Weight loading system for fitness equipments

Abstract

A weight loading system for fitness equipments includes a fitness equipment support, a rally rope, a motor, a motor driving and a motor control unit. The motor is a permanent magnet brushless DC motor with an external rotor structure, and the motor includes a stator mounted onto the fitness equipment support and an external rotor sheathed on the stator and rotatable with respect to the stator, and the rally rope is wound around the external rotor of the motor, and an end of the rally rope is coupled to the external rotor of the motor, and the other end of the rally rope is coupled to the power driving mechanism of the fitness equipment; the power driving mechanism is provided for driving the external rotor of the motor through the rally rope to rotate and generate a rally, and the motor control unit controls the motor to rotate in an opposite direction through the motor driving module, so as to produce a load force opposite to the rally. The weight loading system for fitness equipments structure is simple, lightweight, and achieves the effect of a stepless weight control.

Claims

1. A weight loading system for a fitness equipment comprising a power driving mechanism, the weight loading system comprising: a fitness equipment support, a rally rope, a motor, a motor driving module and a motor control unit, wherein the motor is a permanent magnet brushless DC motor, and the motor includes a stator mounted onto the fitness equipment support and an external rotor sheathed on the stator and rotatable with respect to the stator, and the rally rope is wound around the external rotor of the motor, and an end of the rally rope is coupled to the external rotor of the motor, and the other end of the rally rope is coupled to a power driving mechanism of a fitness equipment; the power driving mechanism is provided for driving the external rotor of the motor through the rally rope to rotate and generate a rally, and the motor control unit controls the motor to rotate in an opposite direction through the motor driving module, so as to produce a load force opposite to the rally; the weight loading system further comprising a tension sensor for detecting the rally produced by the power driving mechanism currently; the weight loading system further comprising an operation interface, a position sensing circuit and a power switch; the motor driving module comprising a synchronous PWM generating unit, wherein the position sensing circuit is provided for sensing a rotating position of the external rotor to determine whether the rally rope is situated in a stretched status or a retracted status, and the motor control unit comprises a memory unit for recording an initial position of the external rotor to control the external rotor to return to the initial position thereof; the operation interface is provided for inputting an analog electromagnetic force Fe, such that when the tension sensor detects the rally Fc produced by the power driving mechanism currently, a current of the motor is regulated by the motor control unit according to a difference of the rally FeFc, and a current information and a switch status are transmitted by the synchronous PWM generating unit to the power switch to drive the motor to work or generate electric power; the weight loading system further comprising a battery, such that when the rally rope on the external rotor is situated at the stretched status, a winding of the motor produces a potential, and the power switch transmits and stores an electricity generated by the potential into the battery, and the electricity stored in the battery provides a driving force to the external rotor when the rally rope is being retracted; when the rally rope is in the retracted status and Fe>Fc, the current is increased; when the rally rope is in the retracted status and Fe<Fc, the current is decreased; when the rally rope is in the stretched status and Fe>Fc, the motor is driven in a resisted status through the power switch; when the rally rope is in the stretched status and Fe<Fc, the battery is charged by the power switch.

2. The weight loading system according to claim 1, further comprising a pulley installed to the fitness equipment support and coordinated with the transmission of the rally rope.

3. The weight loading system according to claim 1, wherein the motor is a wheel hub type motor.

4. The weight loading system according to claim 1, further comprising two switches for increasing and decreasing the electromagnetic force Fe, and the switches being coupled to the motor control unit.

5. A fitness equipment, comprising a weight loading system and a power driving mechanism, the weight loading system comprising: a fitness equipment support, a rally rope, a motor, a motor driving module and a motor control unit, wherein the motor is a permanent magnet brushless DC motor, and the motor includes a stator mounted onto the fitness equipment support and an external rotor sheathed on the stator and rotatable with respect to the stator, and the rally rope is wound around the external rotor of the motor, and an end of the rally rope is coupled to the external rotor of the motor, and the other end of the rally rope is coupled to the power driving mechanism of the fitness equipment; the power driving mechanism is provided for driving the external rotor of the motor through the rally rope to rotate and generate a rally, and the motor control unit controls the motor to rotate in an opposite direction through the motor driving module, so as to produce a load force opposite to the rally; the weight loading system further comprising a tension sensor for detecting the rally produced by the power driving mechanism currently; the weight loading system further comprising an operation interface, a position sensing circuit and a power switch; the motor driving module comprising a synchronous PWM generating unit, wherein the position sensing circuit is provided for sensing a rotating position of the external rotor to determine whether the rally rope is situated in a stretched status or a retracted status, and the motor control unit comprises a memory unit for recording an initial position of the external rotor to control the external rotor to return to the initial position thereof; the operation interface is provided for inputting an analog electromagnetic force Fe, such that when the tension sensor detects the rally Fc produced by the power driving mechanism currently, a current of the motor is regulated according to a difference of the rally FeFc, and a current information and a switch status are transmitted by the synchronous PWM generating unit to the power switch to drive the motor to work or generate electric power; the weight loading system further comprising a battery, such that when the rally rope on the external rotor is situated at the stretched status, a winding of the motor produces a potential, and the power switch transmits and stores an electricity generated by the potential into the battery, and the electricity stored in the battery provides a driving force to the external rotor when the rally rope is being retracted; when the rally rope is in the retracted status and Fe>Fc, the current is increased; when the rally rope is in the retracted status and Fe<Fc, the current is decreased; when the rally rope is in the stretched status and Fe>Fc, the motor is driven in a resisted status through the power switch; when the rally rope is in the stretched status and Fe<Fc, the battery is charged by the power switch; wherein the power driving mechanism is a handle ring or a rally bar, and the rally rope is configured to be controlled through the handle ring or the rally bar to drive the external rotor of the motor to rotate, so as to produce the rally.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a schematic planar view of a fitness equipment of the present invention;

(2) FIG. 2 is a schematic view showing the operating principle of a weight loading system for fitness equipments in accordance with the present invention;

(3) FIG. 3 is a schematic planar view of another weight loading system for fitness equipments in accordance with the present invention; and

(4) FIG. 4 is a schematic view showing the operating principle of a weigh method in accordinance to the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

(5) The above and other objects, features and advantages of this disclosure will become apparent from the following detailed description taken with the accompanying drawings.

(6) With reference to FIGS. 1 and 3 for a fitness equipment provided for training a user's back, and the fitness equipment comprises a fitness equipment support (4), a rally rope (5), a motor (1), a motor driving module and a motor control unit; the motor (1) is a permanent magnet brushless DC motor with an external rotor structure, and specifically a wheel hub type motor, and the motor includes a stator (11) mounted onto the fitness equipment support (4) and an external rotor (12) sheathed on the stator (11) and rotatable with respect to the stator (11), and the rally rope (5) is wound around the external rotor (12) of the motor (1), and an end of the rally rope (5) is coupled to the external rotor of the motor (1), and the other end of the rally rope (5) is coupled to the power driving mechanism (6) of the fitness equipment; the power driving mechanism (6) is provided for driving the external rotor (12) of the motor (1) through the rally rope (5) to rotate and generate a rally, and the motor control unit controls the motor to rotate in an opposite direction through the motor driving module, so as to produce a load force opposite to the rally. In fact, the load force is slightly smaller than the rally of the power driving mechanism (6) so as to produce an applying force of the weight.

(7) The present invention further comprises a tension sensor (7) for detecting a rally produced by the power driving mechanism currently. The tension sensor (7) may be installed onto the pulley (2) or between the shaft of the motor (1) and the fitness equipment support (4), or any other appropriate position as needed.

(8) The power driving mechanism (6) is a handle ring or a rally bar, and a human body can control the rally rope (5) through the handle ring or the rally bar to drive the external rotor of the motor (1) to rotate, so as to produce the rally.

(9) The present invention further comprises a pulley (2) installed to the fitness equipment support (4) and coordinated with the transmission of the rally rope (5).

(10) With reference to FIG. 2 for a schematic view showing the operating principle of a weight loading system for fitness equipments in accordance with the present invention, the weight loading system comprises an operation interface module, a torque control unit, a current regulating unit, a position sensing circuit and a power switch module, wherein the motor driving module includes a synchronous PWM generating unit.

(11) The position sensing circuit is provided for sensing a rotating position and a rotating speed of the external rotor (12) to determine whether the rally rope (5) is situated in a stretched status or a retracted status, and the motor control unit includes a memory unit for recording an initial position of the external rotor (12) to control the external rotor to return to its initial position.

(12) The operation interface module is provided for inputting an analog electromagnetic force Fe, such that when the tension sensor (7) detects the rally Fc produced by the power driving mechanism (6) currently, the motor control unit regulates the current of the motor (1) according to the difference of the rally FeFc by the torque control unit and the current regulating unit, and a control module of the motor (1) controls transmitting the current information and switch status module to the power switch module by the synchronous PWM generating unit to drive the motor (1) to work or generate electric power.

(13) The present invention further comprises a battery, such that when the rally rope (5) on the external rotor (12) is situated at a stretched status, the winding of the motor (1) produces a potential, and the power switch module transmits and stores the electricity generated by the potential into the battery, and the electricity stored in the battery provides a driving force to the external rotor (12) when the rally rope (5) is being retracted.

(14) To improve the fitness exercise effect, the present invention further comprises two switches for increasing and decreasing the electromagnetic force Fe, and the switches is coupled to the motor control unit. During a fitness exercise process, the force can be controlled anytime to achieve the best fitness exercise effect.

(15) The present invention further comprises a motor rotating speed calculation unit and a current converting position calculation unit, wherein the motor rotating speed calculation unit and the current converting position calculation unit are controlled by and coupled to the synchronous PWM generating unit, and the motor rotating speed calculation unit is provided for calculating the rotating speed and direction of the external rotor (12), and the current converting position calculation unit is provided for calculating a switch status required by the power switch module according to the information of the position sensing circuit.

(16) When the rally rope (5) is in the retracted status and Fe>Fc, the torque control unit and the current regulating unit are used to increase the current; when the rally rope (5) is in the retracted status and Fe<Fc, the torque control unit and the current regulating unit are used to decrease the current.

(17) When the rally rope (5) is in the stretched status and Fe>Fc, the torque control unit and the current regulating unit drives the motor (1) to be situated in a resisted status through the power switch module.

(18) When the rally rope (5) is in the stretched status and Fe<Fc, the torque control unit and the current regulating unit charge the battery by the power switch module.

(19) The present invention further provides a weight method comprising the following steps:

(20) setting the magnitude of an analog electromagnetic force Fe, and detecting the current rally Fc by a rally sensor, increasing a duty cycle by a PWM method to increase the current of the motor (1) when FeFc>0, and decreasing the duty cycle to decrease the current of the motor (1) when FeFc<0;

(21) detecting the current current of the motor (1) by a current detection circuit, and feeding back the current current of the motor (1) to a control unit of the motor (1);

(22) wherein, the motor (1) includes a wheel hub comprised of a plurality of permanent magnets, and the relative position of a magnetic field produced by a winding of the motor (1) with respect to the permanent magnet being different, and the position of the motor (1) detected by the position sensor is used for calculating a position compensation parameter according to the current position.

(23) A motor rotating speed calculation unit obtains a rotating speed of the motor (1), and calculates a corresponsive speed compensation parameter according to the current rotating speed of the motor (1). With reference to FIG. 4 for the specific process, an analog electromagnetic force Fe is inputted from a man-machine operation interface, and Fe is equivalent to the weight of an iron block or a load selected for a conventional fitness equipment, and the intensity of such force is stepless and measured in the unit of Kg, and such force is unlike the combination of iron blocks having a limited weight. The position detection circuit and the memory of the motor control unit are operated together to detect whether or not the fitness equipment is situated at an initial status. If the fitness equipment is not situated at the initial status, the rotation of the motor (1) will be controlled to set the fitness equipment back to its original position.

(24) When a user starts the fitness exercise, the user pulls the handle bar downward, and transmits the force through the rally rope (5) and the pulley (2) to the tension sensor and further to the motor external rotor (12) of the motor (1) wound with the rally rope (5), and the tension sensor will detect the current rally Fc, and the motor control unit adjusts the current of the motor (1) by the torque control unit and the current regulating unit according to the rally difference FeFc. If FeFc>0, then the current of the motor (1) will be controlled to increase, or else the current of the motor (1) will be decreased. The regulation algorithm may be a classical PID algorithm or a fuzzy control algorithm, or any other appropriate algorithm. Regardless of which algorithm is used, the pulse width modulation (PWM) method may be used to control the motor (1), or change the duty cycle of the winding of the motor (1) to determine the current of the motor (1).

(25) The control of the current of the motor (1) is related to different factors, and the following factors will be taken into consideration:

(26) Setting a target rally Fe: Without considering the mechanical efficiency of the rally rope (5) and the pulley (2), Fe mainly determines the torque required by the motor (1), and the torque of the motor (1) is related to the current passing through the winding of the motor. In other words, the required current may be calculated by Fe.

(27) Supplying a DC voltage: The voltage of a power supply varies. Even if the duty cycle value is equal, the current output may be different. Therefore, it is necessary to have a voltage sample of the power supply by a voltage signal processing circuit, and perform an AD conversion. A corresponding voltage compensation parameter may be calculated according to a voltage signal.

(28) The position of the motor (1): A permanent magnet DC brushless motor is a wheel hub motor comprised of a plurality of permanent magnets. Since the relative position for the winding of the motor to produce a magnetic field by the permanent magnet varies, the torque produced by a motor with the same current is different (In other words, the rally is different. An encoding sensor (which is a part of the position sensing circuit) is provided for detecting the position of the motor (1). The corresponding position compensation parameter can be calculated according to the position of the current.

(29) The rotating speed of the motor (1): When the motor (1) is rotated, a counter potential is produced. Even if the duty cycle value is the same, the rotating speed, and the output current may be different. The position sensing circuit is provided for detecting the position of the motor (1), so the motor rotating speed calculation unit may obtains the rotating speed of the motor (1) by software. Therefore, the corresponding speed compensation parameter can be calculated according to the current rotating speed of the motor (1).

(30) Another effect of the position sensing circuit is to change phases. The permanent magnet DC motor of the invention has a three-phase winding, so that when the motor is rotated, it is necessary to change the phase anytime. A Hall sensor is installed inside the motor, and a current conversion calculation unit is provided for providing a signal while the current is converted. The signal is combined with the aforementioned parameters, and the synchronous PWM generating unit generates six complementary three-phase PWM waveforms, and a driving signal isolation circuit increments the waveform by 1, and perform a high/low voltage isolation, and then transmits the waveform to a three-phase voltage inverter circuit to drive the permanent magnet brushless motor to achieve a power output up to the level of several kilowatts.

(31) A phase current sampling circuit is provided for detecting the current current of the motor current and feeding back the current to the motor control unit. The phase current sampling circuit is a part of motor protection circuit, wherein if the current exceeds a specific threshold, an alarm is alerted or the operation of the motor is stopped. A temperature signal processing circuit is provided for protecting a high power MOS tube in the three-phase voltage inverter circuit, to prevent the tube from being overheated or disabled.

(32) The weight loading system for fitness equipments uses the permanent magnet brushless DC motor of the external rotor structure to replace the traditional block as a weight, so that the structure is simple, easy, and lightweight, and the principle of electromagnetism is used to adjust the force of the weight to achieve the stepless control effect, and the training becomes more effective, and this system can control the rotating speed of the motor to overcome the problem of the prior art and the issue of dropping the clump weight or damaging the equipment while loosening the power driving mechanism.

(33) While the invention has been described by means of specific embodiments, numerous modifications and variations could be made thereto by those skilled in the art without departing from the scope and spirit of the invention set forth in the claims.