 5 84 877 is connected in parallel to the Zener diode 24, the ohmic resistor 25 and a capacitor 26 to the resistor 25 and the capacitor 26 is separated from the diode 27 of a Zener diode 23 of the second input side 24 of the comparator is connected to a peak value rectifier 17 of the screen 5 expenditure side. The output side of the comparator 23 is connected to the base circuit of the control transistor 29 arranged in the circuit of the opto-switch 28. The optical switch 28, which acts as a voltage difference between the mains voltage of the plate 6 and the voltage circuit, controls the power stage 30 in series with the fan motor 5.

The optical indication of the necessary filter change can be controlled in two ways, depending on whether the pressure switch is equipped with a counter-acting auxiliary contact or a co-operating auxiliary contact. If the push switch 15 is operated by an auxiliary auxiliary contact 31, then the switch gap of this auxiliary contact 31 is connected in parallel to the input resistor 16 of the peak rectifier 17. If a push switch is available with a the control interval of the semiconductor switch 33 connected in parallel to the series connection of the notification element 8 and 9.

In order to enable a polarity-independent connection of the elements 8 and 25 9 arranged in the handle 1, the light emitting diode 9 is connected to the DC voltage diagonal of the two-sided period rectifier 34.

The remote control device operates as follows: By adjusting the resistor element 8 arranged in the handle 1, the height of the voltage coming from the series connection of this resistor element 8 and the light emitting diode 9 is changed. At the input resistance 16, this voltage is then always on the input side 18 of the peak rectifier 17 when the first semiconductor switch 19 is closed. As already mentioned, the first semiconductor switch 19 is controlled periodically to open and close by the operational amplifier 21 6 84877.

A periodic series of control pulses of the operational amplifier 21 is provided by pulsing a DC voltage in the form of sine waves of the bridge rectifier 11 5 and a continuous DC voltage prevailing on the cathode side of the isolating diode 12 of the operational amplifier 21 on the second input side of the operational amplifier 21. A corresponding sensitivity can be provided by the voltage divider 22 by the operational amplifier 21. On the output side of the operational amplifier 21, a closing signal always appears to the first semiconductor switch 19 when the sinusoidal voltage on the second control input side is lower than the DC constant voltage on the second control input side. If the sinusoidal voltage rises above the value of the constant DC voltage on the other input side, then a pass-through signal to the first semiconductor switch 19 enters the output side of the operational amplifier 21. The semiconductor switch 19 is thus synchronously controlled to the mains voltage U open and closed.

During the closing of the first semiconductor switch 19, a voltage pulse on the input side 18 of the peak rectifier 17 causes a continuous DC voltage on the output side of the peak rectifier 17, the height of which depends on the height of the voltage pulse. Thus, the DC voltage on the output side of the peak rectifier-25 is proportional to the voltage drop controlled by the resistor element 8.

Since the sinusoidal voltage on the input side of the operational amplifier 21 is lower than the continuous DC voltage at the second end of the operational amplifier 21 for only a short period of time, the first semiconductor switch 19 closes only for a correspondingly short time. During the rest of the sine wave, the first semiconductor switch 19 is passed through and thus short-circuits the series connection of the resistor element 35 8 and the light emitting diode 9 with the auxiliary switch 31 of the push switch. The light emitting diode is then left in the light because a short voltage pulse is not sufficient during the closing time of the first semiconductor switch 19 to bring the light emitting diode 9 into a detectable flash.

If the push-button switch starts to operate at the specified filling level of the filter bag, a short-circuit in the series switch of the resistor element 8 and the light-emitting diode 9 is interrupted by the auxiliary switch 31 acting counterclockwise. The LED 9 thus receives a sufficient current for the flash and thus signals the necessary filter change.

10 Irrespective of the indication or non-indication of the LED 9, power control of the fan motor is possible. As mentioned above, with the open and close control of the first semiconductor switch 19, the voltage pulses 15 produced on the input side 18 of the peak rectifier 17 are converted into a continuous DC voltage with a relative amplitude. This DC voltage proportional to the voltage drop controlled by the resistor element 8 is applied to the other input side of the comparator 23. In this comparator 23, a constant DC voltage, which can be changed by adjusting the height of the resistor element 8, is compared with the embankment voltage on the other input side.

This ramp-like voltage is generated by charging the capacitor 26 with a positive control pulse of the operational amplifier 21. The pre-connected zener diode 24 25 limits the charging of the capacitor 26 to a constant voltage level. When the positive control pulse is lost, the capacitor 26 begins to discharge with an ohmic resistor 25, whereby the discharge circuit is disconnected from the rest of the circuit by a diode 27. When the capacitor 26 is discharged, the voltage on the control input side of the comparator 23 30 decreases. As soon as this voltage falls below the voltage level on the second control input side, the comparator 23 gives a control signal by which the control transistor 29 is passed through and thus the optical switch 28 is activated, which in turn controls the power stage 30 of the fan motor 5.

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If a pushbutton with a co-operating auxiliary contact 32 is used instead of a pushbutton with an auxiliary auxiliary switch 31, then it is necessary to convert the coupling. In this case, in order to short-circuit the series connection formed by the resistor element 8 and the light-emitting diode 59, a second semiconductor switch 33 is connected, which is connected in series with the load gap (collector-emitter gap). The auxiliary contact 32 provided by the push switch short-circuits the control gap (base-emitter gap) of the second semiconductor switch element 10 33 and thus continuously closes the second semiconductor switch 33. Thus, the light emitting diode 9 has a sufficient current resistance for the flash.

Thus, as long as the push switch has not yet started to operate, the forward auxiliary contact 32 is open, the second semiconductor switch 33 is controlled by its base resistor 35 pre-connected to its base circuit through the operational amplifier 21 periodically open and closed. Here, the corresponding short-measured closing phase of the second semiconductor switch 33 is not sufficient to influence the flash of the light emitting diode 9. In this embodiment, the first semiconductor switch 19 is driven in parallel to the second semiconductor switch 33 from the operational amplifier 21 and thus generates the necessary voltage pulses for the peak rectifier 17. Also after the push-button switch is started and thus the second semiconductor switch 33 thus obtained is closed, the first periodic control of its semiconductor switch 19 is maintained so that the power of the fan motor 5 can be further controlled by adjusting the resistance element 8.

The described remote control device thus leaves the handle 1 for power control of the fan motor 5 and the simultaneous notification of the necessary filter change from the handle 1 by means of a two-branch control line 7.

Claims (6)

1. Device for remote control of the fan motor in a vacuum cleaner from the hose handle, on which on the handle (1) an adjustable control element (8) is arranged and operates in functional connection with the fan motor (5) speed control device via a suction hose (2). , diagonal control line (7), wherein the device control element is connected via a rectifier to an input of a comparator, to which the other input is a periodic, ramp-shaped signal of constant size, and the output of which is connected to the speed of the control device. (30) control thread, characterized in that a) the control element is a resistance element (8), which is connected in series with an electrical indicator element (9) also arranged on the handle (1), and this series connection via the control line (7) is connected to the DC output of a control rectifier (il) arranged in the vacuum cleaner housing (3); B) by means of an electronic switch (19,33) intermittently switched on and off by means of an electronic control circuit (21), the series connection of the resistor and indicator element (8,9) as well as one via an input resistor (16) with the positive pole (11) of the rectifier (11) and at its output 25 with the input of the comparator top value rectifier (17) periodically short-circuable; c) the short circuit of the series coupling of the resistor and indicator element (8,9) is frangible by means of a pressure switch (31, 32) which, depending on the degree of filling of the filter pass, enters into function. Device according to claim 1, characterized in that the series connection of the resistor and indicator element (8,9) and the peak value rectifier (17) are connected via a constant current source (15) to the positive pole of the control rectifier (11). 3. Apparatus according to claim 1 or 2, characterized in that the function switch of the pressure switch designed in the counter-auxiliary contact (31) is connected in parallel with the input resistor (16) of the peak value rectifier (17). Parallel coupling is connected to the minute pole of the control rectifier (11) via a periodically switched on and off first semiconductor coupler (19). 4. Apparatus according to claim 1 or 2, characterized in that the pressure switch constructed by the auxiliary contact (32) can be short-circuited by means of this closing contact for the control of a second semiconductor switch (33), which has its load distance of - generally lying with the series connection of the resistor and indicator element (8,9), and that between the input (18) of the peak value rectifier (17) and the minus pole of the rectifier (11) synchronously with the second semiconductor coupler (33) controlled first semiconductor coupler (19) ) is connected with its load distance. Device according to claim 4, characterized in -20, that both semiconductor couplers (19,33) are jointly connected to the control input pk of an operational amplifier (21), one of which is directly connected to one pole (+) The control rectifier (11) designed as a single-phase bridge rectifier (11) and whose other control input (25) via a voltage divider (22) lies to a direct current (12) supplied by the bridge rectifier (11), provided with a smoothing device (13, 14). . Device according to any one or more of the preceding claims, characterized in that the second input of the comparator (23) is connected to the output of the operating amplifier (21) and to this input of the comparator (23) a zener diode (24). ), a resistor (25) and a capacitor (26) are connected in parallel, the resistor (25) and the capacitor (26) being connected adjacent the input of the comparator (23) and separated by a diode (27) from the zener diode (24).