DE2032476A1 - Vacuum cleaner whose compressor speed automatically adapts to the various work processes - Google Patents

Description

Vacuum cleaner, the compressor speed of which adapts automatically to the various Adjusts work processes The invention relates to a vacuum cleaner whose Compressor speed adapts automatically to different work processes.

To adapt the suction power of a vacuum cleaner to the various Work processes, it is known, on the suction pipe of the vacuum cleaner by means of manual adjustment Provide coverable opening through which more or less Secondary air is pulled so that the suction power at the working nozzle changes accordingly. The suction power N5 ## g of these vacuum cleaners is specified by the compressor, which has approximately the characteristic curve shown in FIG. 1. The compressor motor always takes about full power from the network and runs at an almost constant rate Speed n, as can be seen from Fig. 2. In addition to the high power consumption There is also a considerable amount of noise generated by such vacuum cleaners.

A vacuum cleaner is also known in which a controllable semiconductor element (Triac) connected as an actuator in series with the compressor motor and for the actuator a control circuit is provided (Siemens cylinder vacuum cleaner VS 2803). On the vacuum cleaner an adjustment button is provided for the user, to which a scale is assigned that carries symbols (e.g. carpet, upholstery, curtain) according to which the speed of the compressor motor is adjusted. Through the adjustment knob there is a time shift in the control pulses of the control circuit for the Actuator against the zero crossing of the mains voltage. This makes it possible to use the To change the mean value of the voltage applied to the motor. The suction of this Vacuum cleaner is so over its speed by actuation of Adjustment knob adapted to the respective work process.

The invention has set itself the task of a vacuum cleaner create whose engine speed automatically adapts to the various work processes adapts so that no manual adjustments to the vacuum cleaner are required by the user are.

This object is achieved in that the by the Vacuum cleaner generated constant flow rate per unit of time by means of a control loop is held.

Appropriate developments of the subject matter of the invention are the Refer to subclaims.

The invention is illustrated schematically below with reference to one in the drawing illustrated embodiment explained in more detail. 1 and 2 show the characteristics of the physical parameters of known vacuum cleaners, Fig. 3 shows a principle Formation of the subject matter of the invention, Fig. 4 by the subject matter of the invention changed characteristics of the physical parameters.

In Fig. 3 are only those necessary for understanding the invention Elements of a vacuum cleaner shown, namely its suction tube 1 with a working nozzle 2 and a motor with a compressor connected to a network 3.

The suction power of a vacuum cleaner is N = c. Q ~ hPi Q S flow rate per unit of time, Ap w negative pressure, c = constant.

The limits of the compressor characteristic are either very small Flow rate per unit of time with a large negative pressure 6p or a very small one Negative pressure Op with a large amount of flow per unit of time Q.

Depending on the work process, the most varied of intermediate values can arise result.

The first-mentioned borderline case occurs when it is very poorly air-permeable Objects (e.g. carpets) are processed. In this case the Working nozzle 2 with its fixed cross-section F pressed onto a carpet 4, so that there is a narrow gap 5 between the working nozzle 2 and the bottom 4. The negative pressure becomes very great, as a result of which there is a high flow velocity at the gap 5 v occurs, so that all particles located on the floor 4 into the interior of the The vacuum cleaner. The flow rate Q per unit of time is given by Q = v.

so that N = c can also be written for the suction power. v . F. Ap If the working nozzle 2 is now lifted off the carpet 4, it is not necessary suddenly the negative pressure Ap and becomes almost zero. Since the engine speed n is almost remains constant, this creates a very large flow rate Q per unit of time, i.e. that the flow velocity v at the opening of the working nozzle 2 is also very high becomes large, so that, for example, curtains can no longer be edited because this was torn into the working nozzle 2 by the high flow velocity v will.

The invention makes this behavior of the known vacuum cleaner avoided with constant engine speed. But neither does it need from the user manual adjustment of the vacuum cleaner to the current work process, as required for vacuum cleaners with a motor speed that can be changed by hand is.

The increase in the flow velocity v is controlled by the Compressor motor 3 influencing control circuit 6 prevented.

In the intake manifold 1, a setpoint value for the flow velocity v predetermined by a sensor 7 arranged in the suction pipe 1, which aud the flow velocity v responds, is detected. Since the cross section F of the intake manifold 1 at the point of Sensor 7 is constant, the flow velocity v corresponds to the flow rate Q per unit of time The change resulting from the sensor 7 is transmitted to a control amplifier 8 supplied, which einwiktg on an actuator 9 that influences the compressor motor 3.

Referring to Figs. 3 and 4, the following is the mode of operation of the vacuum cleaner according to the invention explained in more detail.

For example, if the opening of the working nozzle 2 is completely open, then the controller 6 is the speed of the engine because of the high flow velocity v 3 decrease until the specified setpoint for the flow velocity v is reached (a in Fig. 4). As long as the opening of the working nozzle 2 is therefore uncovered is, the motor 3 runs at a relatively low speed n, as is also desired is and there is therefore only a low level of noise. The power consumption NN the vacuum cleaner is also reduced accordingly.

Is now used on objects that are difficult to process (for example Carpet), then the opening of the working nozzle 2 is through the carpet 4 partially covered. As a result, the flow resistance becomes larger, so that the flow rate Q drops per unit of time at the current speed n of the motor 3.

This drop, which is equivalent to a decrease the flow velocity v is detected by the sensor 7 and via the amplifier 8, the actuator 9 is influenced in such a way that this the speed n of the engine 3 is increased to such an extent that the flow velocity v rises again to its nominal value (b in Fig. 4).

When relieving the vacuum cleaner (for example again transition from carpet processing for curtain processing) is the flow velocity v suddenly again much larger than the specified target value.

The increased flow velocity v is detected by the sensor 7 and the speed of the motor 3 is reduced until the flow rate v corresponds to the specified target value.

A heated NTC resistor or a heated Metal wire (platinum) can be used. The air flow passing this sensor cools the sensor more or less according to its flow velocity sharply, so that a corresponding change in resistance occurs. The change in resistance is a function of the flow velocity v and with a constant cross-section F of the suction pipe 1 is also a function of the flow rate Q per unit of time.

A thyristor or triac can be used as the actuator 9.

Even with poorly air-permeable objects, there will always be a finite flow rate Q per unit of time must be present (small flow velocity v).

The arrangement is expediently dimensioned in such a way that the control loop 6 is not fully open when this condition occurs (to increase the Speed of the motor 3). Only when the flow rate falls below this finite amount Q per unit of time, the control circuit 6 is fully opened, this being a sign of this is used to ensure that nothing is conveyed by the vacuum cleaner (for example by a full dust bag in the vacuum cleaner). From this state of the control circuit 6, a signal can be derived through which, for example, a Signal lamp lights up or the motor 3 is also switched off. If the engine is to be switched off, a timer is expediently provided, by which a delayed shutdown of the engine takes place, so that very short Openings of the control circuit 6 do not cause the motor 3 to be switched off.

Since the flow rate Q per unit of time is now kept constant, the suction power N is a function of the negative pressure Ap.

The advantages achieved with the invention are in particular: that, for example, carpets and curtains can be processed equally well, without having to preselect the respective work process on the device by hand. aside from that shows the course of the function n = f (~ p) that the vacuum cleaner according to the invention is a has minor noise nuisance, which is coupled with the speed. About that In addition, it can be seen (Fig. 4) that because of NN = f (Ap) also the one recorded from the network Performance with the required suction power of the device decreases significantly, which an economical operation results.

Claims

Claims (2)

Vacuum cleaner, the compressor speed of which adapts automatically to the various Adjusts work processes, characterized in that the generated by the vacuum cleaner The flow rate per unit of time is kept constant by means of a control circuit (6). 2. Vacuum cleaner according to claim 1, characterized in that in the air stream of the vacuum cleaner a sensor (7) that responds to the flow velocity (v) is arranged, which acts on an electronic actuator (9) which the speed of the compressor motor (3) adjusted so that even with changes of the negative pressure ~ p) the flow velocity (v) in the suction pipe (1) remains constant.