EP0788760A2 - Switch-on device for a vacuum cleaner - Google Patents

Abstract

The vacuum cleaner power-on device (8) includes an electrical load connection (4) and an associated electrical power-on automatic mechanism, which turns on the vacuum cleaner when a device connected to the load connection is turned on. The power-on device is connected to the load connection to operate a device which is not connected to the load connection. The power-on device has a switch element which is operated by the device. When the device is operated the switch element connects the load connection to an electrically simulated load.

Description

The invention relates to a switch-on device for a vacuum cleaner, which has an electrical consumer connection and an electrical circuit associated with this consumer connection, which switches on the vacuum cleaner when a consumer connected to the consumer connection is switched on.

Such a switch-on device is described, for example, in EP 0 455 226 A2. Vacuum cleaners are often used to extract dusts that are created by tools when working on objects, for example when drilling or grinding. These are usually electrically powered tools. The extraction by the vacuum cleaner is only necessary as long as these tools are in operation, that is, the vacuum cleaner and the electrical tool are used in a closely coordinated manner. For this reason, it is known to connect the tool directly to a consumer connection of the vacuum cleaner and to provide a switch-on device itself in the vacuum cleaner which determines that a current flows through the consumer connection, that is to say the tool connected to this consumer connection is operated.

As soon as this is the case, the vacuum cleaner is switched on by the switch-on device. This automatically results in a synchronization of the vacuum cleaner operation and the tool operation.

However, such a combination can only be operated if the tool or more generally the consumer is connected to the electrical consumer connection of the vacuum cleaner connection and draws current from it for commissioning. However, if the consumer is driven by another energy source, such a combined mode of operation of the consumer and the vacuum cleaner can no longer be carried out.

It is an object of the invention to propose a switch-on device in which such a switching on and off of the vacuum cleaner correlated with the operation of the consumer can also take place when the consumer is driven by an external energy source, ie not via the consumer connection of the vacuum cleaner.

This object is achieved according to the invention in a switch-on device of the type described at the outset in that, in order to operate a device which is not connected to the consumer connection, a switching element is provided in the switch-on device connected to the consumer connection which connects the consumer connection to an electrically simulated consumer when this device is operated.

In contrast to known arrangements of this type, it is provided that the switch-on device is connected to the consumer connection and not that Device to be operated synchronously with the vacuum cleaner. This switch-on device connected to the consumer connection is now switched by the externally operated device in such a way that the switch-on device, when the externally driven device is operating, places a simulated consumer on the consumer connection of the vacuum cleaner, so that the electrical circuit associated with the consumer connection of the vacuum cleaner detects a consumption on this consumer connection and accordingly turns on the vacuum cleaner. The switch-on device therefore takes on the role of the consumer connected to the consumer connection in this vacuum cleaner, and the externally driven device in turn actuates the switching element in the switch-on device in order to connect the simulated consumer either to the consumer connection of the vacuum cleaner or to separate it from it.

The device operated externally in this way can of course be designed very differently, in particular this arrangement is favorable for the operation of tools of all kinds. Their drive can take place by means of a wide variety of external energy sources other drives possible, for example pneumatic or hydraulic drives. It is only essential that the switching on of the device actuates the switching element in the switching device in some way. This can be done in all ways familiar to the person skilled in the art, for example by simple means mechanical connections to the device or by measuring physical parameters on the device that change with the operation of the device.

It is particularly advantageous if the electrically simulated consumer is a reactance, which can be implemented in particular by a capacitor. This prevents the simulated consumer from heating up during operation and still ensures that the electrical circuit of the vacuum cleaner recognizes the consumer and switches on the vacuum cleaner.

In a particularly preferred embodiment it is provided that the switch-on device in a pneumatically driven device is switched on in the line of the pneumatic medium and is actuated by the flow of the pneumatic medium.

Furthermore, it can be provided that the switch-on device comprises a closing device for the line of the pneumatic medium, which can be actuated by an electrical monitoring circuit of the vacuum cleaner via the consumer connection and its connection to the switch-on device. It is then possible to switch off the device from the vacuum cleaner by interrupting the flow of the pneumatic medium. This can be advantageous, for example, if a monitoring circuit for the effectiveness of the suction flow is present in the vacuum cleaner. If this suction flow, for example, when the vacuum cleaner filter is dirty is too weak, this monitoring circuit responds and delivers a shutdown signal to the locking device in the switch-on device via the consumer connection, so that the device is switched off for safety reasons because the suction of the vacuum cleaner is no longer effective enough.

In a particularly preferred embodiment it is provided that the switch-on device is detachably fastened as a structural unit to the vacuum cleaner and is provided with a cable and a connecting piece adapted to the consumer connection. It is therefore easily possible to use the vacuum cleaner either directly with an electrical consumer, as is known per se, or with an externally driven device. In the latter case, the switch-on device designed as a structural unit is attached to the vacuum cleaner and connected to the consumer connection via its cable and its connecting piece. The switch-on device itself is then switched by the externally operated device and connects the vacuum cleaner to a simulated consumer in the manner described.

In a particularly preferred embodiment it is provided that the switching element is a reed contact and that this is actuated by a magnet which can be moved depending on the operation or non-operation of the device. This shifting movement could be done mechanically, for example, by a switch that also turns on the device.

In the case of a pneumatically operated device, it is particularly advantageous if the magnet can be displaced by the gas flow driving the device. Thus, when the pneumatically operated device is switched on, the pneumatic element driving the device automatically actuates the switching element in the switching device.

It is expedient if the magnet is a piston which can be displaced in a flow channel of the gas stream against the action of an elastic restoring force.

In a preferred embodiment of the invention it is provided that a supply circuit for the electrical switching elements of the switching device is connected to its connection to the consumer connection, the electrical consumption of which is so low that the electrical circuit of the vacuum cleaner alone does not activate the vacuum cleaner by this consumption becomes. The line connection of the switch-on device to the consumer connection is thus used in this embodiment not only to connect the simulated consumer to the consumer connection, but also to supply the switch-on device with the operating energy from the vacuum cleaner, for example amplifiers and relays can be provided in the switch-on device, which form the switching element operate or, if necessary, a locking device. The electrical consumption of the switching device is included usually very low, and therefore it is possible to make the supply through the consumer connection of the vacuum cleaner without the circuit associated with the vacuum cleaner already switching on the vacuum cleaner due to this low consumption alone. It suffices to provide this circuit with a threshold value detection so that the vacuum cleaner is only switched on when the current flowing through the consumer connection exceeds a certain threshold value. This threshold value is chosen so that it lies above the value that is necessary to supply the switch-on device, but below the value that a consumer usually connected to the consumer connection requires.

Figur 1:

eine schematische Seitenansicht eines Staubsaugers mit einem Verbraucheranschluß und einem aufgesetzten Einschaltgerät ohne daran angeschlossenes extern betriebenes Gerät;

Figur 2:

ein bevorzugtes Ausführungsbeispiel eines Schaltglieds für ein Einschaltgerät mit einem verschiebbaren Magneten zur Schaltung eines Reedkontakts im Längsschnitt längs Linie 2-2 in Figur 3;

Figur 3:

eine Längsschnittansicht längs Linie 3-3 in Figur 2 bei fehlender Durchströmung;

Figur 4:

eine Ansicht ähnlich Figur 3 mit Durchströmung und

Figur 5:

eine schematische Schaltung eines Einschaltgeräts.

The following description of preferred embodiments of the invention serves in conjunction with the drawing for a more detailed explanation. Show it:

Figure 1:

a schematic side view of a vacuum cleaner with a consumer connection and an attached switch-on device without an externally operated device connected thereto;

Figure 2:

a preferred embodiment of a switching element for a starting device with a displaceable magnet for switching a reed contact in longitudinal section along line 2-2 in Figure 3;

Figure 3:

a longitudinal sectional view taken along line 3-3 in Figure 2 with no flow;

Figure 4:

a view similar to Figure 3 with flow and

Figure 5:

a schematic circuit of a switching device.

In Figure 1, a conventional vacuum cleaner 1 is shown schematically with an intake port 2, a large dirt collecting container 3 and with a suction unit placed thereon, which is not specifically shown in the drawing. The suction unit connects the dirt collecting container 3 to the environment via a filter (also not shown), so that a suction flow can be directed through the dirt collecting container 3 and the filter into the environment through the suction nozzle 2. A flexible hose line that can be connected to the intake port 2 can thus suck off dirt particles and dust particles and collect them in the dirt collecting container 3. To this extent, the vacuum cleaner 1 is a conventional vacuum cleaner, as is readily known to the person skilled in the art.

The vacuum cleaner 1 has an electrical consumer connection 4, which preferably has the form of a normal mains socket. At this consumer connection 4, an electrical consumer can be connected, for example an electric drill, an electric grinding machine or the like, which is supplied with the necessary operating energy via the consumer connection 4.

An electrical circuit 5 is arranged in the interior of the vacuum cleaner 1 and determines whether a current flows through the consumer connection 4. If this is the case, this circuit 5 activates the electric motor of the vacuum cleaner 1, so that the vacuum cleaner is thereby put into operation. If there is no such current flow through the consumer connection 4, the vacuum cleaner 1 may be switched off with a time delay. It is thereby possible to operate the vacuum cleaner synchronously with a consumer connected to the consumer connection 4, for example an electrical tool.

In the illustrated embodiment, however, no electrical tool or the like is connected to the consumer connection 4, but rather a switch-on device 8, which is designed as a box-shaped unit, via a connecting cable 6 and a connecting piece 7. This switch-on device 8 is hooked onto the vacuum cleaner 1 by means of a bracket 9 and is thereby detachably held on the latter.

The switch-on device 8 has at one end a connection 10 for a line 21 of a pneumatic one Medium, for example for compressed air. Another connection 11 for a pneumatic medium is arranged on the opposite side of the switch-on device.

Connections 10 and 11 in the interior of the switch-on device 8 each have a blind hole 12 or 13 (FIGS. 2 to 4) which lie so close to one another that they at least partially overlap and thus form a continuous connection between the connections 10 and 11.

A magnetic piston 14 is slidably mounted in a blind hole 12, on which a helical spring 16 which is arranged in the blind hole 12 and is supported on the bottom 15 thereof is supported.

The piston 14 is usually moved by the helical spring 16 into a region of the blind hole 12 which has no connection to the adjacent blind hole 13 (FIGS. 2 and 3). If, however, pneumatic medium is supplied via the connection 10, the piston 14 is displaced by this pneumatic flow and releases the connection to the adjacent blind hole 13 (FIG. 4). In the flowed-through state, the piston 14 is therefore displaced against the action of the helical spring 16, while in the flow-through state it is not displaced.

The piston 14 is designed as a magnet and actuates a reed contact 17 which is arranged along the blind hole 12. Depending on the position of the magnetic piston 14, the reed contact 17 is opened once (FIG. 3) and once closed (FIG. 4).

It is thus possible to determine the presence of a pneumatic current in line 21, into which the switch-on device 8 is switched on via the connections 10 and 11. This line 21 leads, for example, to a pneumatically drivable tool which is put into operation when a pneumatic flow is passed through this line, for example a compressed air flow. Depending on the operation of this tool, this results in switching of the reed contact 17.

An electrical circuit, as shown schematically in FIG. 5, is arranged in the switch-on device 8. This essentially comprises a line 18 connecting the two wires of the connecting cable 6, into which a switch 19 and a capacitor 20 are connected. The switch 19 can be formed directly by the reed contact 17, but it is advantageous if the reed contact 17 in turn actuates an electrical circuit which then actuates an electrically activatable switch 19, so that more robust switches can also be used here.

When the switch 19 is open, the line 18 is interrupted, so that the consumer connection 4 does not "recognize" any consumers, and a current cannot flow. However, if the switch 19 is closed, a current flows from the consumer connection 4 via the capacitor 20. This capacitor 20 forms a reactance, which is recognized as a consumer by the electrical circuit 5 in the vacuum cleaner 1, and this circuit 5 switches the vacuum cleaner 1 in this case on.

The switch 19 is only closed as long as the externally operated device is in operation, so long as, for example, the blind holes 12 and 13 are flowed through by compressed air. When the device is switched off and this compressed air flow is interrupted, the reed contact 17 opens and this leads to the opening of the switch 19. As a result, the vacuum cleaner 1 is switched off via the circuit 5.

In a preferred exemplary embodiment, a closing device 22, for example a solenoid valve, can be provided in the line 21 of the pneumatic medium, which is shown schematically in FIG. This electrically actuated locking device 22 is connected via lines 23 and 24 to the two wires of the connecting cable 6. It is therefore possible for the electrical circuit 5 in the vacuum cleaner 1 to actuate the closing device 22 via the connecting cable 6 and the lines 23 and 24 and optionally to open and close the line 21. Usually is this line opened, but a monitoring circuit in the vacuum cleaner 1 can generate signals for its closure. This monitoring circuit can measure, for example, the size of the suction air flow and thus the effective operation of the vacuum cleaner. If this operation is restricted, for example by clogging of the filter, a signal for activating the closing device 22 is generated, as a result of which the pneumatic flow in the line 21 is interrupted, that is to say the pneumatically operated device is stopped. This then also leads to the vacuum cleaner being switched off, so that the user is informed that there is a malfunction.

Claims (10)

Switch-on device for a vacuum cleaner, which has an electrical consumer connection and an electrical circuit associated with this consumer connection, which switches on the vacuum cleaner when a consumer connected to the consumer connection is switched on, characterized in that in order to operate a device not connected to the consumer connection (4) the switch-on device (8) connected to the consumer connection (4) is provided with a switching element (19) which connects the consumer connection (4) to an electrically simulated consumer (20) during operation of this device. Switch-on device according to Claim 1, characterized in that the electrically simulated consumer (20) is a reactance. Switch-on device according to Claim 2, characterized in that the electrically simulated consumer (20) is a capacitor. Switch-on device according to one of the preceding claims, characterized in that it is switched on in the case of a pneumatically driven device in the line (21) of the pneumatic medium and is actuated by the flow of the pneumatic medium. Switch-on device according to Claim 4, characterized in that it comprises a closing device (22) for the line (21) of the pneumatic medium, which is switched from an electrical monitoring circuit of the vacuum cleaner (1) via the consumer connection (4) and its connection (6) to the Switch-on device (8) can be actuated. Switch-on device according to one of the preceding claims, characterized in that it is detachably attached as a structural unit to the vacuum cleaner (1) and is provided with a cable (6) and a connector (7) adapted to the consumer connection (4). Switch-on device according to one of the preceding claims, characterized in that the switching element is a reed contact (17) and that this is actuated by a magnet (14) which can be moved depending on the operation or non-operation of the device. Switch-on device according to Claim 7, characterized in that the magnet (14) in a pneumatically operated device can be displaced by the gas flow driving the device. Switch-on device according to Claim 8, characterized in that the magnet (14) is a piston which can be displaced in a flow channel (12) of the gas flow against the action of an elastic restoring force. Switch-on device according to one of the preceding claims, characterized in that a supply circuit for the electrical switching elements of the switch-on device (8) is connected to its connection (6) to the consumer connection (4), the electrical consumption of which is so low that the electrical circuit (5) of the vacuum cleaner (1) is not activated by this consumption alone to switch on the vacuum cleaner (1).

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