WO2012155335A1 - Forward-backward rotating circuit for direct-current brushless motor - Google Patents

Abstract

A forward-backward rotating circuit for a direct-current brushless motor includes an intelligent motor power chip (IC1), a plurality of hall elements and a circuit board (1) on which the intelligent power motor chip (IC1) and a plurality of hall elements are mounted. Two sets of mounting positions of the hall elements are reserved on the wire board (1). When a plurality of hall elements are inserted into the first set of mounting positions of the hall elements (11), the current flows from the first pins of hall elements to the third pins, and the second and fourth pins of the hall elements are connected with the intelligent power motor chip (IC1), thereby the motor is controlled by the intelligent power motor chip (IC1) to rotate normally. When a plurality of hall elements are inserted into the second set of mounting positions of the hall elements (12), the current flows from the third pins of hall elements to the first pins, and the second and fourth pins of the hall elements are connected with the intelligent power motor chip (IC1), thereby the motor is controlled by the intelligent power motor chip (IC1) to rotate reversely. The circuit has the advantages of simple structure, low manufacturing cost and easiness to implement.

Description

 A forward and reverse circuit of a brushless DC motor TECHNICAL FIELD

 The utility model relates to a forward and reverse circuit of a brushless DC motor.

Background technique :

 At present, the DC brushless motor controller generally has a microprocessor MCU and an IGBT driver chip. The combination of the microprocessor MCU and the IGBT driver chip has complicated peripheral circuits, resulting in an increase in cost, and is not fully utilized to the microprocessor MCU. In view of this, some manufacturers specialize in developing integrated chips for DC brushless motors, such as TPD4122K motor control chip developed by Toshiba Corporation, FM500K AX02 chip developed by other companies, etc. These chips have high integration, small peripheral circuits, and circuits. The structure is simple and the cost is low, so it is accepted by the majority of manufacturers. However, there are some defects: Since the pins of each chip are defined, the number of pins is small, some chips are not considered in development, and there is a lack of forward and reverse considerations. It is urgent to use a method to solve the rotor stator. The unchanging situation will solve the problem of the utility model of the positive and negative problems:

 The purpose of the utility model is to provide a forward and reverse circuit of a brushless DC motor, which has a simple circuit structure, low manufacturing cost, easy implementation of the cylinder, and realizing the forward and reverse of the DC brushless motor under the condition that the rotor stator is constant. The function.

 The object of the present invention is achieved by the following technical solutions.

A forward and reverse circuit of a DC brushless motor, comprising a motor intelligent power chip, a plurality of Hall elements and a circuit board, a motor smart power chip, and a plurality of Hall elements are mounted on the circuit board, wherein: The board reserves two sets of Hall element mounting positions. When several Hall elements are inserted and mounted in the first group of Hall element mounting positions, current flows from the first leg of the Hall element to the third leg, and the second leg of the Hall element. And the fourth foot is connected with the motor intelligent power chip, and the motor intelligent power chip controls the motor to rotate forward; when several Hall elements are inserted and installed in the second group of Hall element mounting positions, the current flows from the third leg of the Hall element to the first Foot, the second and fourth feet of the Hall element are connected to the motor smart power chip, and the motor intelligent power chip controls the motor to reverse. There are three Hall elements mentioned above, and the DC brushless motor is a 3-phase motor.

 There are three mounting positions of the first group of Hall elements described above, and three mounting positions of the second group of Hall elements.

 The first group of Hall element mounting positions described above is ahead of the normal commutation position of the motor by a mechanical angle B, and the second group of Hall element mounting positions are advanced by a mechanical angle B from the normal commutation position of the motor.

 In the above, when a plurality of Hall elements are inserted and mounted in the first group of Hall element mounting positions, the first leg of the Hall element is connected to the power source Vcc through a resistor, and the third leg is connected to the ground through a resistor.

 In the above, when a plurality of Hall elements are inserted and mounted in the second group of Hall element mounting positions, the first leg of the Hall element is connected to the ground through a resistor, and the third leg is connected to the power source Vcc through a resistor.

 Compared with the prior art, the utility model has the following advantages: while reducing the cost of the motor by using a dedicated integrated control chip of the DC brushless motor, by installing two sets of Hall element mounting positions on the circuit board, when several Hall elements are used Inserted and installed in the first group of Hall element mounting positions, current flows from the first leg of the Hall element to the third leg, and the second and fourth legs of the Hall element are connected to the motor intelligent power chip, and the motor intelligent power chip controls the motor. Forward rotation; When several Hall elements are inserted and installed in the second group of Hall element mounting positions, current flows from the third leg of the Hall element to the first leg, and the second and fourth legs of the Hall element and the motor intelligent power The chip is connected, the motor intelligent power chip controls the motor reversal, the circuit structure is simple, the manufacturing cost is low, the cylinder is easy to implement, and the forward and reverse functions of the DC brushless motor are realized under the condition that the rotor stator is unchanged. BRIEF DESCRIPTION OF THE DRAWINGS:

 Figure 1 is a schematic view of the structure of the present invention;

 Figure 2 is a cross-sectional view taken along line A-A of Figure 1;

 3 is a circuit diagram of the Hall element of the present invention installed at a mounting position of the first group of Hall elements; and FIG. 4 is a circuit diagram of the Hall element of the present invention installed at a mounting position of the second group of Hall elements. detailed description:

The present invention will be further described in detail below through specific embodiments and with reference to the accompanying drawings: FIG. 1, FIG. 2, FIG. 3 and FIG. 4, a forward/reverse circuit of a DC brushless motor, including a motor smart power chip IC1, several Hall elements and circuit board 1, motor intelligent power chip IC1, if The dry Hall elements are all mounted on the circuit board 1. Two sets of Hall element mounting positions are reserved on the circuit board 1. When several Hall elements are inserted and mounted in the first group of Hall element mounting positions 11, the current flows from the Hall. The first leg of the component flows to the third leg, and the second and fourth legs of the Hall component are connected to the motor intelligent power chip IC1, and the motor intelligent power chip IC1 controls the motor to rotate forward; when several Hall components are inserted and installed in the second The Hall element is mounted at position 12, the current flows from the third leg of the Hall element to the first leg, and the second and fourth legs of the Hall element are connected to the motor intelligent power chip IC1, and the motor intelligent power chip IC1 controls the motor reversal. There are three Hall elements, the DC brushless motor is a 3-phase motor, the first group of Hall element mounting positions 11 has three, and the second group of Hall element mounting positions 12 also has three, the first The group Hall element mounting position 11 is ahead of the normal commutation position of the motor by a mechanical angle B, and the second group of Hall element mounting positions 12 is ahead of the normal commutation position of the motor by a mechanical angle B, when several Hall elements are inserted and installed. a group of Hall elements In the mounting position 11, the first leg of the Hall element is connected to the power source Vcc through the resistor R12, and the third leg is connected to the ground through the resistor R1 Q. When several Hall elements are inserted and mounted in the second group of Hall element mounting positions 12, The first leg of the element is connected to the ground through a resistor R10, and the third leg is connected to the power source Vcc via a resistor R12. The first group of Hall element mounting positions 11, the second group of Hall element mounting positions 12, the resistor R10, the resistor R12, the power source Vcc, the ground, and the pins of the motor smart power chip IC1 are connected by printed lines on the surface of the board 1.

 The principle of the utility model is: By installing two sets of Hall element mounting positions on the circuit board 1, when several Hall elements H1, H2, H3 are inserted and installed in the first group of Hall element mounting positions 11, the current flows from the Hall. The first leg of the components H1, H2, and H3 flows to the third leg, and the second and fourth legs of the Hall elements H1, H2, and H3 are connected to the motor smart power chip, and the motor smart power chip IC1 controls the motor to rotate forward; The Hall elements H1, H2, and H3 are inserted and mounted in the second group of Hall element mounting positions 12, and the current flows from the third leg of the Hall elements H1, H2, and H3 to the first leg, and the Hall elements HI, H2, and H3. The second leg and the fourth leg are connected to the motor intelligent power chip IC1, and the motor intelligent power chip IC1 controls the motor to reverse, the circuit structure is simple, the manufacturing cost is low, and the tube is easy to implement.

The above embodiments are preferred embodiments of the present invention, but the embodiments of the present invention are not limited thereto, and any other changes, modifications, and alterations made without departing from the spirit and principles of the present invention. Generation, combination, and tube, all equivalent replacement methods are included in the scope of protection of the present invention.

Claims

Rights request

 1. A forward/reverse circuit of a DC brushless motor, comprising a motor intelligent power chip (IC1), a plurality of Hall elements and a circuit board (1), a motor intelligent power chip (IC1), and a plurality of Hall elements are mounted. On the circuit board (1), it is characterized in that: two sets of Hall element mounting positions are reserved on the circuit board (1), and a plurality of Hall elements are inserted and mounted in the first group of Hall element mounting positions (11), current From the first leg of the Hall element to the third leg, the second and fourth legs of the Hall element are connected to the motor intelligent power chip (IC1), and the motor intelligent power chip (IC1) controls the motor to rotate forward; The component is inserted into the second group of Hall element mounting positions (12), the current flows from the third leg of the Hall element to the first leg, and the second and fourth legs of the Hall element are coupled to the motor smart power chip (IC1). Connected, the motor smart power chip (IC1) controls the motor reversal.

 2. A forward/reverse circuit for a brushless DC motor according to claim 1, wherein: a plurality of Hall elements are three, and said DC brushless motor is a 3-phase motor.

 3. A forward/reverse circuit for a brushless DC motor according to claim 2, wherein: the first group of Hall element mounting positions (11) has three, and the second group of Hall element mounting positions (12) There are also 3).

 4. A forward/reverse circuit for a brushless DC motor according to claim 1 or 2 or 3, wherein: the first set of Hall element mounting positions (11) is ahead of the normal commutation position of the motor by a mechanical angle B, the second group of Hall element mounting positions (12) is ahead of the normal commutation position of the motor by a mechanical angle

B.

 The forward/reverse circuit of a brushless DC motor according to claim 1 or 2 or 3, wherein: when a plurality of Hall elements are inserted and mounted in the first group of Hall element mounting positions (11), The first leg of the Hall element is connected to the power supply Vcc through a resistor (R12), and the third pin is connected to the ground through a resistor (R10).

 6. A forward/reverse circuit for a brushless DC motor according to claim 1 or 2 or 3, wherein: when a plurality of Hall elements are inserted and mounted in the second group of Hall element mounting positions (12), The first leg of the element is connected to the ground through a resistor (R10), and the third leg is connected to the power source Vcc via a resistor (R12).