DE4210061A1 - Vacuum cleaner with cleaning motor and an optionally connected power tool - Google Patents

Abstract

A description is given of a wet-dry cleaner (37) with an electric tool (1) connected to it, vacuuming of the area to be cleaned being carried out by means of the wet-dry cleaner and there being provided at the same time an automatic mode of the wet-dry cleaner, in particular whenever excessive moistness occurs in the connection region of the electric tool. The object of the present invention is to provide a satisfactory dedusting mode of the wet-dry cleaner in combination with an electric tool connected to it and the vacuuming region of the latter. For this purpose, it is proposed that the soiling of the filter is measured by means of a flow sensor (22) and at the same time the flow sensor is arranged in an air duct underneath the turbine, an upwardly acting air stream being generated, which constantly surrounds the flow sensor and the filter material at the same time being measured for its degree of moistness by means of a moistness sensor (40), the degree of moistness being used as a control signal for switching the electromechanically operated dedusting. <IMAGE>

Description

The invention relates to a vacuum cleaner with a cleaning motor and with an optionally connected power tool with suction about the filter arrangement of the vacuum cleaner according to the preamble of Claim 1.

In a known version of a vacuum cleaner is already one Differential pressure cell provided, however, in their arrangement below the turbine is not working properly, especially if it is too big Moisture occurs in the filter elements, which causes the Measuring element of the differential pressure can in the flow area below the Turbine could easily steam up.

The object of the present application is to cover an area of the invention in this way create that the disadvantages mentioned above are avoided and that a cleaning taking into account the moisture values in the Airflow takes place.

The disadvantage of the previously known differential pressure cans is that they either are relatively expensive or in the case of less expensive differential pressure cans not easily possible to carry out the readjustment exactly. After such differential pressure cans work partly mechanically it is very difficult to apply moisture in a small pressure range of 1 up to max. 5 mbar a reproducible setting of the differential pressure can to guarantee.  

This is where the advantages of flow meters come in, which are easy reproducible measured values. The advantage of flow sensors is remaining that temperature compensation is integrated, d. H. the Flow measurement works relatively independently of the Ambient temperature. There is a temperature compensation circuit for this attached to the measuring element itself, so that the measurements are independent to be able to run from the ambient temperature.

The object of the invention is achieved in that the Filter pollution influencing air volume flow in connection with a flow sensor measured in the flow area below the turbine becomes. Here, the flow sensor is in an air duct below the Turbine arranged, the turbine via in a manner known per se an inlet opening the air flow in the area of the flow sensor sweeps away.

In connection with the measurement via a flow sensor is a Cleaning motor available and therefore an electromechanical Cleaning the filter.

If too much moisture is measured on the filter, there is a risk that the wet filter was destroyed by the electromechanical cleaning. For this reason, a humidity sensor 40 is provided, which measures the relative air humidity at the filter, and if the degree of humidity is too high, the cleaning is put out of operation.

Such a cut-off humidity would, for. B. at a value between 90 and given 100% relative humidity.

Show it:

Fig. 1 is a schematic representation of vacuum cleaner with attached power tool,

Fig. 2 shows the arrangement of a flow sensor,

Fig. 3 is a flow-diagram of the output voltage,

Fig. 4 is a control loop representation for automatic suction power adjustment.

With regard to the drawings, it is stated that a dirt vacuum cleaner according to the invention with a connected tool 1 is shown schematically in FIG . This tool is arranged via a suction hose 2 at the connection opening 3 of the vacuum cleaner. The vacuum cleaner carries a suction head 4 , in which a turbine 5 is installed. The turbine 5 is driven by an electric motor, not shown. In this case, an insertion filter 7 is installed in the dirt container 6 , which is designed, for example, as a dirt-receiving bag (filter bag). Furthermore, a filter element 8 is arranged in the dirt container with an internal float 9 (see FIG. 2).

A control panel 10 is also arranged on the suction head 4 , with which the various functions of the vacuum cleaner can be controlled.

Fig. 2 shows further details of the vacuum cleaner according to Fig. 1, where it can be seen that a float 9 is guided vertically adjustable in a support basket 11 . The support basket 11 of the filter element 8 is arranged in the filter element 8 .

The filter element is held in a mounting plate 12 for the turbine.

The turbine 5 has outlet openings 13 and is embedded in upper and lower seals 14 , the upper seal 14 being arranged in the region of a clamping plate 15 , while the lower seal 14 is provided in the region of the receiving plate 12 .

The receiving plate 12 has an upper opening 16 which lies on the clean air side of the filter element 8 .

An air duct 17 is arranged below the opening 16 , which essentially consists of a tube piece 18 which is reinforced by an annular flange 19 . An annular chamber 20 is hereby formed within the annular flange 19 .

The opening 16 is closed by a wire mesh 21 . It is now important that a flow sensor 22 projects radially through the wall of the pipe section 18 into the air duct 17 and is acted upon by the volume flow coming from below in the direction of the arrow 23 .

The cable feed to the flow sensor 22 takes place through the annular chamber 20 .

The clean air is thus guided via the sensor 22 in the direction of arrow 23 , sucked into the underside of the turbine 5 and introduced through the outlet openings 13 via an annular chamber 24 in the direction of the arrow 25 into a sound absorbing arrangement which is in the hood (suction head 4 ) according to FIG Vacuum cleaner is arranged.

The sound-insulated air in this way is pressed out through the blow-out openings 26 ( FIG. 1).

In Fig. 3, the volume stream is recorded on the abscissa, while the output voltage of the flow sensor 22 is recorded on the ordinate.

It is a non-linear curve, it is important that that with smaller volume flows there is a higher resolution (Delta UA) results.  

The curve is provided with the reference number 27 . With a clean, unused device to which an unused power tool is connected, e.g. B. reaches an operating point 28 , which corresponds for example to a volume flow of 80 cbm / h and an output voltage of approximately 3.7 V at the flow sensor 22 .

With increasing exposure to the filter or with increasing clogging of the power tool, the working point 28 moves downward in the direction of the arrow 29 until a minimal working point 30 is reached. This minimum working point is specified by the trade association regulations and corresponds to a minimum volume flow of z. B. 26 cbm / h.

The volume flow value of 26 m ³ / h results, for example, when a power tool with a suction nozzle cross section of approximately 360 mm ² at a z. At present the required minimum air speed of 20 m / s is operated.

On the curve 27 there are further working points 31 , 32 , 33 , for example the working point 31 corresponding to a suction hose diameter of 36 mm and a nominal voltage of 200 V, while the working point 32 corresponds to a suction hose diameter of 36 mm at a nominal voltage of 230 V and the Working point 33 corresponds to a suction hose diameter of 36 mm and an overvoltage of 240 V.

There are further working points 34, 35 on the curve 27 , for example the working point 34 corresponding to a suction hose diameter of 32 mm at a nominal voltage of 230 V and the working point 35 corresponding to a suction hose diameter 27 mm at a nominal voltage of 230 V.

With a fixed and given suction hose diameter, a change in the nominal voltage in the drive motor of the turbine therefore only results in a shift in the direction of arrow 29 or in the opposite direction on curve 27 for the operating point in question.

A selector switch is now attached to the front of the device certain volume flows are set in several stages can.

At operating point 34, for example, a volume flow of 70 cbm / h results for a suction hose of 32 mm diameter and a nominal voltage of 230 V on the drive motor of the turbine. An output voltage value of z. B. 3.6 V on the flow sensor.

With the selector switch, the threshold value with respect to the lower, minimally permitted working point 30 can now be set continuously.

According to FIG. 1, only one unit is always considered, consisting of a vacuum cleaner 37 , a suction hose 2 and an associated tool 1 .

For the power tool 1 used, a minimally permitted amount of air (volume flow) is now prescribed by the manufacturer, which in turn is determined by the connection diameter of this tool to the suction hose 2 .

Such a limit is reached when e.g. B. contain no more than 2 mg of dust per cubic meter of air. This minimum permissible volume flow assigned to the power tool is now set at the selector switch 38 of the vacuum cleaner 37 . When this value is reached, a warning signal is first generated, which can consist of an optical signal and / or an acoustic signal.

Additionally or alternatively, there is also the possibility of reaching this minimum threshold value the tool and optionally the vacuum motor switch off.  

This has the advantage that with all conventional power tools on the market whose minimum permissible volume flow is known, this volume flow can be adjusted continuously or in several stages on the control panel of the vacuum cleaner 37 and the minimum operating point 30 can thus always be shifted on the curve 27 , is observed.

These working points are designated in Fig. 3 with the points 30 a, 30 b, 30 c, etc.

The infinitely variable setting is made using a potentiometer or in the case of several stages by a step switch with assigned Fixed resistors on the switch panel, creating a threshold of a Comparator is set, which is the output voltage of the Flow sensor with this set threshold value compares and at If the threshold value is undershot, an output signal is generated.

In a further development of the present invention, it is provided that the upper operating points 31 , 32 . . . 35 can be infinitely adjusted, namely by speed control of the drive motor for the turbine. This has the advantage that you can first drive in the initial operation with throttled power, which means great energy savings, because the working point selected is z. B. 10% above the switch-off point 30 as a safety reserve.

If these devices become full with the progressive operation of the vacuum cleaner and the power tool and the volume flow thus drops near the lower working point 30 , the speed of the turbine can be increased until the safety reserve of 10% above the lower working point 30 is reached again.

So you continue to work with relatively little energy. This means that the operator has a manually operated one  Suction power adjustment available to reduce energy costs.

In a further equipment variant, the speed can be electronically and automatically linked to both the actual volume flow value and the set value (setpoint), which results in a fully automatic suction power adjustment that is independent of the operator (see Fig. 4).

With increasing contamination of the vacuum cleaner and the power tool, the speed of the turbine is increased continuously until the maximum permissible speed has been reached. If the set minimum operating point 30 is now reached with the suction motor controlled to a maximum, an acoustic and / or optical warning signal is emitted and after a certain delay the power tool is then switched off, provided this is approved by the professional association.

Then after a further delay time the Vacuum cleaner itself.

This automatic suction power adjustment is therefore about a very energy-saving operation, which the service life of the Turbine of the Vacuum cleaner increases and results in a significant reduction in noise.

Another method claim would be moisture measurement in the Filter area to prevent unauthorized cleaning of a damp filter avoid that could be damaged and a third A process claim would be a level measurement in the dirt container.

The procedures described in the Expose dated October 22, 1991, are to be summarized in procedural claims. Here is z. B. provided that with the switching of the vacuum cleaner in the standby position at the same time Ready for electromechanical cleaning  is switched on by pressing its own, on Control panel attached, cleaning button is activated and the Cleaning expires.

There are other switch positions, "manual", and "auto", with in cleaning is activated in both positions and by pressing the cleaning button starts and runs.

Drawing legend

1 tool
2 suction hose
3 connection opening
4 suction head
5 turbine
6 dirt containers
7 insert filters
8 filter element
9 swimmers
10 control panel
11 support basket
12 mounting plate
13 outlet opening
14 sealing
15 clamping plate
16 opening
17 Venturi nozzle
18 blank
19 ring flange
20 ring chamber
21 wire mesh
22 flow sensor
23 direction of arrow
24 ring chamber
25 direction of arrow
26 outlet opening
27 curve
28 working point
29 arrow direction
30 working point
31 operating point
32 operating point
33 operating point
33 operating point
34 operating point
35 working point
36 operating point
37 vacuum cleaner
38 main switch
39 cleaning button
40 humidity sensor
41 Speed control knob

Claims (13)

1.Dirt cleaner with cleaning motor and with an optionally connected power tool with suction via the filter arrangement of the vacuum cleaner via a suction hose, whereby the power tool is switched on and automatically switched off or the power tool continues to run and an acoustic and / or visual signal takes place instead of the switch-off as soon as the filter contamination exceeds a certain guide value, characterized in that the filter contamination is measured via a flow (flow) sensor ( 22 ), the flow sensor ( 22 ) in connection with thermocouples and an integrated heating coil in an air duct below the turbine ( 5 ) is arranged and the turbine ( 5 ) sucks in the suction air through the filter arrangement and the air duct below the turbine, the turbine having outlet openings ( 13 ) for the air outlet, from which the suction air flows out, in the coaxially arranged annular chamber ( 24 ) is and exits the vacuum cleaner via two outlet openings, the main switch ( 38 ) of the vacuum cleaner being switched to the "MAN" or "AUTO" position. 2. Vacuum cleaner according to claim 1, characterized characterized in that at position "MAN" and "AUTO" in Connection with a button "cleaning" a small green LED lights up and the cleaning cycle runs at the same time. 3. Vacuum cleaner according to claims 1 and 2, characterized characterized that starting from the lighting up of the green LED the vacuum motor is switched off, and a time of 4-5 seconds elapses before a cleaning motor starts, the Cleaning motor if the current flow is too high, caused by too stiff rotation of the cleaning mechanism or even blocking it is stopped by electronic current monitoring, while the green LED changes to red. 4. Vacuum cleaner according to claim 1 and claim 3, characterized characterized in that when switching back from position "MAN" the main switch after the "Stop" position starts the cleaning cycle tarnish. 5. Vacuum cleaner according to claim 1, characterized in that in the "Auto" position the automatic switch-on with tool locking (alternatively also without) is in operation, wherein - as soon as an electric tool (e.g. orbital sander) is switched on and the main switch ( 38 ) is moved from position "zero" to "auto", the tool starts very briefly (max. 10 msec) and then stops again, then a large, red LED (tool lock) flashes, the lock being released when the tool is switched off and the main switch is set to "zero". 6. Vacuum cleaner according to claim 1, characterized in that a moisture sensor is provided which, when the air humidity is too high, caused by an excessive moisture loading of the main filter, switches off the cleaning with the cleaning motor, with the cleaning on the display panel or Control panel ( 10 ) the same small, red LED - as with overcurrent in connection with an overload of the mechanics of the cleaning device lights up. 7. Vacuum cleaner according to claim 1, characterized in that in the "MAN" position of the main switch, the vacuum cleaner starts immediately in normal operation and that when the cleaning button ( 39 ) is actuated, the motor or turbine ( 5 ) of the vacuum cleaner is stopped, the so-called Cleaning starts and the turbine of the vacuum cleaner is switched on again after cleaning is complete. 8. Vacuum cleaner according to claim 1, characterized in that when the main switch is actuated from "zero" to "AUTO", the tool lock (flashing a large, red LED) is in operation, the tool being brought into the switched-off position for automatic operation and the main switch ( 38 ) must be switched from the "AUTO" position to the "ZERO" position and back to the "AUTO" position. 9. vacuum cleaner according to claim 1 and claim 5 and claim 7, characterized in that at a position of Main switch from "zero" to "auto" the tool into operation is switched, after the start of the tool the vacuum motor begins to run with a delay, with a time shift of the two starting currents ensures that the network side Power fuse cannot trigger even under heavy loads and dust extraction of the generated dust is guaranteed. 10. Vacuum cleaner according to claim 8, characterized in that the vacuum motor of the vacuum cleaner continues to run for a short time after the end of the operating time of the power tool and after the dirt suction there, whereby the suction hose ( 2 ) is subjected to cleaning and the vacuum cleaner switches off automatically after a short time . 11. Vacuum cleaner according to claim 8, characterized in that when the cleaning is actuated while working with the tool ( 1 ) via the cleaning button ( 39 ), the tool lock with the tool ( 1 ) being switched off first comes into effect, as a result of which the tool ( 1 ) is activated and the vacuum motor of the vacuum cleaner switches off with a time delay. 12. Vacuum cleaner according to one of claims 1-11, characterized in that the suction power of the Turbine is automatically adjusted to an adjustable minimum Volume flow value (setpoint), so that the air flow of the turbine by one Amount of z. B. 100 is above the minimum volume flow. 13. Vacuum cleaner according to claim 12, characterized characterized in that after reaching the maximum permissible Load speed of the turbine and after falling below the minimum volume a warning signal is generated.