PEDAL CONNECTION MECHANISM AND ELECTRIC BALANCING VEHICLE USING THE SAME

Abstract

A pedal connection mechanism, includes a left and a right pedal, and a transverse connecting member. The first cylindrical shaft is provided along the bottom of the left pedal. The left side of the top wall of the transverse connecting member is provided with the first support member. The second cylindrical shaft is provided along the bottom of the right pedal. The right side of the top wall of the transverse connecting member is provided with the second support member. The present invention further provides an electric balancing vehicle using this pedal connection mechanism. The left pedal and the right pedal are not connected with each other through an intermediate shaft. Their motion statuses are controlled respectively by the left foot and the right foot independently. The transverse connecting member shares the weight of a human body. The force distributes evenly. The balancing vehicle is flexible and durable.

Claims

1. A pedal connection mechanism, comprising a left pedal, a right pedal, and a transverse connecting member, a first cylindrical shaft being transversely provided along a center of a bottom of the left pedal; a left side of a top wall of the transverse connecting member being provided with a first support member, the first support member being provided with a first recess matching the first cylindrical shaft; the first cylindrical shaft being provided inside the first recess, such that the left pedal is connected to the first support member in a rotatable manner; and a second cylindrical shaft being transversely provided along a center of a bottom of the right pedal; a right side of the top wall of the transverse connecting member being provided with a second support member, the second support member being provided with a second recess matching the second cylindrical shaft; the second cylindrical shaft being provided inside the second recess, such that the right pedal being connected to the second support member in a rotatable manner.

2. The pedal connection mechanism according to claim 1, wherein the first cylindrical shaft includes two transversely provided first cylinders, the two first cylinders being symmetrically provided on both sides of a bottom of the left pedal; correspondingly, the left side of the top wall of the transverse connecting member being provided with two first support members, the two first support members all being provided with a first recess matching the first cylinder; the left pedal being connected to the first support member in a rotatable manner; and wherein the second cylindrical shaft includes two transversely provided second cylinders, the two second cylinder symmetrically provided on both sides of a bottom of the right pedal; correspondingly, the right side of the top wall of the transverse connecting member being provided with two second support members, the two second support members all being provided with a second recess matching the second cylinder; the right pedal being connected to the second support member in a rotatable manner.

3. The pedal connection mechanism according to claim 1, further comprising a first resilient member and a second resilient member; one end the first resilient member being connected to the bottom of the left pedal, the other end thereof being connected to the left side of the top wall of the transverse connecting member correspondingly; one end of the second resilient member being connected to the bottom of the right pedal, the other end thereof being connected to the right side of the top wall of the transverse connecting member.

4. The pedal connection mechanism according to claim 3, wherein the first resilient member and the second resilient member are all springs.

5. The pedal connection mechanism according to claim 3, wherein a number of the first resilient members is four, one end of each of the four first resilient members respectively being connected to four corners of the bottom of the left pedal, the other end thereof being respectively connected to the left side of the top wall of the transverse connecting member correspondingly; and wherein a number of the second resilient members is four, one end of each of the four second resilient members respectively being connected to four corners of the bottom of the right pedal, the other end thereof respectively being connected to the right side of the top wall of the transverse connecting member correspondingly.

6. The pedal connection mechanism according to claim 1, wherein the transverse connecting member is a flat panel, wherein along a direction of a longitude of the flat panel, both sides of a middle portion thereof symmetrically inwardly recess.

7. An electric balancing vehicle using the pedal connection mechanism according to claim 1, comprising a housing, a pedal connection mechanism, a plurality of wheels, a plurality of motors, a plurality of sensing systems, at least one signal processor, and a power supply; an interior of the housing being provided with an accommodating cavity, a top surface thereof being provided with a first notch and a second notch that are bilaterally symmetrical with each other; the first notch matching the left pedal; the second notch matching the right pedal; the pedal connection mechanism being provided inside the accommodating cavity; wherein the left pedal is provided inside the first notch, the right pedal being provided inside the second notch; the plurality of wheels including a left wheel and a right wheel, both of which respectively being provided on a left side and a right side of the housing; the plurality of motors including a first motor and a second motor; the first motor being provided inside the left wheel, a power output terminal thereof being connected to a. left wheel drive; after receiving a signal transmitted from the signal processor, the first motor controlling a motion status of the left wheel; the second motor being provided inside the right wheel, a power output terminal thereof being connected to the right wheel drive; after receiving a signal transmitted from the signal processor, the first motor controlling a motion status of the right wheel; the plurality of sensing systems including a first sensing system and a second sensing system; the first sensing system being provided on a bottom of the left pedal, and in parallel with the left pedal; the second sensing system being provided on a bottom of the right pedal, and in parallel with the right pedal; the first sensing system including a first sensing element and at least one first touch sensing switch; the first sensing element sensing a motion status of the left pedal, a signal output terminal of the first sensing element being connected to a signal input terminal of the signal processor; a signal output terminal of the first touch sensing switch being connected to a signal input terminal of the first motor; the second sensing system including a second sensing element and at least one second touch sensing switch; the second sensing element sensing a motion status of the light pedal, a signal output terminal of the second sensing element being connected to a signal input terminal of the signal processor; a signal output terminal of the second touch sensing switch being connected to a signal input terminal of the second motor; the at least one data processor being provided inside the accommodating cavity, a signal input terminal of the data processor being connected to a signal output terminal of the sensing system, a signal output terminal of the data processor being connected to a signal input terminal of the motor; and the power supply being provided inside the accomodating cavity, providing energy for the electric balancing vehicle.

8. The electric balancing vehicle according to claim 7, wherein a number of the signal processor is one; wherein the first sensing element includes a first gyroscope and a first acceleration sensor; a signal output terminal of the first gyroscope being connected to a first signal input terminal of the signal processor; a signal output terminal of the first .acceleration sensor being connected to a second signal input terminal of the signal processor; and wherein the second sensing element includes a second gyroscope and a second acceleration sensor; a signal output terminal of the second gyroscope being connected to a third signal input terminal of the signal processor; a signal output terminal of the second acceleration sensor being connected to a fourth signal input terminal of the second signal processor.

9. The electric balancing vehicle according to claim 7, wherein a number of the signal processor is two, which are referred as a first signal processor and a second signal processor respectively; wherein the first sensing element includes a first gyroscope and a first acceleration sensor; a signal output terminal of the first gyroscope being connected to a first signal input terminal of the first signal processor; a signal output terminal of the first acceleration sensor being connected to the second signal input terminal of the first signal processor; and wherein the second sensing element includes the second gyroscope and the second acceleration sensor; a signal output terminal of the second gyroscope being connected to the first signal input terminal of the second signal processor, a signal output terminal of the second acceleration sensor being connected to the second signal input terminal of the second signal processor.

10. The electric balancing vehicle according to claim 7, wherein a number of the first touch sensing switch is two and wherein a number o the second touch sensing switch is two.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0035] FIG. 1 is a front view of a pedal connection mechanism provided by an embodiment of the present invention.

[0036] FIG. 2 is a left view of the pedal connection mechanism according to an embodiment of the present invention;

[0037] FIG. 3 is a right view of the pedal connection mechanism according to an embodiment of the present invention;

[0038] Reference symbols: 10, left pedal; 11, first cylindrical shaft; 12, first resilient member; 20, right pedal; 21, second cylindrical shaft; 22, second resilient member; 30, transverse connecting member; 31, first support member; 32, second support member.

[0039] Figures hereinafter are incorporated into the specification and constitute a part of the specification, showing embodiments in accordance with the present invention, together with the specification explaining the principle of the present invention.

DETAILED DESCRIPTION

[0040] Hereinafter, further detailed descriptions are made for the present invention through embodiments in conjunction with drawings.

[0041] As shown in FIG. 1, a pedal connection mechanism includes left pedal 10, right pedal 20, and transverse connecting member 30. First cylindrical shaft 11 is transversely provided along the center of the bottom of left pedal 10. The left side of the top wall of transverse connecting member 30 is provided with first support member 31. First support member 31 is provided with a first recess matching first cylindrical shaft 11. First cylindrical shaft 11 is provided inside the first recess, such that left pedal 10 is connected to first support member 31 in a rotatable manner. Second cylindrical shaft 21 is transversely provided along the center of the bottom of right pedal 20. The right side of the top wall of transverse connecting member 30 is provided with second support member 32. Second support member 32 is provided with the second recess matching second cylindrical shaft 21. Second cylindrical shaft 21 is provided inside the second recess, such that right pedal 20 is connected to second support member 32 in a rotatable manner.

[0042] Hereafter, the arrangement of this pedal connection mechanism is further illustrated.

[0043] First cylindrical shaft 11 includes two transversely provided first cylinders. The two first cylinders are symmetrically provided on both sides of the bottom of left pedal 10. Correspondingly, the left side of the top wall of transverse connecting member 30 is provided with two first support members 31. Two first support members 31 are all provided with the first recesses matching the first cylinders. Left pedal 10 is connected to first support member 31 in a rotatable manner. Second cylindrical shaft 21 includes two transversely provided second cylinders. The two second cylinders are symmetrically provided on both sides of the bottom of right pedal 20. Correspondingly, the right side of the top wall of transverse connecting member 30 is provided with two second support members 32. Two second support members 32 are all provided with the second recesses matching the second cylinders. Right pedal 20 is connected to second support member 32 in a rotatable manner.

[0044] Preferably, first resilient members 12 and second resilient members 22 are also included. One end of first resilient member 12 is connected to the bottom of left pedal 10, and the other end correspondingly is connected to the left side of the top wall of transverse connecting member 30. One end of second resilient member 22 is connected to the bottom of right pedal 20, and the other end thereof is correspondingly connected to the right side of the top wall of transverse connecting member 30. First resilient member 12 and second resilient member 22 may all be provided as springs, but not limited to springs, and can be provided as other suitable resilient members. The resilient member provides the user a certain buffer after stepping on the pedal, so as to improve the comfort level. The number of first resilient members 12 is four. One end of the four first resilient members 12 is connected to four corners of the bottom of left pedal 10 respectively, and the other end thereof is correspondingly connected to the left side of the top wall of transverse connecting member 30 respectively. The number of second resilient members 22 is four. One end of four second resilient members 22 is connected to four corners of the bottom of right pedal 20 respectively, and the other end thereof is correspondingly connected to the right side of the top wall of transverse connecting member 30.

[0045] Preferably, transverse connecting member 30 can be provided as a flat panel, along the longitudinal direction of the flat panel, both sides of the middle portion extend inwardly and symmetrically.

[0046] In the pedal connection mechanism provided by the embodiment of the present invention, the bottom of left pedal 10 and right pedal 20 is provided with transverse connecting member 30. Left pedal 10 and right pedal 20 is rotatably connected to transverse connecting member 30 respectively. Left pedal 10 and right pedal 20 are independent from each other. During the use of the balancing vehicle, the weight applied to the pedal by the human body is conveyed to transverse connecting member 30, such that transverse connecting member 30 bears the weight of the human body, and thus the force distributes evenly. This avoids the defect of the prior art, where the left and right pedals are connected through a middle shaft, and the middle shaft bears the weight of the human body, and therefore the middle shaft is likely to wear and even crack. Balancing vehicle made by the proposed pedal connection mechanism is reliable, safe, and durable. Moreover, this pedal connection mechanism not only can be used in a double-wheeled balancing vehicle, but also can be used in a three wheeled balancing, vehicle, a four-wheeled balancing vehicle, or other suitable types of vehicles. It has a wide range of applications, a high practical utility, and a great commercial prospect.

[0047] The present invention further provides an electric balancing vehicle using this pedal connection mechanism, which includes a housing, a pedal connection mechanism, wheels, motors, sensing system, at least one signal processor, and a power supply. The interior of the housing is provided with an accommodating cavity, and the top surface thereof is provided with the first notch and the second notch that are bilaterally symmetrical with each other. The first notch matches left pedal 10. The second notch matches right pedal 20. The pedal connection mechanism is provided within the accommodating cavity. Among others, left pedal 10 is provided inside the first notch, and right pedal 20 is provided inside the second notch. The wheels include a left wheel and a right wheel. They are provided on the left and right sides of the housing respectively. The motors include the first motor and the second motor. The first motor is provided within the left wheel, with its power output terminal being connected to the left wheel drive. After receiving the signal transmitted from the signal processor, the first motor controls the motion status of the left wheel. The second motor is provided within the right wheel, with its power output terminal being connected to the right wheel drive. After receiving the signal transmitted from the signal processor, the second motor controls the motion status of the right wheel. Sensing systems include a first sensing system and a second sensing system. The first sensing system is provided on the bottom of left pedal 10, and is provided in parallel with left pedal 10. Second sensing system 20 is provided on the bottom of right pedal 20, and is provided in parallel with right pedal 20. The first sensing system includes a first sensing element and at least one first touch sensing switch. The first sensing element senses the motion status of left pedal 10, with its signal output terminal being connected to the signal processor. The signal output terminal of the first touch sensing, switch is connected to the signal input terminal of the first motor. The second sensing system includes a second sensing element and at least one second touch sensing switch. The second sensing element sensing the motion status of right pedal 20, with its signal output terminal being connected to the signal input terminal of the signal processor. The signal output terminal of the second touch sensing switch is connected to the second signal input terminal of the second motor. At least one signal processor is provided within the accommodating cavity. The signal input terminal of the data processor is connected to the signal output terminal of the sensing system. The signal output terminal of the data processor is connected to the signal input terminal of the motor, The power supply is provided within the accommodating cavity, providing energy for the electric balancing vehicle.

[0048] Hereinafter, the arrangement of the sensing system and the signal processor are further illustrated.

[0049] The number of signal processor is one. The first sensing element includes the first gyroscope and the first acceleration sensor. A signal output terminal of the first gyroscope is connected to the first signal input terminal of the signal processor. A signal output terminal of the first acceleration sensor is connected to the second signal input terminal of the signal processor. The second sensing element includes the second gyroscope and the second acceleration sensor. A signal output terminal of the second gyroscope is connected to the third signal input terminal of the signal processor. A signal output terminal of the second acceleration sensor is connected to the fourth signal input terminal of the signal processor.

[0050] In another implementation, the number of signal processors is two. They are referred as the first signal processor and the second signal processor respectively. The first sensing element includes the first gyroscope and the first acceleration sensor. A signal output terminal of the first gyroscope is connected to the first signal input terminal of the first signal processor. A signal output terminal of the first acceleration sensor is connected to the second signal input terminal of the first signal processor. The second sensing element includes the second gyroscope and the second acceleration sensor. A signal output terminal of the second gyroscope is connected to the first signal input terminal of the second signal processor. A signal output terminal of the second acceleration sensor is connected to the second signal input terminal of the second signal processor.

[0051] In addition, the number of first touch sensing switches is two. The number of second touch sensing switches is two. One of first touch sensing switches and one of second touch sensing switches are spare switches. Providing spare switches is convenient and practical. Because they avoid such defect of only one switch that once the switch is broken the balancing vehicle cannot start up.

[0052] The working, principle of the electric balancing vehicle provided by the present invention is as follows:

[0053] During the operation of the electric balancing vehicle, when the user's left foot steps on left pedal 10, the first touch sensing is turned on. When the user's right foot steps on right pedal 20, the second touch sensing switch is turned on. While the user's left foot steps on left pedal 10, making left pedal 10 incline forwards or backwards, the first sensing system which is connected in parallel to the bottom of left pedal 10 inclines forwards or backwards along with left pedal 10. This time, the first sensing element detects the motion status of left pedal 10 constantly, and transmits the signal to the signal processor. The signal processor feeds back the signal to the first motor. The motion status of the left wheel is adjusted according to the power output of the first motor. On the other hand, while the user's right foot steps on right pedal 20, making right pedal 20 incline forwards or backwards, the second sensing system which is connected in parallel to the bottom of right pedal 20 inclines forwards or backwards along with right pedal 20. At this time, the second sensing element on the second sensing system detects the motion status of right pedal 20, and transmits the signal to the signal processor. The second signal processor feeds back the signal to the second motor. The motion status of the right wheel is adjusted according to the power output of the second motor. When the user steps hard on left pedal 10 and right pedal 20 to the forward simultaneously, the left wheel and the right wheel keep rolling forwards, and the balancing vehicle moves forwards. When the user steps hard on left pedal 10 and right pedal 20 to the backward simultaneously, the left wheel and the right wheel keep rolling backwards, and the balancing vehicle moves backwards. However, when the stepping motion of the user makes motion status of left pedal 10 and that of right pedal 20 inconsistent, the balancing vehicle will turn.

[0054] Meanwhile, the first sensing element and the second sensing element will feed back the swing magnitude of the user's body, such that the first motor and the second motor could obtain different power outputs, so as to adjust the velocity of the balancing vehicle.

[0055] For a person of ordinary skill in the art, other kinds of corresponding alternations and modifications can be made according to technical solutions and concepts described above. All of these alternations and modifications should belong to the scope of the claims of the present invention.