Patent Publication Number: US-2017363429-A1

Title: Two-wheel electric vehicle

Description:
FIELD OF INVENTION 
     The present invention relates to the field of electric vehicles, and more particularly to a two-wheel electric vehicle having a gyroscope device. 
     BACKGROUND 
     The related background technologies of the present invention are described below; however, these descriptions do not necessarily constitute the prior art of the present invention. 
     Nowadays, environmental pollution becomes increasingly severe, energy supply becomes limited and inadequate, and traffic congestion occurs more and more often. Green, low-carbon, lightweight, and miniaturized vehicles gradually become a new trend in the development of the industry and become increasingly popular among travelers. 
     A two-wheeled vehicle appeared in 1914, which has a front wheel and a rear wheel and implements left-right balance by means of a mechanical gyroscope, so that stability as that of a normal four-wheeled vehicle is provided, that is, the vehicle does not fall when being static. As compared with a conventional four-wheeled vehicle, a two-wheeled vehicle not only changes people&#39;s driving habits, but also has a lighter weight and a smaller volume and is therefore more energy-saving. However, because control of a mechanical gyroscope is relatively complex, requirements on components such as a microprocessor, a motor, and a sensor are also relatively high, and in addition, there are more safety problems; therefore, in the past century, two-wheel electric vehicles have not made substantial breakthroughs. Many two-wheel electric vehicles that have been developed at present basically all have problems such as undesirable stability, slow start of a gyroscope, and a limited turning capability, and therefore fail to achieve commercial scale up. 
     In fact, there are many types of two-wheel vehicles, for example, a normal motorcycle and a scooter, which can provide higher efficiency than conventional four-wheel car. However, the efficiency mainly comes from physical differences between a two-wheeled vehicle and a four-wheeled car, for example, a reduced weight, a relatively small friction area, and a reduced resistance. In addition, due to factors such as influence by a weather condition, for example, wind, a safety problem when a crash accident occurs, and that stability of a vehicle must be kept during the use of the vehicle, many users are not willing to or cannot use a motorcycle instead of a vehicle as a vehicle. 
     A solution for protecting a user (driver) of a two-wheeled vehicle from influence by bad weather and heavy wind is usually limited to: A device, for example, a windshield that can protect the driver from external influence is used for partial shielding, to allow the user to use one leg or two legs to help stabilize the vehicle when the vehicle is static or runs at a low speed, that is, two feet of the driver can directly contact the ground. In addition, there are some other solutions in the prior art, for example, one in which an enclosed cab is used on a two-wheeled vehicle; however, because the solution does not use an additional wheel to stabilize a vehicle, the vehicle may be unable to stand stably in some states. 
     Research on stabilizing a vehicle by using a gyroscope may be traced back to about a hundred years ago. However, because of problems such as complexity and safety of a gyroscope system, for a solution to a problem of stability in high-speed steering of a two-wheeled vehicle, so far there is no product of a commercial scale. 
     SUMMARY 
     An objective of the present invention is to provide a two-wheel electric vehicle, including a gyroscope device. The gyroscope device can enable a two-wheel electric vehicle to keep balance of a body when the two-wheel electric vehicle is static but a power supply is not turned off, for example, within a period of a wait at a traffic light, within a period during which the vehicle runs at a low speed, and within a period during which the vehicle steers. 
     According to an aspect of the present invention, the present invention provides a two-wheel electric vehicle, including: a frame; a housing connected to the frame; one front wheel and one rear wheel each connected to the frame; a gyroscope device connected to the frame, the gyroscope device including a flywheel; and a control system, the control system controlling a precession angular speed of the flywheel within a period during which the two-wheel electric vehicle is started but does not run, a period during which the two-wheel electric vehicle runs normally or a period during which the two-wheel electric vehicle steers, to keep balance of a body of the two-wheel electric vehicle. 
     According to another aspect of the present invention, in the two-wheel electric vehicle, there is one gyroscope device and only one flywheel is included. 
     According to another aspect of the present invention, in the two-wheel electric vehicle, there are two gyroscope devices, each gyroscope device includes one flywheel, and the two gyroscope devices are disposed in a manner of being symmetrical relative to a longitudinal axis of the frame. 
     According to another aspect of the present invention, the control system includes a microprocessor, an electronic gyroscope, an angle sensor, and low-speed motor controller, when the vehicle tilts in a transverse direction because of an external force, the electronic gyroscope reads a tilt angle of the body, the angle sensor reads the precession angular speed of the flywheel, and the microprocessor determines, based on the tilt angle and the precession angular speed, a magnitude and a direction of the precession angular speed of the flywheel that are required to keep the balance of the body, and outputs the magnitude and the direction to the low-speed motor controller, so as to keep the balance of the body by controlling a precession of the flywheel. 
     According to another aspect of the present invention, the control system includes a microprocessor, an electronic gyroscope, and an angle sensor, when the vehicle steers, the electronic gyroscope reads a tilt angle in a transverse direction and an angular speed of the vehicle during steering and a centripetal acceleration of the vehicle, the angle sensor reads the precession angular speed of the flywheel, and the microprocessor determines a required magnitude and direction of the precession angular speed of the flywheel based on the tilt angle, the angular speed, the centripetal acceleration, and the precession angular speed and outputs the magnitude and direction to the low-speed motor controller, so as to keep the balance of the body by controlling a precession of the flywheel. 
     According to another aspect of the present invention, the control system includes a microprocessor, an electronic gyroscope, an angle sensor, and a low-speed motor controller, when the vehicle tilts in a transverse direction because of an external force, the electronic gyroscope reads a tilt angle of the body, the angle sensor reads precession angular speeds of the two flywheels, and the microprocessor determines, based on the tilt angle and the precession angular speeds, magnitudes and directions, of the precession angular speeds of the two flywheels, required to keep the balance of the body of the vehicle and outputs the magnitudes and directions to the low-speed motor controller, so as to keep the balance of the body by controlling precessions of the two flywheels. 
     According to another aspect of the present invention, the control system includes a microprocessor, an electronic gyroscope, an angle sensor, and a low-speed motor controller, when the vehicle steers, the electronic gyroscope reads a tilt angle in a transverse direction and an angular speed of the vehicle during steering and a centripetal acceleration of the vehicle, the angle sensor reads precession angular speeds of the flywheels, and the microprocessor determines required magnitudes and directions of the precession angular speeds of the two flywheels based on the tilt angle, the angular speed, the centripetal acceleration, and the precession angular speeds and outputs the magnitudes and directions to the low-speed motor controller, so as to keep the balance of the body by controlling precessions of the two flywheels. 
     According to another aspect of the present invention, when the vehicle steers, the microprocessor further determines an angle value of a tilt which the body of the vehicle should generate in a transverse direction, and the angle value can enable the vehicle to use a component, in the transverse direction of a gravity, generated from the tilt of the body to cancel a centrifugal force or an external force in the transverse direction which is generated during steering of the vehicle, to enable the body of the vehicle to keep a balanced state. 
     According to another aspect of the present invention, the control system includes two groups of low-speed motor controllers. 
     According to another aspect of the present invention, the period during which the two-wheel electric vehicle is started but does not run is for example, a period of a wait for a green light at a crossing, and another period of emergency braking. 
     According to the two-wheel electric vehicle of the present invention, because one or two gyroscope devices are provided, within a period during which the vehicle is started but does not run, for example, during a wait for a green light at a crossing, when the vehicle comes under an effect of an external force during normal driving, and when the vehicle steers, an effect of the one or two gyroscope devices can be used to implement balance of a body of the vehicle in a transverse direction, that is, a left-right direction of the vehicle, thereby working out a technical problem existing in the prior art that a two-wheel electric vehicle has undesirable stability. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The features and advantages of the present invention will become clearer by reading the embodiments provided with reference to the accompanying drawings, where in the accompanying drawings: 
         FIG. 1  is a schematic view of an embodiment in which a two-wheel electric vehicle has one gyroscope device according to the present invention; 
         FIG. 2  is a schematic view of a control system of the two-wheel electric vehicle having one gyroscope device according to the present invention; 
         FIG. 3  is a schematic view of one gyroscope device of the two-wheel electric vehicle having one gyroscope device according to the present invention, in which a flywheel is shown; 
         FIG. 4  is a schematic view of another embodiment in which a two-wheel electric vehicle has two gyroscope devices according to the present invention; 
         FIG. 5  is a schematic view of a control system of the two-wheel electric vehicle having two gyroscope devices according to the present invention; 
         FIG. 6  is a schematic view of two gyroscope devices of the two-wheel electric vehicle having two gyroscope devices according to the present invention, in which two flywheels are shown; and 
         FIG. 7  is a schematic exploded view of one gyroscope device according to the present invention. 
     
    
    
     DETAILED DESCRIPTION OF EMBODIMENTS 
     The exemplary implementations of the present invention are described below in detail with reference to the accompanying drawings. The descriptions of the exemplary implementations are merely used for illustrative purposes, and do not constitute any limitation to the application or usage of the present invention. 
     As discussed above, for an prior art two-wheel electric vehicle, balance in a transverse direction, that is, a left-right direction of the vehicle is basically implemented by means of a mechanical gyroscope. However, because control of a mechanical gyroscope is relatively complex, requirements on components such as a microprocessor, a motor, and a sensor are also relatively high, and in addition, more safety problems are involved; therefore, many prior art two-wheel electric vehicles substantially all have problems such as undesirable stability, slow speed of start of a gyroscope, and a limited turning capability, and therefore fail to achieve commercial scale up. 
       FIG. 1  is a schematic structural view of a two-wheel electric vehicle having one gyroscope device according to the present invention. Hereinafter, for simplicity, the “two-wheel electric vehicle” is generally referred to as a “vehicle”. The two-wheel electric vehicle includes: a frame  1 , a housing  3 , a front wheel  2 , a rear wheel  6 , a gyroscope device  5 , a steering wheel  4 , a seat  7 , an auxiliary wheel  8 , a battery group  9 , and a control system  10 . The housing  3  is connected to the frame  1 , and the front wheel  2  and the rear wheel  6  are also both connected to the frame  1 . The gyroscope device  5  may be fixed, from the bottom, on the frame  1  in a detachable manner by using a connecting piece such as a bolt. Certainly, the gyroscope device  5  may also be attached, from the bottom, to the frame  1  in a manner of fixed connection such as welding. A location of the gyroscope device  5  on the frame  1  is preferably a location in the middle along a longitudinal direction of the frame  1 , but is not limited thereto. Similarly, the control system  10  may also be fixed on the frame  1  in a detachable manner by using a connecting piece such as a bolt. Certainly, the control system  10  may also be attached to the frame  1  in a manner of fixed connection such as welding. 
       FIG. 2  is a brief schematic view of the control system  10  of the two-wheel electric vehicle having one gyroscope device in  FIG. 1 . The control system  10  includes: a power supply, an attitude controller, a high-speed motor controller, a high-speed motor, a low-speed motor controller, a low-speed motor, and the like. The attitude controller includes: an electronic gyroscope, a microprocessor, and an angle sensor. 
       FIG. 3  is a schematic view of one gyroscope device  5  of the two-wheel electric vehicle having one gyroscope device according to the present invention. A flywheel  13  is connected to the low-speed motor  11 . 
     Operations of the two-wheel electric vehicle having one gyroscope device are described below in detail. 
     Before the vehicle is started, two auxiliary wheels  8  extend to contact the ground and are at working locations, so as to assist the front wheel  2  and the rear wheel  6 , to enable the two-wheel electric vehicle to be balanced and stand still on the ground. 
     After the vehicle is started, the gyroscope device  5  is started by means of the high-speed motor and begins to run. The flywheel  13  of the gyroscope device  5  is in an axial rotation state by means of the high-speed motor. Once the vehicle runs, the two auxiliary wheels  8  are retracted and are at non-working locations, and in this case, the vehicle contacts the ground by means of only the front wheel and the rear wheel. Within a period during which the vehicle normally runs, when the vehicle is subjected to an external force and tilts in a transverse direction, that is, in a left-right direction of the vehicle, the electronic gyroscope detects an angle at which a body tilts in the transverse direction and a value of an angular speed of the vehicle, and transfers the angle and the value of the angular speed to the microprocessor. The angle sensor also reads a precession angular speed of the flywheel  13  and transfers the precession angular speed to the microprocessor. The microprocessor calculates, according to these values, a magnitude and a direction of a torque required to keep transverse balance of the body of vehicle, and converts the magnitude and the direction into a required magnitude and direction of the precession angular speed of the flywheel  13 , and subsequently the microprocessor sends an instruction to the low-speed motor controller according to the required magnitude and direction of the precession angular speed. The low-speed motor controller drives the low-speed motor  11 , so as to control the precession angular speed and a direction of the flywheel  13 , to enable the flywheel  13  to generate a torque with the required direction and magnitude to keep balance of the body of vehicle, thereby keeping the balance of the body of vehicle. 
     Within a period during which the vehicle is started but does not run, for example, in a case of a wait for a green light at a crossing or another case of emergency braking, that is, the vehicle does not turn off the power supply but stops running, in this case, the auxiliary wheels  8  are still at non-working locations. In a case of support with only the front wheel  2  and the rear wheel  6 , the body of the vehicle also tilts in a transverse direction. When the body tilts, the electronic gyroscope in the control system detects an angle at which the body tilts in a transverse direction and an angular speed of the vehicle, and the electronic gyroscope then transfers the angle at which the body tilts in the transverse direction and a value of the angular speed of the vehicle to the microprocessor. The angle sensor reads the precession angular speed of the flywheel  13  and transfers the precession angular speed of the flywheel  13  to the microprocessor. The microprocessor calculates, according to these values, a magnitude and a direction of a torque required to keep the balance of the body of the vehicle. Subsequently, the microprocessor calculates a required magnitude and direction of the precession angular speed of the flywheel  13  according to a moment of inertia of the flywheel  13 , a rotational speed of the flywheel  13 , and the torque required to keep balance, and subsequently sends an instruction to the low-speed motor controller according to the required magnitude and direction of the precession angular speed, to drive the low-speed motor  11 , so as to control a magnitude and a direction of the precession angular speed of the flywheel  13 , to enable the flywheel  13  to generate a torque with the required direction and magnitude to keep the balance of the body of the vehicle, thereby keeping the balance of the body of the vehicle. 
     When the vehicle steers during running, the vehicle is subjected to an external force and the body tilts in a transverse direction, and in this case the electronic gyroscope of the control system detects an angle at which the body tilts in the transverse direction, an angular speed of the vehicle, and a centripetal acceleration of the vehicle, and transfers the angle, the angular speed, and the centripetal acceleration to the microprocessor. The angle sensor reads the precession angular speed of the flywheel  13  and transfers the precession angular speed to the microprocessor. The microprocessor calculates, according to these values, an angle value of a tilt that the body of the vehicle should generate in the transverse direction, where the angle value can enable the vehicle to use a component, in the transverse direction of a gravity, generated from the tilt of the body to cancel the centrifugal force generated during steering of the vehicle or the external force in the transverse direction, so that the body keeps a balanced state. The microprocessor subsequently converts the value into a required magnitude and direction of the precession angular speed of the flywheel  13 , and sends an instruction to the low-speed motor controller, to drive the low-speed motor  11  to control a magnitude and direction of the precession angular speed of the flywheel  13 , to enable the gyroscope device  5  to generate a torque with the required direction and magnitude to enable the vehicle to keep balance, thereby keeping the balance of the body. 
     When the vehicle is subjected to an external force, for example, gravity, wind, and a crash and tilts in a transverse direction, the electronic gyroscope detects an angle at which the body tilts in a transverse direction and an angular speed of the vehicle and transfers the angle and the angular speed to the microprocessor. The angle sensor reads the precession angular speed of the flywheel and transfers the precession angular speed to the microprocessor. The microprocessor calculates, according to the angle at which the body of the vehicle tilts, the angular speed, and the precession angular speed of the flywheel, a direction and a magnitude of a torque that the gyroscope device  5  is required to output to enable the body of the vehicle to restore a standing state. Similarly, the microprocessor sends an instruction to the low-speed motor controller based on the result, to enable the low-speed motor to drive the flywheel  13 , so as to enable the gyroscope device  5  to generate a torque with the required direction and magnitude to keep balance of the vehicle, thereby keeping balance of the body of the vehicle. 
     A magnitude of a torque generated by the gyroscope device is directly proportional to the moment of inertia of the flywheel  13 , the rotational speed of the flywheel  13 , and the precession angular speed of the flywheel. 
     Specifically, the moment of inertia of the flywheel may be calculated by using the following formula: 
     A flywheel moment M generally represents one amount of rotational inertia of a mechanical system. 
         M=GD̂ 2 
     G: Equal to an equivalent weight of a load in a motor traction system (that is, a total weight of a load is equivalent to the weight of one mass point at one end of an inertia radius). 
     D: An inertia diameter. 
     An equivalence relationship between a moment of inertia of the system and the flywheel moment is: J=(GD̂2)/4 g 
     A torque that can be generated by a gyroscope device is calculated by using the following formula: 
         T=J*ω 1*ω2
 
     T: Equal to a torque generated by the gyroscope device 
     J: The moment of inertia of the flywheel 
     ω1: A rotational speed of the flywheel 
     ω2: A torsional speed of the flywheel 
     A required torsional speed of the flywheel may be calculated according to a height of a center of mass and a weight of the vehicle 
       ω2= T /( J*ω 1)
 
     In an embodiment of the present invention, a designed weight of the flywheel is 50 kg, the moment of inertia is 0.36 kg·m 2 , a rotational speed of the flywheel is 12000 revolutions (1256 radian/second). A torsional speed of the flywheel that can be provided by the motor is 300 revolutions (31.4 radian/second). The gyroscope device may provide a torque of about 14000 NM. 
       FIG. 4  is a schematic view of a two-wheel electric vehicle with two gyroscope devices according to the present invention. As shown in  FIG. 4 , in a case in which double gyroscope devices are used, preferably, two gyroscope devices  5 A and  5 B are disposed in a manner of being symmetrical relative to a longitudinal axis X of the vehicle; however, the present invention is not limited thereto. In addition, the structure of the vehicle is similar to the foregoing structure with one gyroscope device, and therefore is no longer elaborated herein. 
       FIG. 5  shows the gyroscope devices  5 A and  5 B of the two-wheel electric vehicle with two gyroscope devices, and the gyroscope devices  5 A and  5 B respectively include flywheels  13 A and  13 B. The flywheels  13 A and  13 B are respectively connected to motors  11 A and  11 B. 
       FIG. 6  is a schematic view of a control system of the two-wheel electric vehicle with two gyroscope devices. As can be seen in  FIG. 6 , the control system includes a power supply, an attitude controller, two groups of high-speed motors I and II and high-speed motor controllers I and II, two groups of low-speed motors I and II and low-speed motor controllers I and II, and the like. The attitude controller includes: an electronic gyroscope, a microprocessor, and an angle sensor I, and an angle sensor II. 
     Operations of the two-wheel electric vehicle with two gyroscope devices are described below in detail. For simplicity, hereinafter, the two-wheel electric vehicle is generally referred to as a “vehicle”. 
     Before the vehicle is started, two auxiliary wheels  8  extend to contact the ground and at working locations, so as to assist a front wheel  2  and a rear wheel  6 , to enable the vehicle to be balanced and stand still on the ground. 
     After the vehicle is started, the control system  10  first begins to work. The microprocessor outputs a signal to the high-speed motor controller I and the high-speed motor controller II, to respectively start the high-speed motor I and the high-speed motor II. The flywheels  13 A and  13 B of the two gyroscope devices  5 A and  5 B start by means of the high-speed motor I and the high-speed motor II, to be in an axial rotation state. When the high-speed motors I and II reach set rotational speeds, the high-speed motor controller I and the high-speed motor controller II feed back signals to the microprocessor. The microprocessor outputs a control signal to the low-speed motor controller I and the low-speed motor controller II, to drive the low-speed motor I and the low-speed motor II to work. The low-speed motor I and the low-speed motor II begin to work, and in this case, the two auxiliary wheels  8  are retracted and are at non-working locations. The flywheels  13 A and  13 B of the gyroscope devices  5 A and  5 B generate precession motion by means of the low-speed motors I and II. 
     When the vehicle is subjected to an effect of a gravity, a manipulative force of a driver or another external force to tilt in a transverse direction, the electronic gyroscope of the control system detects an angle at which the vehicle tilts in a transverse direction and an angular speed and transfers the angle and the angular speed to the microprocessor. The angle sensors I and II respectively read precession angular speeds of the flywheels  13 A and  13 B and transfer the precession angular speeds to the microprocessor. The microprocessor calculates, based on the foregoing data, magnitudes and directions, of the precession angular speeds of the flywheels  13 , required to keep balance of a body of the vehicle. The microprocessor then outputs a control signal to the low-speed motor controller I and the low-speed motor controller II, and the low-speed motor controller I and the low-speed motor controller II control the low-speed motor I and the low-speed motor II, so as to control magnitudes and directions of the precession angular speeds of the flywheels  13 A and  13 B, to enable the gyroscope devices  5 A and  5 B to generate torques with the required magnitudes and directions, thereby keeping the balance of the body of the vehicle. 
     When the vehicle stops to wait for a green light at a crossing, that is, the vehicle does not turn off the power supply but stops running, the vehicle tilts in a transverse direction. The electronic gyroscope detects an angle at which the body of the vehicle tilts in the transverse direction and a value of an angular speed and transfers the angle and the value of the angular speed to the microprocessor. The angle sensors I and II respectively read the precession angular speeds of the flywheels  13 A and  13 B and transfer the precession angular speeds to the microprocessor. The microprocessor further calculates, according to these values, torques required to keep the balance of the body of the vehicle. The microprocessor calculates required magnitudes and directions of the precession angular speeds of the flywheels  13 A and  13 B according to moments of inertia of the flywheels  13 A and  13 B, the precession angular speeds, and the torques required to keep the balance of the body of the vehicle, and subsequently sends instructions to the low-speed motor controller I and the low-speed motor controller II according to the required magnitudes and directions of the precession angular speeds, to drive the low-speed motor I and the low-speed motor II, so as to control magnitudes and directions of the precession angular speeds of the flywheels  13 A and  13 B, to enable the gyroscope devices  5 A and  5 B to generate torques with corresponding magnitudes and directions, to keep the balance of the body of the vehicle. 
     When the vehicle steers and tilts during run, the electronic gyroscope detects an angle at which the body of the vehicle tilts in a transverse direction, an angular speed of the vehicle, and a centripetal acceleration of the vehicle. The angle sensors I and II respectively read precession angular speeds of the flywheels  13  and transfer the precession angular speeds to the microprocessor. The microprocessor calculates, according to the foregoing data, torques required to steer the vehicle. Specifically, the microprocessor calculates an angle value of a tilt that the body should generate in the transverse direction, where the angle value can enable the vehicle to use a component, in the transverse direction of a gravity, generated from the tilt of the body to cancel a centrifugal force generated during steering of the vehicle or an external force in the transverse direction, so that the body keeps a balanced state. The microprocessor outputs a signal to the low-speed motor controller I and the low-speed motor controller II, and the low-speed motor controller I and the low-speed motor controller II control the low-speed motor I and the low-speed motor II to operate, to drive the flywheels  13 A and  13 B to perform precessions of corresponding directions and magnitudes, so as to enable the gyroscope devices  5 A and  5 B to generate torques which enables the body of the vehicle to tilt in the transverse direction, to enable the vehicle to keep a tilted state during steering. The microprocessor adjusts magnitudes and directions of the precession angular speeds of the flywheels  13  according to a speed of the vehicle during steering, the angle at which the body tilts in the transverse direction, and the angular speed, to enable the body to stay in a stable tilted state. When detecting that the vehicle restores a straight-run state from a steering state, the control system then correspondingly adjusts the magnitudes and directions of the precession angular speeds of the flywheels  13 , to enable the body to restore straight-run balanced states. 
     It should be noted that the two-wheel electric vehicle of the present invention may also use three or more gyroscope devices, of which effects and principles are similar to those introduced above. However, a single gyroscope device and double gyroscope devices are undoubtedly the most efficient from a manufacturing cost to energy consumption. 
     Assembly of a structure of a gyroscope device with a flywheel is described below in detail. 
     As shown in  FIG. 7 , a gyroscope device  5  includes a flywheel  13 . A shaft on two ends of the flywheel is connected to bearings  12 . The flywheel of which the two ends are connected to the bearings is first mounted in a flywheel front cover  20 , and a flywheel rear cover  14  is then installed on the axially connected bearing on the other surface of the flywheel. The flywheel front cover  20  and the flywheel rear cover  14  are tightened by using a bolt. A flywheel connection flange  16  is connected to the shaft of the flywheel at one side of the flywheel front cover by using a bolt. A motor connection flange  17  is connected to the high-speed motor  18  by using a bolt. The high-speed motor connection flange  17  connected to the high-speed motor is connected to the flywheel connection flange  16  by using a bolt. A motor cover  19  is connected to a motor by using a bolt, and the motor cover  19  is then rotated to a suitable angle, to align a hole of the motor cover  19  with a bolt hole of the flywheel front cover  20 , and the motor cover  19  is connected to the flywheel front cover  20  by using a bolt. 
     A flywheel cover upper flange  25  is connected, by using a bolt, above the installed flywheel cover, and a flywheel cover lower flange  15  is connected under the installed flywheel cover. Bearings are respectively installed on the flywheel cover upper flange  25  and the flywheel cover lower flange  15 . 
     A support right cover plate  22  and a support left cover plate  24  are connected on a support lower cover plate  23  by using a bolt. An assembled flywheel box lower bearing is aligned with a bearing step hole of the support lower cover plate  23  for installation and fitting. A support upper cover plate  21  is installed at a location of a flywheel box upper bearing, and the support upper cover plate  21  is then connected to the support right cover plate  22  and the support left cover plate  24  by using a bolt. A motor  11  is connected to the flywheel cover upper flange  25 , and the motor is then connected to the support upper cover plate  25  by using a bolt. Here, assembly of the gyroscope device is completed. 
     About the terms, the “transverse direction” herein refers to a left-right direction of a body of a vehicle, that is, a width direction of the vehicle, and the “longitudinal direction” refers to a front-rear direction of the body of the vehicle, that is, a length direction of the vehicle. 
     Although the present invention is described with reference to the exemplary embodiments, it should be understood that the present invention is not limited to the specific embodiments described and shown in the specification. A person skilled in the art can make various changes to the exemplary embodiments without departing from the scope limited in the claims, and all these changes fall within the protection scope of the present invention.