KR20110108163A - Bicycle robot of possible for exerciing management and driving method thereof - Google Patents

Abstract

The present invention is equipped with a weight sensor, a tilt sensor, and a hall sensor on the bicycle used for commuting and moving, and calculates the amount of exercise, strength and endurance of the bicycle user based on the information from these sensors to provide the user The present invention relates to a bicycle robot that enables a systematic movement using the commute and movement and its management.

Description

Bicycle Robot Of Possible For Exerciing Management And Driving Method Thereof}

The present invention relates to a bicycle robot capable of exercise management and a driving method thereof, comprising a weight sensor, a tilt sensor, and a hall sensor mounted on a bicycle used for commuting and moving, and based on information from these sensors. The present invention relates to a bicycle robot and a driving method thereof, which are capable of systematic exercise using commute and movement and the management thereof by calculating the amount of exercise of the exercise and providing the same to the user.

As the quality of life improved with the development of technology, modern people's interest changed from solving consciousness to living a healthy life. There are many ways to lead a healthy life, such as improving your diet, exercising, or eating dietary supplements.However, as health maintenance through exercise is considered the best, most modern people try to stay healthy through exercise. Doing. Accordingly, various exercise equipments such as treadmills and fitness bicycles have been developed, and modern people are trying to maintain their health by using them in the form of directly purchasing a treadmill or exercise equipment such as a fitness bicycle or using them in a health club.

However, modern people have neglected their exercise because they could not afford time to visit a health club equipped with exercise equipment due to living conditions or busy routines. In addition, even in the case of purchasing and using the exercise equipment directly, it is a reality that the exercise is neglected due to the inconvenience of preparing the use of the exercise equipment, including the provision of the exercise equipment.

Currently developed exercise equipment manages exercise such as checking user's exercise time in order to increase the user's exercise effect, and in the case of treadmill, improve exercise effect by adjusting exercise speed and inclination, In the case of a bicycle, it includes functions such as improving the exercise effect by adjusting the tension of the pedal. However, these functions are merely functions that are limited to the amount of exercise of the user, and most of them do not consider the health or fitness state of the user.

On the other hand, busy modern people are hard to find time for exercise, and the number of people exercising by commuting and moving by bicycle is increasing rapidly. In particular, the recent increase in oil prices, the rapid increase in the cost of moving through the car in consideration of health and costs together, the use of bicycles worldwide is increasing. However, the current bicycle, as well as the measurement of the amount of exercise, the reality is not equipped with a function for the exercise management through the amount of exercise and the user's fitness and health.

Accordingly, the bicycle robot capable of exercise management according to an embodiment of the present invention includes a weight measuring sensor for measuring a user's weight; A tilt measuring sensor for measuring an inclination angle between the uphill or the downhill and the bicycle when the driving bicycle drives uphill or downhill; Hall sensor for measuring the rotational speed per second of the running bicycle wheel; A system controller which calculates and manages an exercise amount of a user using data measured by the sensors; And a data display unit for displaying data output by the system control unit.

The bicycle robot capable of exercise management further includes a motor connected to the sprocket of the bicycle and driven according to a control signal from the system controller.

The system control unit includes a data input unit for receiving data measured by the sensors; An exercise amount calculator configured to calculate an exercise amount of a user by using the data output by the data input unit; An exercise amount management unit is configured to manage an exercise amount of a user using data output by the exercise amount calculation unit.

The exercise amount calculating unit calculates the exercise amount of the user using the total weight, the gravity acceleration, the change amount of the height of the bicycle, and the speed of the bicycle, which are the sum of the weight of the user and the weight of the bicycle.

The system control unit includes: a user designation input unit capable of designating a user who uses the initial bicycle for driving the bicycle; An individual exercise amount storage unit storing data output by the exercise amount management unit for each individual; An individual exercise habit storage unit for organizing and storing the pattern from the individual data output by the exercise amount management unit; The communication unit may further include a communication unit configured to transmit data managed by the exercise amount management unit through a communication network or input information received through the communication network to the exercise amount management unit.

The exercise robot that can manage the movement and the generator for generating electricity by the power of the rotation of the bicycle wheel; An energy storage unit for storing the electricity generated by the generator and supplying the stored electricity; A motor driving unit for driving the motor in accordance with the control signal from the system control unit is further provided.

According to an embodiment of the present invention, there is provided a driving method of a bicycle robot capable of managing exercise, the method comprising: setting energy consumption per predetermined time; Calculating a required exercise amount according to the set energy consumption amount; Calculating the amount of exercise of the user using the total weight, the acceleration of gravity, the change in height of the bike, and the speed of the bicycle, which are the sum of the weight of the user and the weight of the bicycle; Determining whether the calculated exercise amount of the user exceeds the required exercise amount; Driving the motor connected to the sprocket of the bicycle when the calculated exercise amount of the user exceeds the required exercise amount; If the calculated exercise amount of the user does not exceed the required exercise amount, determining whether the calculated exercise amount of the user is less than the required exercise amount; If the calculated exercise amount of the user is less than the required exercise amount, generating a generator to increase the resistance of the bicycle.

The energy consumption per fixed time may be set in a range, and when the energy consumption per fixed time is set in a range, the required exercise amount is calculated in a range.

The driving method of the bicycle robot capable of exercise management may include determining whether the calculated exercise amount of the user falls within a range of the required exercise amount; If the calculated exercise amount of the user is included in the range of the required exercise amount, the method further includes the step of returning to the step of setting the energy consumption per fixed time.

As described above, the bicycle robot and the driving method capable of exercise management according to an embodiment of the present invention, the weight of the user from the weight sensor, the slope from the uphill or downhill from the tilt sensor and the inclination of the bicycle, from the hall sensor Based on the speed of the bicycle, it calculates the user's exercise amount, strength exercise and endurance, and displays and manages it so that systematic exercise management is possible.

When the exercise amount set by the user reaches and stores the exercise amount set by the user in the storage unit, excessive exercise of the user can be prevented by driving the motor to drive electricity by driving the motor.

In addition, by setting and storing the energy consumption per fixed time in the storage unit and calculating the required exercise amount according to the set energy consumption amount, the motor is driven when the user's exercise amount exceeds the required exercise amount and the generator is generated when the user's exercise amount is less than the required exercise amount. This allows the user to drive the bicycle with a constant force.

In addition, it is applied to a bicycle robot that can actually drive, so that you can understand your own exercise habits by considering the exercise and health management of busy modern people, individual exercise habits and previous exercise amount, as well as identify exercise habits and By comparing the current amount of exercise and providing it, more systematic exercise is possible, and health care is also possible when considering individual health status.

Furthermore, by being applied to a bicycle robot that can actually run, it is effective in the use of exercise and health care time by busy modern people.

1 is a view schematically showing a bicycle robot capable of exercise management according to an embodiment of the present invention;
Figure 2 is a block diagram schematically showing a bicycle robot capable of exercise management according to an embodiment of the present invention,
3 is a flowchart illustrating a method of driving a bicycle robot capable of managing exercise according to an embodiment of the present invention;
4 is a block diagram schematically illustrating a bicycle robot capable of managing exercise according to another embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described with reference to FIGS. 1 to 4.

Referring to FIG. 1, a bicycle robot capable of exercise management according to an exemplary embodiment of the present invention includes a weight measuring sensor 10 measuring a user's weight, a tilt measuring sensor 11 measuring a tilt of a driving bicycle, Hall sensor 12 for measuring the speed of the bicycle running, the data display unit 20 for displaying information related to the user's movement, and the amount of exercise of the user based on the input of the sensors (10, 11, 12) It is provided with a system control unit 100 for calculating and managing it.

The weight measuring sensor 10 measures a user's weight, and is mainly installed under the saddle 2 to facilitate the user's weight measurement. The weight measuring sensor 10 is most preferably installed in the lower part of the saddle 2, but may be any place where the user's weight can be measured.

The inclination measuring sensor 11 measures the inclination between the uphill or the downhill and the bicycle when the bicycle travels uphill or downhill. If the bicycle is driving on a flat surface at 0 °, it is measured at a (+) angle when driving uphill based on 0 °, and at a minus (-) angle when driving downhill. The inclination measurement sensor 11 is preferably installed under the saddle 2 together with the weight measurement sensor 10, but may be any place as long as it can measure the inclination of the bicycle on the road. As the tilt measurement sensor 11, a gyro sensor or a tilt sensor may be used.

The hall sensor 12 is installed on a bicycle frame around the wheels 4 or on a wheel support in the center of the wheels 4 to measure the rotational speed of the wheels 4 per second to measure the speed of the bicycle being driven.

The system controller 100 may be configured based on information such as the weight of the user from the weight measuring sensor 10, the tilt of the bicycle being driven from the tilt measuring sensor 11, the speed of the bicycle being driven from the hall sensor 12, and the like. Calculate and manage your momentum. The system control unit 100 is most preferably installed in the handle 6 portion, but may be installed in the lower part of the saddle 2 together with the weight measurement sensor 10 and the tilt measurement sensor 11.

The data display unit 20 displays information related to the exercise of the user calculated and managed by the system control unit 100. The data display unit 20 is preferably provided in the handle 6 portion so that the user can easily see it.

Hereinafter, with reference to Figure 2 will be described with respect to the system control unit 100 of the bicycle robot capable of exercise management of the present invention.

The system controller 100 uses the data input unit 110 to which data measured by the weight measuring sensor 10, the tilt measuring sensor 11, and the hall sensor 12 are input, and the data output from the data input unit 110. The exercise amount calculating unit 120 for calculating the exercise amount of the user, the exercise amount managing unit 130 for managing the exercise of the user using the data output by the exercise amount calculating unit 120, and the individual amount output by the exercise amount managing unit 130. Personal exercise habit storage unit 140 for recording the individual exercise pattern, that is, habits through the data, and the individual exercise amount storage unit 150 for receiving the individual data output by the exercise amount management unit 130 and storing the exercise amount for each user do. The apparatus further includes a communication unit 160 which transmits the exercise state of the user managed by the exercise amount management unit 130 to the outside, or receives necessary information related to the exercise of the user from the outside and transmits the necessary information to the exercise amount management unit 130. .

The data input unit 110 may measure the weight of the user measured by the weight measuring sensor 10, the inclination of the running bicycle measured by the tilt measuring sensor 11 with the uphill or the downhill, and the driving bicycle measured by the hall sensor 12. Receives the speed of the output to the momentum calculation unit 120.

The exercise amount calculating unit 120 calculates the amount of exercise of the user by using the weight of the user input from the data input unit 110, the inclination and the speed at which the bicycle is running uphill or downhill.

The exercise amount calculation unit 120 calculates the total weight (M = m ₁ + m ₂ ), which is the sum of the user's weight m ₁ and the bicycle weight m ₂ through the weight measuring sensor 10. The amount of exercise (E) of the user is calculated using the inclination of the bicycle through the inclination measurement sensor 12 and the uphill or downhill and the speed through the hall sensor 11. The exercise amount E of the user can be regarded as the amount of work done by the user. Accordingly, the momentum calculation unit 120 of the present invention uses the amount of work (E ₁ ) the user did using the potential energy and the amount of work (E ₂ ) by the user using the kinetic energy as shown in Equation 1 Calculates the amount of work (E)

E ₁ = M × G × Δh

E ₂ = 1/2 × M × V ²

G = gravitational acceleration, △ h = height change, V = speed

At this time, the change amount Δh of the height of the bicycle is calculated as in Equation 2 from the inclination of the bicycle measured by the inclination measurement sensor 20 with the uphill or the downhill.

Δh = h _i -h _{i -1}

x = the inclination of the bicycle uphill or downhill measured by the tilt sensor

At this time, when the inclination measured by the inclination measuring sensor 20 is measured as a negative value or is changed from a positive value to a negative value, it is determined that the vehicle is driving downhill, and the speed when driving downhill is measured. Since the increase is not caused by the user's motion, but the speed increases because the potential energy is changed to the kinetic energy, the kinetic energy E ₁ is subtracted from the kinetic energy E ₂ as shown in Equation 3 Calculate

When driving uphill by judging by the inclination value measured by the inclination measurement sensor 20, the exercise amount calculation unit 120 increases the weight w for the strength exercise E _M as shown in Equation 4 so that the user's strength exercise Calculate

A is proportional constant

The weight is set to 1 when driving on a flat surface, and the weight is gradually increased as the slope of the ascent increases. For example, when the slope is 5 °, the weight is set to 1.2, and when the slope is 10 °, the weight is set to 1.4. In addition, the exercise amount calculation unit 120 further increases the weight for the strength exercise when running for a long time uphill, and increases the weight for the strength exercise of the user even when running for a long time at high speed and high speed. For example, the driving time on an uphill road will gradually increase the weight by 0.2 every 10 seconds over time if it exceeds 30 seconds and 0.2 to 0.5 km / h for speeds above 10 km / h. Gradually increase the weight, and if more than 5 minutes over 10km / h, the weight is gradually increased by 0.2 every 30 seconds. Here, examples of the weights may have individual differences, and are not limited to the above. In addition, the exercise amount calculation unit 120 increases the endurance of the user when driving the bicycle for a long time.

The individual exercise habit storage unit 140 receives the user's exercise amount, strength exercise, and endurance from the exercise amount management unit 130 to record the individual exercise pattern, that is, the exercise habit of the user. At this time, the present invention can determine a user (User) at the beginning of the driving of the bicycle, in order to store the individual exercise habits. To this end, the present invention includes a user designation input section 13 for designating a user, and the user designation input section 13 is arranged in the data display section 20 or the like.

The individual exercise amount storage unit 150 receives and stores the individual exercise amount, strength exercise, and endurance of the user from the exercise amount management unit 130.

The communicator 160 transmits the exercise state of the user managed by the exercise amount management unit 130 to the outside through a wireless or wired communication network, or receives necessary information related to the exercise of the user from the outside to receive the exercise amount management unit 130. To be sent).

When the initial driving user of the bicycle is determined, the exercise amount management unit 130 may read individual information from the individual exercise amount storage unit 150 and display the previous exercise amount through the data display unit 20. Thus, the user can compare his previous exercise amount and the current exercise amount. In addition, various types of information received through the communication unit 160 may be displayed through the data display unit 20. Then, by reading the individual exercise habit information from the individual exercise habit storage unit 140, and displayed on the data display unit 20 to enable the exercise with reference to this.

In the bicycle robot capable of exercise management according to the present invention, if the user sets the amount of exercise to be stored in any one of the storage units such as the individual exercise amount storage unit 150 or the individual exercise habit storage unit 140, the user's exercise amount The exercise amount management unit 130 determines whether the set exercise amount is reached by the comparing unit 32, and when the exercise amount of the user reaches the set exercise amount, the motor 35 is driven to drive the bicycle by electric power. do.

To this end, the bicycle robot capable of exercise management of the present invention includes a generator 50 for generating electricity by power of rotation of the wheel 4, an energy storage unit 40 for storing electricity generated by the generator 50, and The motor drive part 30 which drives the motor 35 by the control signal from the exercise amount management part 130, and the motor 35 which drives a bicycle by chaining and rotating with the sprocket 8 of a bicycle are provided.

The generator 50 generates electricity by generating power by rotating the wheel 4 that rotates while the bicycle is running. Although FIG. 1 shows an example in which power is obtained from a wheel 4 rotating in contact with the wheel 4, the generator 50 of the present invention is not limited thereto, and generates electricity by using the rotation of the wheel 4 as power. Any generator can be used.

When the control signal from the momentum management unit 130 is applied, the motor driver 30 receives electricity from the energy storage unit 40 and applies a driving force to the motor 35.

The motor 35 rotates when the driving force is applied from the motor driver 30 to rotate the sprocket 8 of the chain-connected bicycle so that the bicycle runs on electricity.

In addition, the bicycle robot capable of exercise management according to the present invention operates the motor 35 and the generator 50 while driving on a general road, such that the fitness bicycle applies a constant resistance to the pedals of the bicycle so that the user can exercise with a constant force. It is also possible to allow the user to drive the bicycle with a constant force.

Referring to FIG. 3, in the method of driving a bicycle robot capable of exercise management according to an exemplary embodiment of the present invention, a user first sets an energy consumption amount per predetermined time (S10). At this time, the energy consumption per fixed time is set in the range. For example, the energy consumption is set to consume 0.5 to 1 cal of energy per second. Then, the driving method of the bicycle robot capable of exercise management of the present invention calculates the energy that the user should consume according to the range of energy consumption set by the user, that is, the range of the required amount of exercise per second, for example (S20). At this time, the required amount of exercise can be obtained from the calorie and energy (J) 1cal = 4.185J.

Then, the driving method of the bicycle robot capable of exercise management of the present invention determines whether the user's real-time exercise amount calculated by the exercise amount calculation unit 120 is included in the range of the required exercise amount set by the user (S30). As a result of the determination in S30, if the real-time exercise amount of the user is included in the range of the requested exercise amount, it is determined that the user is exercising with a constant force and returns to S10. However, as a result of the determination in S30, if the real-time exercise amount of the user is not included in the range of the required exercise amount, it is determined whether the real-time exercise amount of the user is larger than the range of the required exercise amount (S40). As a result of the determination in S40, if the real-time exercise amount of the user is larger than the range of the required exercise amount, the driving method of the bicycle robot capable of exercise management of the present invention drives the motor 35 so that the user can exercise at the exercise amount within the required range (S45). ). In other words, in the method of driving a bicycle robot capable of exercise management according to the present invention, when the user is exercising at an exercise amount exceeding a required range, it is determined that the energy consumption is an uphill or the like, and the user drives the motor 35. Do not apply force beyond the set range. As a result of the determination in S40, if the real-time exercise amount of the user is not larger than the range of the required exercise amount, it is determined whether the real-time exercise amount of the user is smaller than the range of the required exercise amount (S50). As a result of the determination in S50, if the real-time exercise amount of the user is smaller than the range of the required exercise amount, the generator 50 is developed so that the user can exercise at the exercise amount in the required range (S55) and a resistance force is applied to the bicycle being driven. In other words, when the user is exercising at an exercise amount less than the required range, it is determined that the energy consumption amount is a downhill or the like, and the generator 50 is generated so that the user does not exert a force less than the required range. Therefore, the bicycle robot capable of exercise management of the present invention allows the bicycle to be driven with a constant force set by the user while driving on a general road.

In addition, the bicycle robot capable of managing exercise of the present invention may consider an individual health state and the like. Referring to FIG. 4, a bicycle robot capable of managing exercise according to another embodiment of the present invention includes an individual health state storage unit 170 and a second comparison unit 135 in which an individual health state is stored in the system controller 100. In addition, the second exercise unit 135 compares the current exercise amount of the user calculated by the exercise amount calculator 120 with the health state information stored in the individual health state storage unit 170. As a result of the comparison, if the current exercise amount of the user calculated by the exercise amount calculation unit 120 can cause harm to the user, the data display unit 20 warns this. For example, if the cardiopulmonary state of the user should not drive the bicycle for more than 10 minutes / 10km / h or more through the display unit 20 to warn. That is, the bicycle robot capable of exercise management of the present invention is capable of exercise and health management in consideration of individual health status. In this case, the individual health state information stored in the individual health state storage unit 170 may be directly stored, but may be received from the outside, for example, from a hospital through the communication unit 160. In addition, the bicycle robot capable of exercise management according to the present invention drives the motor 35 when the user cannot perform a sudden exercise such as driving on a path having a large inclination based on the stored health state information of the user and the bicycle is electric. It can also be driven by power.

2: saddle 4: wheels
6: handle 8: stroke
10: weight measurement sensor 11: tilt measurement sensor
12: Hall sensor 13: User input input unit
20: data display unit 30: motor drive unit
32: comparison unit, first comparison unit 35: motor
40: energy storage unit 50: generator
100: system control unit 110: data input unit
120: exercise amount calculation 130: momentum management unit
135: second comparison unit 140: individual exercise habit storage unit
150: individual exercise amount storage 160: communication unit
170: personal health state storage unit

Claims (9)

A weight measurement sensor for measuring a weight of the user;
A tilt measuring sensor for measuring an inclination angle between the uphill or the downhill and the bicycle when the driving bicycle drives uphill or downhill;
Hall sensor for measuring the rotational speed per second of the running bicycle wheel;
A system controller which calculates and manages an exercise amount of a user using data measured by the sensors;
And a data display unit displaying data output from the system control unit.
The method according to claim 1,
And a motor connected to the sprocket of the bicycle, the motor being driven in accordance with a control signal from the system controller.
The method according to claim 1,
The system control unit,
A data input unit for receiving data measured by the sensors;
An exercise amount calculator configured to calculate an exercise amount of a user by using the data output by the data input unit;
The exercise robot for exercise management, characterized in that it comprises an exercise amount management unit for managing the exercise amount of the user using the data output by the exercise amount calculation unit.
The method according to claim 3,
The momentum calculation unit,
A bicycle robot capable of calculating a user's exercise amount using a total weight, a gravity acceleration, a change amount of a height of a bicycle, and a speed of a bicycle, the sum of the weight of the user and the weight of the bicycle.
The method according to claim 3,
The system control unit,
A user designation input unit capable of designating a user who uses the bicycle at the beginning of driving of the bicycle;
An individual exercise amount storage unit storing data output by the exercise amount management unit for each individual;
An individual exercise habit storage unit for organizing and storing the pattern from the individual data output by the exercise amount management unit;
And a communication unit configured to transmit data managed by the exercise amount management unit through a communication network or to input information received through the communication network to the exercise amount management unit.
The method according to claim 2,
A generator for generating electricity by rotating the bicycle wheels;
An energy storage unit for storing the electricity generated by the generator and supplying the stored electricity;
And a motor driving unit for driving the motor in response to a control signal from the system control unit.
Setting an energy consumption per fixed time;
Calculating a required exercise amount according to the set energy consumption amount;
Calculating the amount of exercise of the user using the total weight, the acceleration of gravity, the change in height of the bike, and the speed of the bicycle, which are the sum of the weight of the user and the weight of the bicycle;
Determining whether the calculated exercise amount of the user exceeds the required exercise amount;
Driving the motor connected to the sprocket of the bicycle when the calculated exercise amount of the user exceeds the required exercise amount;
If the calculated exercise amount of the user does not exceed the required exercise amount, determining whether the calculated exercise amount of the user is less than the required exercise amount;
And if the calculated exercise amount of the user is less than the required exercise amount, generating a generator to increase the resistance of the bicycle.
The method according to claim 7,
The energy consumption per fixed time can be set in a range, and if the energy consumption per fixed time is set in a range, the required exercise amount is calculated as a range.
The method according to claim 8,
Determining whether the calculated exercise amount of the user falls within a range of the required exercise amount;
And if the calculated exercise amount of the user is included in the range of the required exercise amount, returning to the step of setting the energy consumption per predetermined time.

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