WO2008064759A1 - High pressure cleaning device, and a method for varying the motor power thereof - Google Patents

Abstract

The invention relates to a high pressure cleaning device with an electric motor and a pump driven by said electric motor for the delivery of pressurized cleaning fluid, wherein the electric motor contains a coil mechanism with at least one coil for the production of a magnetic field, and the electric motor is connected to a control unit for controlling the motor power. In order to develop the high pressure cleaning device further in such a way that the motor power can be easily constructively altered also for motors of greater power without creating network reactions that are not tolerable, it is proposed according to the present invention that the number of the effective turns of the coil mechanism for the creation of a magnetic field can be changed by the control mechanism. Further, a method is proposed for changing the power of the electric motor for a high pressure cleaning device of this kind.

Description

 High-pressure cleaning device and method for changing its engine power

The invention relates to a high-pressure cleaning device having an electric motor and a driven by the electric motor pump for discharging pressurized cleaning liquid, wherein the electric motor comprises a coil means having at least one coil for generating a magnetic field and the electric motor is connected to a control device for controlling the engine power.

Moreover, the invention relates to a method for changing the power of the electric motor of such a high-pressure cleaner.

In order to be able to change the pressure of the cleaning fluid dispensed by the high-pressure cleaning device or also the amount of detergent dispensed per unit of time, it is known to vary the electric power of the electric motor. For example, in the European patent application EP 1 384 529 A2 it is proposed to switch a diode into the electrical supply line of the electric motor to reduce its power, so that the motor power can be halved. Alternatively, the use of a phase control is proposed, which can be set by the user using a potentiometer to a desired engine performance.

The motor power can be changed with the help of a phase control. However, the use of phase control in higher power electric motors, for example, more than 1.4 kW, often to intolerable repercussions on the supply network to which the electric motor is connected because form harmonic currents.

Object of the present invention is to develop a high-pressure cleaning device of the type mentioned in such a way that the engine power can be changed in a structurally simple way even with electric motors higher performance without forming no longer tolerable network perturbations.

This object is achieved in a high-pressure cleaning device of the generic type according to the invention that the number of effectively effective for forming a magnetic field turns of the coil means by means of the control device is variable.

In the invention, the idea flows in that the motor power can be changed by changing the inductance of the coil means. The inductance is dependent on the number of turns that effectively form the magnetic field of the electric motor. Increasing the number of effectively effective turns results in an increase in the inductance of the coil means, and this in turn causes a reduction in motor power. If the high-pressure cleaning device is to be operated at high power, a smaller number of windings effectively forming the magnetic field is brought into use by means of the control device than at lower power.

It can be provided that the number of effectively effective for forming a magnetic field turns by means of the control device is continuously variable to the performance of the high-pressure cleaning device continuously to be able to adjust. In a structurally particularly simple and inexpensive to produce embodiment, however, it is provided that optionally a first or a second number of turns of the coil device is effectively effective for forming a magnetic field. In such a configuration, the effectively effective number of turns is thus switchable between a first and a second value. It can be provided, for example, that optionally a maximum number of effectively effective turns or only half of the maximum number is used.

To change the effective number of windings of the coil means is preferably a switching device of the control device is used. The switching device can be manually operated, for example.

It is particularly advantageous if the switching device is electrically controllable. As a result, a manual operation of the switching device can be omitted.

The switching device comprises in a preferred embodiment of the invention at least one relay. It is advantageous if only a single relay is used, with the aid of which the number of effectively effective turns of the coil device is variable. The relay can be acted upon by a control circuit of the control device with a control signal.

The control device preferably has a control circuit in the form of a microcontroller.

The coil device may for example comprise a coil, which is designed as a stator winding of the electric motor. This gives the possibility to the Number of effective to form the magnetic field effective turns of the stator winding to change by means of the control device.

The change in the number of effectively effective turns can be effected in a particularly simple manner in that the coil device comprises two coils which each form a stator winding of the electric motor. This gives the possibility of supplying either a first and / or a second stator winding with electricity. If only the first stator winding is used, then a motor power corresponding to the first stator winding can be achieved. If only the second stator winding is used, a motor power corresponding to the second stator winding can be provided by the electric motor. Of course, it can also be provided that in order to achieve a certain engine power both stator windings are supplied with power simultaneously to achieve a combined use of both stator windings corresponding motor power.

It can be provided that the two stator windings have the same number of turns. This gives the possibility of doubling the number of turns effective to form a magnetic field by using both stator windings compared to the number of turns effective to use only one of the two stator windings to form a magnetic field.

It can also be provided that the two stator windings have different numbers of turns. For example, the first stator winding can only have half the number of turns as the second stator winding.

In a particularly preferred embodiment of the high-pressure cleaning device according to the invention, the two stator windings are optionally parallel Allel or in series with each other switchable. If the two stator windings are connected in series with each other, the number of turns effectively forming the magnetic field of the electric motor results from the sum of the number of turns of the two stator windings. If, on the other hand, the two stator windings are connected in parallel, the number of effectively effective turns is smaller. If the two stator windings have the same number of turns, when the stator windings are connected in parallel, only half of the windings for forming a magnetic field are effectively effective compared with the number of turns effective for a series connection of the stator windings. The consequence of the parallel connection is that ultimately only the wire cross-section of the coil device of the electric motor increases, without thereby increasing the number of turns that effectively form the magnetic field. By selectively switching in parallel or in series of the two stator windings can thus be selected between a large number of effective effective turns at a certain wire cross-section and a smaller number of effectively effective turns with increased wire cross-section, and in this way the power of the electric motor between a first power value and a second power value are switched.

It is particularly advantageous if the two stator windings are configured identically. This allows a uniform current load of the stator windings, wherein the current load can be adjusted to the maximum allowable heat generation of the engine. If the two stator windings are connected in parallel with one another, the maximum motor power is achieved; in the case of a series connection of the two stator windings, a reduced motor power, for example 70% of the maximum power, is provided by the electric motor. The stator windings connected in parallel provide a smaller number of windings in order to form the magnetic field. Pelt as large wire cross-section ready as this is the case with a series connection of the identical stator windings.

It is particularly advantageous if the control device comprises a phase control. This makes it possible to change the motor power on the one hand by changing the number of effective for forming a magnetic field winding number of the coil means, on the other hand, the engine power can be changed by means of the phase control. As mentioned above, the use of a phase control at high engine power, especially at engine power of more than 1.4 kW, in many cases no longer tolerable network perturbations result. It is therefore advantageous if, by means of the phase-angle control, the power of the electric motor is then reduced if a first power reduction has already been achieved by changing the number of windings of the coil device effectively effective for forming a magnetic field.

It is favorable if the engine power can be changed continuously by means of the phase control or can be switched over between at least two power values. For example, it can be provided that the motor power can be reduced by 30% to 60% by means of the phase control. For example, in combination with changing the motor power by changing the number of turns of the coil means effectively effective to form a magnetic field, the electric motor may be selectively operated at 100%, 50% or 30% of its maximum power. The reduction of the power from 100% to 50% can be achieved by changing the number of effective turns in connection with the use of the small firing angle phase control. The additional power reduction to 30% can be achieved by increasing the firing angle of the phase control. In the reduced power range is the use of the phase control unobjectionable with regard to possible repercussions on the electrical supply network, since at lower power levels can not be expected with a massive formation of harmonic currents.

The phase control usually comprises a TRIAC. After a zero crossing of the AC voltage provided by the supply network, the TRIAC does not conduct the current until it receives an ignition pulse from the control device at a specific ignition angle. From this point on, the electric motor is supplied with energy until the next zero crossing of the alternating voltage. The later the TRIAC is detonated, d. H. the larger the firing angle, the lower the power averaged over one period of the AC voltage.

It is particularly advantageous if the TRIAC of the phase control is assigned a test circuit for detecting the switching state of the TRIAC. By means of the test circuit can be determined in a structurally simple manner, whether after the ignition of the TRIAC there is a current flow or not. If, for example, the electric motor is disconnected from the supply network by means of a switch connected in series with the TRIAC, then the TRIAC ignites when it is charged with an ignition pulse, but then no current flows through the TRIAC; in particular, the TRIAC does not flow in it open position at least required holding current. If, on the other hand, the switch is closed, a current flows after the ignition of the TRIAC and the TRIAC remains in its open position until the next zero crossing. The switching state of the TRIAC can be detected by the test circuit based on the current flow. The behavior of the TRIAC after being subjected to an ignition pulse thus reflects the switching state of the switch downstream of the TRIAC. Thus, constructive integration With the help of the test circuit information can be obtained about the state of the switch.

The pump of the high-pressure cleaning device usually has a suction inlet for sucking in cleaning liquid and a pressure outlet for dispensing pressurized cleaning liquid. At the pressure outlet, a pressure line can be connected. It is advantageous if the engine power can be controlled by opening and closing a closing valve connected in the pressure line. If the closing valve is closed by the user when the engine is running, a pressure spike is formed in the pressure line, and the pressure in the pressure line then decreases very briefly when the closing valve is opened, in order subsequently to assume a value given by the engine power. The strong pressure increase when closing the closing valve and the strong pressure drop when opening the closing valve can be used to control the engine performance. For this purpose, for example by means of a pressure sensor, a pressure signal corresponding to the pressure rise or the pressure drop can be generated.

Of particular advantage with regard to the simplest possible handling of the high-pressure cleaning device, it is when the engine power in dependence on the period between the closing and the opening of the closing valve is controllable. It can be provided, for example, that by closing the closing valve, a first control signal and subsequent opening of the closing valve, a second control signal is provided and that the motor power is controlled in dependence on the duration of the time interval between the two control signals. If the time interval between the first and the second control signal is shorter than a predetermined period of time, for example shorter than 0.5 to 1.5 seconds, the engine power is automatically changed by means of the control device. Preferably, the engine power is changed in a predetermined order. This gives the option of operating the high-pressure cleaner with either maximum engine power or reduced engine power. In particular, it can be provided that the user can choose between several predetermined engine performances by repeatedly briefly closing the closing valve, preferably between at least three engine powers, for example between 100%, 50% and 30% of the maximum power of the electric motor. If, starting from the maximum engine power, the closing valve is briefly closed once and then re-opened, the engine power drops to a first reduced power value, for example to 50% of the maximum power. If the closing valve is subsequently closed again for a short time and then opened again, the engine power drops to a second reduced power value, for example 30%. If the closing valve is briefly closed again for a short time and then opened again, the engine output rises again to the maximum value. However, if the closing valve closed by the user for a long time, for example, for more than 0.5 to 1.5 seconds, then the subsequent reopening of the closing valve does not result in a change in engine performance, but the engine is then with his before the grinding of the Closing valve present engine power operated.

As mentioned above, the invention also relates to a method for changing the power of the electric motor of a high-pressure cleaning device. In order to be able to change the engine power in a structurally simple manner, without fear of intolerable repercussions on the supply network, the invention provides that, in order to reduce the engine power, the number of windings of the coil device effectively effective for forming a magnetic field increases. As already explained, can through increasing the number of effectively effective turns increases the inductance of the coil means of the electric motor and reduces its performance.

It is favorable if, in order to reduce the motor power, two stator windings of the electric motor are connected in series. Compared to a parallel connection of the two stator windings, the number of effective windings for forming the magnetic field, i. E. H. increases the number of turns that determine the inductance of the coil means, and at the same time the effective effective wire cross-section of the coil means is halved in a series connection of the stator windings compared with a parallel circuit.

In a preferred embodiment of the method according to the invention, the motor power is additionally reduced by means of a phase control.

It is advantageous if, starting from a maximum motor power, in which two stator windings are connected in parallel, for the first power reduction, the stator windings connected in series and additionally reduces the power output by means of the phase control for further power reduction. The phase control is thus used to reduce the engine power when the two stator windings of the motor are connected in series and therefore the motor can no longer achieve its achievable in parallel connection of the stator windings maximum power. Unacceptable system perturbations of the phase control can be avoided in a simple manner. It can also be provided that, starting from a maximum motor power, in which two stator windings are connected in parallel and no phase angle is made to achieve an average power stage, the stator windings in series and additionally operates the phase control with a small ignition angle, and to achieve a low power stage leaves the stator windings in series connection and the phase control operates with a larger ignition angle.

The following description of a preferred embodiment of the invention serves in conjunction with the drawings for further explanation.

The sole FIGURE of the drawing shows schematically a high-pressure cleaning device according to the invention, to whose pressure line a closable spray nozzle is connected.

In the drawing, a generally designated by the reference numeral 10 high-pressure cleaning device is shown with a pump 12 which is driven by an electric motor 13. The electric motor 13 comprises a coil device with three coils, namely with an armature winding 15 and with a first stator winding 16 and a second stator winding 17. The three windings are arranged in a conventional manner within a housing of the electric motor 13. Only to achieve a better overview, the two stator windings 16 and 17 were shown in the drawing offset from the electric motor 13.

The pump 12 has a suction inlet 19 for supplying cleaning liquid, preferably water, which is pressurized by the pump and discharged via a pressure outlet 20 and a pressure line 21 adjoining the pressure outlet 20. At the free end of the pressure line 21st is a closing valve in the form of a known per se and therefore only schematically shown in the drawing spray gun 22 is connected. The spray gun 22 can be selectively opened and closed by the user in the usual way by means of an actuating lever, not shown in the drawing.

To the pressure line 21, a signal generator 24 is connected, which provides a control signal in response to the pressure prevailing in the pressure line 21 pressure.

The high-pressure cleaning device 10 furthermore has a control device 27, to which the electric motor 13 is connected and which has a first power supply connection 29 and a second power supply connection 30. About the two power supply terminals 29 and 30, the high-pressure cleaning device 10 can be connected to the power supply to a power grid.

The control device 27 comprises a switching device in the form of a relay 32 with a first relay switching element 33 and a second relay switching element 34. The two relay switching elements 33 and 34 are switched simultaneously and can each optionally assume a first switching position or a second switching position.

For controlling the relay 32, the control device 27 has a control circuit 36 which is connected via a control line 37 to the relay 32. In addition, the control circuit 36 is connected to a phase control 39, which comprises a control member 40 and a TRIAC 41. In addition, the control circuit 36 is in electrical connection with a test circuit 43 and with a no-pass detection circuit 45. The TRIAC 41 is connected in a connecting line 47, via which the two power supply terminals 29 and 30 are connected to each other. In series with the TRIAC 41, an ohmic resistor 48 is connected in the connecting line 47. To the control terminal 50 of the TRIAC 41, the control member 40 of the phase control 39 is connected. The control member 40 is supplied by the control circuit 36 with a control signal for igniting the TRIAC 41st

The test circuit 43 is connected to the connection line 47 between the TRIAC 41 and the ohmic resistor 48. It detects a current flow in the connecting line 47 and acts on the control circuit 36 with a corresponding sensor signal.

The zero crossing detection circuit 45 is connected between the ohmic resistor 48 and the second power supply terminal 30 to the connection line 47. It detects the zero crossings of the alternating voltage applied to the connecting line 47 and provides the control circuit 36 with a corresponding control signal.

A first supply line 53 branches off from the connecting line 47 between the TRIAC 41 and the ohmic resistor 48, and a second supply line 54 branches off from the connecting line 47 between the ohmic resistor 48 and the second power supply connection 30. In the two supply lines 53, 54, a pressure switch 56 is connected, which can be acted upon via a signal line 57 with an electrical signal of the signal generator 24 for pressure-dependent production and disconnection of the connection between the power supply terminals 29 and 30 and the electric motor 13. Rather than by means of an electric Signal over A Signalieitung the pressure switch 56 to operate, can also be provided that a pressure switch is used, which is actuated mechanically by means of a switching plunger.

The electric motor 13 can thus be switched on and off by means of the pressure switch 56 as a function of the pressure prevailing in the pressure line 21.

The first supply line 53 leads from the pressure switch 56 via the relay 32 to the two stator windings 16 and 17, and the second supply line 54 leads from the pressure switch 56 to the armature winding 15 of the electric motor 13. The two stator windings 16, 17 can by means of the relay 32 optionally parallel to each other and be connected in series with each other. If the two relay switching elements 33 and 34 their first switching position shown in the drawing, so the two stator windings 16, 17 are connected in parallel, whereas the two stator windings 16, 17 are connected in series, when the two relay switching elements 33, 34 their second Assume switching position. Which switching position is present in each case, is specified by the control circuit 36.

By means of the two stator windings 16 and 17, a magnetic field can be generated in the electric motor 13. If the two stator windings 16, 17 are connected in series with one another, all windings of the stator windings 16, 17 are effective for forming the magnetic field. The two stator windings 16 and 17 are identical, in particular they have the same number of turns and the same wire cross-section. The total number of effective for the formation of the magnetic field turns results in series connection of the two stator windings 16 and 17 from the sum of the number of turns of the two windings. If the two stator windings 16 and 17 are connected in parallel with each other, the number of turns effective for forming the magnetic field is halved and the wire cross section is doubled compared to a series connection of the stator windings 16 and 17.

The electric motor 13 achieves its maximum power in parallel connection of the two stator windings 16 and 17, the two stator windings 16, 17 connected in series with each other, so the engine power is reduced.

Starting from a series connection of the two stator windings 16, 17, the motor power can be further reduced by using the phase control 39 by the TRIAC 41 in response to the desired engine power offset in time to a zero crossing of the AC voltage, an ignition pulse is provided. From this point on, the electric motor 13 is supplied with energy via the first supply line 53 and the second supply line 54 until the AC voltage reaches its next zero crossing. The TRIAC 41 then locks again until it is ignited again.

A change in engine performance can be achieved by the user of the high-pressure cleaner 10 in a simple manner by briefly closing the spray gun 22. If the spray gun 22 is closed, then a strong pressure increase is formed in the pressure line 21, which is detected by the signal generator 24. The signal generator 24 then provides the pressure switch 56 with a control signal, so that it passes into its open switching state and thereby interrupts the power supply of the electric motor 13. If subsequently the spray gun 22 is opened again by the user, a strong pressure drop occurs in the pressure line 21. This pressure drop too is detected by the signal generator 24, which then provides the pressure switch 56 a signal to re-close. Thus, the electric motor 13 is supplied with energy again. The opening and closing of the pressure switch 56 is detected by the test circuit 43 by this checks whether after the provision of an ignition pulse of the TRIAC 41 remains until the next zero crossing in its open position. This is the case only when the pressure switch 56 is closed. If the pressure switch 56 is opened, the current flow in the connecting line 47 is limited by the ohmic resistor 48 in such a way that the holding current required to maintain the opened state of the TRIAC 41 can not flow. This has the consequence that after ignition of the TRIAC 41 immediately closes again before the next zero crossing of the AC voltage is reached. This is detected by the test circuit 43, which provides the control circuit 36 with a signal corresponding to the behavior of the TRIAC 41. Based on the opening and closing behavior of the TRIAC 41 thus the switching state of the pressure switch 56 can be detected. This allows the control circuit 36 to change the power of the electric motor 13 if the user closes the spray gun 22 for a period of less than one second and then reopens.

If the electric motor 13 is operated with stator windings 16 and 17 connected in parallel, then the electric motor 13 can reach its maximum power by fully switching the TRIAC 41 on, that is to say, it already receives its ignition pulse at a zero crossing of the AC voltage. If the spray gun 22 is briefly closed by the user and then opened again at maximum engine power, the control circuit 36 controls the relay 32 in such a way that the relay switching elements 33 and 34 assume their second switching position, not shown in the drawing, in which the two stator windings 16 and 17 are connected in series with each other. For the other the control circuit 36 controls the phase angle control 39 such that the TRIAC 41 is switched with a small ignition angle. This results in a reduction of the engine power to 50% of the maximum power. If the user again interrupts the dispensing of pressurized cleaning liquid by momentarily closing and then re-opening the spray gun 22, the two stator windings 16, 17 continue to be connected in series, and in addition, the control circuit 36 controls the phase control 39 such that the TRIAC 41 is switched with a large ignition angle. The engine power can be reduced in this way, for example, to 30% of the maximum power. If the delivery of pressurized cleaning liquid by means of the spray gun 22 interrupted again briefly, the control unit 36 switches back to maximum motor power by the stator windings 16 and 17 are connected in parallel by means of the relay 32 and the TRIAC 41 is fully controlled.

A reduction of the engine power is thus carried out by means of the phase control 39, if there is already a reduced engine power, for example, a power of less than 1.4 kW. This ensures that non-permeable reactions to the supply network, to which the electric motor 13 is connected via the power supply connections 29 and 30, are reliably prevented even when the phase-angle control 39 is used.

Claims

PATENT CLAIMS

A high-pressure cleaning device comprising an electric motor and a pump driven by the electric motor for delivering pressurized cleaning fluid, wherein the electric motor comprises a coil device with at least one coil for generating a magnetic field and the electric motor is connected to a control device for controlling the engine power, characterized in that the number of windings of the coil device (15, 16, 17) which are effective for forming a magnetic field can be changed by means of the control device (27).

2. High-pressure cleaning device according to claim 1, characterized in that optionally a first or a second number of turns of the coil means (15, 16, 17) is effective to form a magnetic field.

3. High-pressure cleaning device according to claim 1 or 2, characterized in that the control device (27) comprises a switching device (32) for changing the effective effective number of turns of the coil means (15, 16, 17).

4. High-pressure cleaning device according to claim 3, characterized in that the switching device (32) is electrically controllable.

5. High-pressure cleaning device according to claim 3 or 4, characterized in that the switching device comprises at least one relay (32).

6. High-pressure cleaning device according to one of the preceding claims, characterized in that the coil device comprises at least one coil, which is designed as a stator winding (16, 17) of the electric motor (13).

7. High-pressure cleaning device according to claim 6, characterized in that the coil device comprises two coils, each forming a stator winding (16, 17) of the electric motor (13).

8. High-pressure cleaning device according to claim 7, characterized in that the two stator windings (16, 17) have the same number of turns.

9. High-pressure cleaning device according to claim 7, characterized in that the two stator windings have different numbers of turns.

10. High-pressure cleaning device according to claim 7, 8 or 9, characterized in that the two stator windings (16, 17) are selectively connected in parallel or in series with each other.

11. High-pressure cleaning device according to one of claims 7 to 10, characterized in that the two stator windings (16, 17) are designed identically.

12. High-pressure cleaning device according to one of the preceding claims, characterized in that the control device (27) comprises a phase control (39).

13. High-pressure cleaning device according to claim 12, characterized in that the engine power by means of the phase control (39) is continuously variable or switchable between at least two power values.

14. High-pressure cleaning device according to claim 12 or 13, characterized in that the phase control (39) comprises a TRIAC (41) to which a test circuit (43) is assigned for detecting the switching state of the TRIAC (41).

15. High-pressure cleaning device according to one of the preceding claims, characterized in that to the pump (12) a pressure line (21) is connected for dispensing pressurized cleaning fluid and that the engine power by opening and closing a in the pressure line (21) connected closing valve (22) is controllable.

16. High-pressure cleaning device according to claim 15, characterized in that the engine power in dependence on the period between the closing and the opening of the closing valve (22) is controllable.

17. A method for changing the power of the electric motor of a high-pressure cleaning device according to one of the preceding claims, characterized in that the number of effective for forming a magnetic field turns of the coil device increases to reduce the engine power.

18. The method according to claim 17, characterized in that two stator windings of the electric motor connected in series to reduce the engine power.

19. The method according to claim 17 or 18, characterized in that additionally reduces the engine power by means of a phase control.

20. The method according to claim 19, characterized in that, starting from a maximum motor power, in which two stator windings are connected in parallel, for the first power reduction, the stator windings connected in series and additionally reduces the power output by means of the phase control for further power reduction.

21. The method according to claim 19, characterized in that, starting from a maximum motor power, in which two stator windings are connected in parallel, for the first power reduction, the stator windings connected in parallel and the phase control operates with low firing angle and to achieve a further power reduction, the two stator windings in Series connection leaves and operates the phase control with a large ignition angle.