DE202018103456U1 - Charging system for a brushless motor driven, continuously operating generator - Google Patents

Abstract

Charging system for a brushless motor driven, continuously operating generator comprising
a brushless DC motor (1) connected to a motor controller (11), the motor controller (11) setting a duty period after a pulse width modulation (PWM) to change the rotational speed of the brushless DC motor (1); and
a generator (2) which is connected to the brushless DC motor (1), wherein the generator (2) is driven in synchronism with the power generation when the brushless DC motor (1) rotates.

Description

[Technical area]

The invention relates to a brushless motor-driven, continuously operating generator, in particular a charging system for a brushless motor driven, continuously operating generator, which provides for a continuous and stable power generation to realize an uninterruptible and stable power supply.

[State of the art]

Currently, a large number of new energy sources such as solar energy, wind energy, etc. are used. However, solar energy and wind energy are subject to various restrictions during operation, with weather-related factors such as irradiance, wind force, etc., resulting in unstable power generation, resulting in extremely large inconvenience of pantographs to renewable energy.

OBJECT OF THE INVENTION

The invention has for its object to avoid the above-mentioned shortcomings and to provide a charging system for a driven by a brushless motor, continuously operating generator, which ensures a continuous and stable power generation, which is not only a convenient use by a stable and uninterruptible Power supply, but also increases the practicality of the whole.

[Technical solution]

This object is achieved by a charging system for driven by a brushless motor, continuously operating generator having the features specified in claims 1, 3 and 7. Further advantageous developments of the invention will become apparent from the dependent claims.

list of figures

• 1 ein Blockdiagramm eines Ausführungsbeispiels eines erfindungsgemäßen Aufladesystems eines durch einen bürstenlosen Motor angetriebenen, ununterbrochen arbeitenden Generators,
• 2 ein Blockdiagramm eines weiteren Ausführungsbeispiels eines erfindungsgemäßen Aufladesystems eines durch einen bürstenlosen Motor angetriebenen, ununterbrochen arbeitenden Generators,
• 3 ein PWM-(Pulsweitenmodulation)-Wellenformdiagramm einer herkömmlichen Zerhackersteuerung,
• 4 ein Oberwellen-PWM-Wellenformdiagramm einer erfindungsgemäßen Zerhackersteuerung,
• 5 ein Hybrid-PWM-Wellenformdiagramm einer erfindungsgemäßen Zerhackersteuerung und
• 6 ein Blockdiagramm eines noch weiteren Ausführungsbeispiels eines erfindungsgemäßen Aufladesystems eines durch einen bürstenlosen Motor angetriebenen, ununterbrochen arbeitenden Generators.

In the following the invention and its embodiments will be explained in more detail with reference to the drawings. In the drawings shows

• 1 a block diagram of an embodiment of a charging system according to the invention of a brushless motor driven, continuously operating generator,
• 2 a block diagram of another embodiment of a charging system according to the invention of a brushless motor driven, continuously operating generator,
• 3 a PWM (pulse width modulation) waveform diagram of a conventional chopper control,
• 4 a harmonic PWM waveform diagram of a chopper control according to the invention,
• 5 a hybrid PWM waveform diagram of a chopper control according to the invention and
• 6 a block diagram of yet another embodiment of a charging system according to the invention of a driven by a brushless motor, continuously operating generator.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Based on an in 1 1 is an exemplary embodiment of the charging system according to the invention for the brushless motor-driven, continuously operating generator with reference to FIG 3 . 4 and 5 , described, wherein 3 a PWM pulse width modulation waveform diagram of a conventional chopper control and 4 shows a harmonic PWM waveform diagram of a chopper control according to the invention, during 5 FIG. 3 illustrates a hybrid PWM waveform diagram of a chopper control according to the invention. FIG.

Like in the 1 is shown, the charging system according to the invention of the driven by the brushless motor, continuously operating generator comprises a brushless DC motor 1 , a generator 2 , a magnet generator 3 and a battery 4 where the brushless DC motor 1 with a motor controller 11 connected is. The motor controller 11 works according to a 120 ° switch-on method, ie the brushless DC motor 1 To drive, only the windings for two phases are switched on simultaneously in a three-phase winding system. Therefore, only two power transistors not shown in the drawings and two flywheel diodes not shown in the drawings are used in each zone, with a stator winding current being proportional to a motor torque, thus allowing the speed of the brushless DC motor 1 is set by the size of the stator winding current is driven accordingly. To the stator winding current one must turn on the brushless DC motor 1 However, voltage applied to be changed by a modulation input, ie to change a duty cycle of the chopper control according to the invention, a working period must be controlled by means of the PWM, whereby the rotational speed of the brushless DC motor 1 is regulated in the present invention.

Typically, signals used to switch the power transistors of a three-phase inverter controlled by PWM are handled by three chopper control strategies. These are a conventional chopper control circuit whose PWM waveform diagram is shown in FIG 3 is shown, provided with an upper arm chopper control circuit whose PWM waveform diagram in 4 and a hybrid chopper control circuit whose PWM waveform diagram is shown in FIG 5 is shown.

As in 1 shown is the generator 2 with the brushless DC motor 1 connected, wherein a coil, not shown in the drawing of the generator 2 is driven synchronously with, so that the coil rotates between two poles of a magnet, not shown in the drawings, when the brushless DC motor 1 rotates, resulting in a coil in the generator 2 magnetic field changes, so that an induction current is generated to recover electrical energy.

Next in terms of 1 is the magnet generator 3 also with the brushless DC motor 1 connected, wherein a metal wire spool of the magnetic generator 3, not shown in the drawings is driven synchronously with and rotates about the two poles of the magnet, not shown in the drawings, when the brushless DC motor 1 rotates. At each revolution, a circuit breaker (also called a contact) is opened one or more times by a cam, not shown in the drawings, whereby current is generated in the magnetic field of a primary coil by said interruptions. If the magnetic field disappears, a voltage is created on the primary coil. When the contact is opened, a plurality of contact points are formed between a contact pitch, which means that the voltage generated on the primary coil is applied between the corresponding points, with appropriate capacitors being attached to the individual points to calm a possible arc and the To stabilize voltage on the primary coil, and wherein a Energiedissipationsrate the primary coil is controlled to generate electricity.

Still further in terms of 1 becomes the battery 4 electrically with the generator 2 and the magnet generator 3 connected, so that the stored electrical energy to the generator 2 and the magnet generator 3 is provided, the battery 4 simultaneously with the motor controller 11 of the brushless DC motor 1 is connected, so that for the operation of the brushless DC motor 1 required, electrical energy via the motor controller 11 is delivered.

This will realize that the brushless DC motor 1 during its operation via the motor controller 11 with the in the battery 4 stored energy is supplied while the motor controller 11 by means of the PWM regulates the working period to the speed of the brushless DC motor 1 continue to regulate, with the generator 2 and the magnet generator 3 be driven synchronously to power generation when the brushless DC motor 1 simultaneously rotated. The through the generator 2 and the magnet generator 3 generated electrical energy is separated from each other to the battery 4 forwarded and stored there, which allows the battery 4 not only for the operation of the brushless DC motor 1 provides required electrical energy, but also provides a household appliance, the electrical energy. The fully charged battery can either be sold to an electricity company or used to drive a transport.

In 2 FIG. 12 shows another embodiment of the present invention in which the charging system of the DC brushless motor is shown 1 powered, continuously working generator directly in a means of transport 6 used as a motor vehicle or a motorcycle, the generator 2 electrically with the brushless DC motor 1 and an energy storage device 61 of the means of transport 6 connected is. When the brushless DC motor 1 rotates, rotates the coil of the generator, not shown in the drawings 2 by driving between the two poles of the magnet, not shown in the drawings, whereby the magnetic field in the coil of the generator 2 is changed and an induction current is generated to generate the current, wherein the generated electrical energy to the energy storage device 61 of the means of transport 6 is forwarded so that enough power to charge the energy storage device 61 of the means of transport 6 is available. Subsequently, in the energy storage device 61 of the means of transport 6 stored electrical energy via the motor controller 11 to the brushless DC motor 1 delivered so that it is driven to the means of transport 6 put into operation. In addition, the during the operation of the means of transport 6 generated electrical energy back to the energy storage device 61 of the means of transport 6 forwarded and stored there.

A still further embodiment of the present invention is in 6 shown in a block diagram. In 6 let the generator 2 and the magnet generator 3 of the charging system according to the present invention from that by the brushless DC motor 1 powered, continuously working generator separately from each other with two groups of batteries 4 . 5 connect, taking a group of batteries 4 both electrically with the magnet generator 3 as well as simultaneously with the motor controller 11 of the brushless DC motor 1 which realizes that the motor controller 11 the brushless DC motor 1 provides the electrical energy needed for operation. The other group of batteries 5 becomes electric with the generator 2 connected, with the batteries 5 corresponding lead-acid battery (deep cycle lead-acid battery) are, which convert the stored electrical energy from a direct current into an alternating current and make this the corresponding household appliances of various types available.

In summary, the invention relates to a charging system for a brushless motor-driven, continuously operating generator comprising a brushless DC motor, a generator and a battery, wherein the DC brushless motor is connected to a motor controller which controls a duty cycle after pulse width modulation (PWM). to further change a speed of the brushless DC motor. The generator is connected to the brushless DC motor, so that the generator is driven synchronously to generate power when the brushless DC motor rotates. The battery is electrically connected to the generator and serves to store the generated electrical energy, the stored electrical energy being provided to the generator. In addition, the battery is electrically connected to the motor controller so that the electrical energy stored in the battery pack is supplied to the brushless DC motor via the motor controller to provide the electrical energy needed to operate the brushless DC motor.

From the foregoing description, the present invention will be explained along with its embodiments, from which it can be seen that the present invention can stably and continuously generate electricity as compared with the conventional art, not only allowing easy use by a stable and uninterruptible power supply, but also also increases the practical applicability of the present invention holistically.

Claims (10)

Charging system for a brushless motor driven, continuously operating generator comprising a brushless DC motor (1) connected to a motor controller (11), the motor controller (11) setting a duty period after a pulse width modulation (PWM) to change the rotational speed of the brushless DC motor (1); and a generator (2) which is connected to the brushless DC motor (1), wherein the generator (2) is driven in synchronism with the power generation when the brushless DC motor (1) rotates. Charging system after Claim 1 , characterized in that the brushless DC motor (1) is connected to a means of transport (6) having an energy storage device (61). Charging system for a brushless motor driven, continuously operating generator comprising a brushless DC motor (1) connected to a motor controller (11), the motor controller (11) setting a duty period after a pulse width modulation (PWM) to change the rotational speed of the brushless DC motor (1); and a generator (2) connected to the brushless DC motor (1), wherein the generator (2) is driven in synchronism with power generation when the brushless DC motor (1) rotates; a battery (4) electrically connected to the generator (2), the battery (4) providing electrical energy generated by the generator (2), the battery (4) being electrically connected to the motor controller (4); 11) of the brushless DC motor (1), so that the electric power required by the brushless DC motor (1) can be supplied through the motor controller (11). Charging system after Claim 3 characterized in that the brushless DC motor (1) is further connected to a magnet generator (3) connected to the battery (4), the magnet generator (3) being driven in synchronism with power generation when the brushless DC motor (1 ), whereby the generated electrical energy can be forwarded to the battery (4) and stored. Charging system after Claim 3 , characterized in that in the battery (4) stored electrical energy can either be provided to a household appliance or used to drive a means of transport. Charging system after Claim 3 , characterized in that the fully charged battery (4) can be sold to an electricity company. Charging system for a brushless motor driven, continuously operating generator comprising a brushless DC motor (1) connected to a motor controller (11), the motor controller (11) setting a duty period after a pulse width modulation (PWM) to change the rotational speed of the brushless DC motor (1); and a generator (2) connected to the brushless DC motor (1), wherein the generator (2) is driven in synchronism with power generation when the brushless DC motor (1) rotates; a magnet generator (3) connected to the brushless DC motor (1), wherein the magnet generator (3) is driven in synchronism with power generation when the brushless DC motor (1) rotates; and two groups of batteries (4), which are separately connected electrically to the generator (2) and to the magnetic generator (3), the two batteries (4) providing an electrical energy generated by the generator (2) electrical energy generated by the magnetic generator (3), wherein the battery (4) electrically connected to the magnetic generator (3) is electrically connected to the motor controller (11) of the brushless DC motor (1), so that the brushless DC motor (1 ) supplied electrical energy through the motor controller (11), while connected to the generator (2) battery (4) provides a domestic appliance, the electrical energy. Charging system after Claim 7 , characterized in that the batteries (4) are designed as lead-acid batteries with deep discharge characteristics. Charging system after Claim 7 , characterized in that in the battery (4) stored electrical energy can either be provided to a household appliance or used to drive a means of transport. Charging system after Claim 7 , characterized in that the fully charged battery (4) can be sold to an electricity company.

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