Smart handlebar for utility vehicles

What is claimed is: 1 . A utility vehicle configured for transporting goods, the utility vehicle comprising: a chassis; wheels mounted to the chassis; a housing mounted to the chassis, the housing configured for storing the goods therein during transport; a motor configured to drive the wheels; a handlebar extending into a chassis sleeve defined by the chassis, the handlebar slidably moveable forward and backward within the chassis sleeve; a sensor including a flexible member having a first end mounted to the chassis sleeve and a second end mounted to the handlebar, the sensor configured to sense a magnitude and a direction of a force exerted on the handlebar by an operator; and a control module in communication with the sensor and the motor, the control module configured to control motor speed and motor direction of the motor based on the magnitude and the direction of the force exerted on the handlebar by the operator as sensed by the sensor, wherein the flexible member is a deflection beam extending along an axial center of the handlebar. 2 . The utility vehicle of claim 1 , wherein the first end of the flexible member is fastened to a chassis stand-off mount within the chassis sleeve, and the second end of the flexible member is fastened to a handlebar standoff mount within the handlebar. 3 . The utility vehicle of claim 1 , wherein the flexible member includes a first strain gauge proximate to the first end and a second strain gauge proximate to the second end. 4 . The utility vehicle of claim 3 , wherein: the flexible member further includes a third strain gauge proximate to the first end and a fourth strain gauge proximate to the second end; and the first strain gauge, the second strain gauge, the third strain gauge, and the fourth strain gauge are connected in a Wheatstone bridge circuit. 5 . The utility vehicle of claim 1 , wherein at an interface between the handlebar and the chassis sleeve, one of the chassis sleeve and the handlebar is oval in cross-section, and the other of the chassis sleeve and the handlebar is circular in cross-section. 6 . The utility vehicle of claim 5 , wherein cooperation between the handlebar and the chassis sleeve at the interface permits horizontal movement of the handlebar forward and backward, and restricts vertical movement of the handlebar upward and downward relative to the chassis sleeve. 7 . The utility vehicle of claim 5 , wherein: at the interface between the handlebar and the chassis sleeve, the handlebar is round in cross-section and the chassis sleeve is oval in cross-section; the handlebar directly abuts the chassis sleeve at a top and a bottom of the interface to restrict vertical movement of the handlebar upward and downward; and a front gap is defined between the handlebar and the chassis sleeve at a front of the interface, and a rear gap is defined between the handlebar and the chassis sleeve at a rear of the interface, to permit horizontal movement of the handlebar forward and backward. 8 . The utility vehicle of claim 1 , wherein: the handlebar includes an enabling switch configured to sense physical contact with the operator, the enabling switch is in cooperation with the control module; and the control module is configured restrict operation of the motor without physical contact with the operator sensed by the enabling switch. 9 . The utility vehicle of claim 1 , further comprising a velocity sensor configured to measure velocity of the utility vehicle, the velocity sensor is in cooperation with the control module; wherein the control module is configured to: measure acceleration of the utility vehicle based on the velocity measured by the velocity sensor; identify a loaded mass of the utility vehicle based on the measured acceleration and the magnitude of the force exerted on the handlebar as sensed by the sensor; identify a payload mass of a payload of the utility vehicle equal to a difference between the loaded mass and an unloaded mass of the utility vehicle; and generate an alert to the operator when the payload mass exceeds a predetermined threshold. 10 . A utility vehicle configured for transporting goods, the utility vehicle comprising: a chassis; wheels mounted to the chassis; a motor configured to drive the wheels; a housing mounted to the chassis, the housing configured for storing the goods therein during transport; a handlebar extending into a chassis sleeve defined by the chassis, one of the chassis sleeve and the handlebar is oval in cross-section and the other of the chassis sleeve and the handlebar is circular in cross-section, cooperation between the handlebar and the chassis sleeve permits horizontal movement of the handlebar forward and backward, and restricts vertical movement of the handlebar upward and downward; a strain gauge load cell sensor configured to sense a magnitude and a direction of a force exerted on the handlebar by an operator, the strain gauge load cell sensor including a deflection beam extending along an axial center of the handlebar, the deflection beam including a first end and a second end opposite to the first end, the first end is mounted to the chassis and the second end is mounted to the handlebar; and a control module in communication with the strain gauge load cell sensor and the motor, the control module configured to control motor speed and motor direction of the motor based on the magnitude and the direction of the force exerted on the handlebar by the operator as sensed by the strain gauge load cell sensor. 11 . The utility vehicle of claim 10 , wherein the deflection beam includes a first strain gauge, a second strain gauge, a third strain gauge, and a fourth strain gauge connected in a Wheatstone bridge circuit. 12 . The utility vehicle of claim 10 , wherein: the handlebar includes an enabling switch configured to sense physical contact with the operator, the enabling switch is in cooperation with the control module; and the control module is configured restrict operation of the motor without physical contact with the operator sensed by the enabling switch. 13 . The utility vehicle of claim 10 , further comprising a velocity sensor configured to measure velocity of the utility vehicle, the velocity sensor is in cooperation with the control module; wherein the control module is configured to: measure acceleration of the utility vehicle based on the velocity measured by the velocity sensor; identify a loaded mass of the utility vehicle based on the measured acceleration and the magnitude of the force exerted on the handlebar as sensed by the strain gauge load cell sensor; identify a payload mass of a payload of the utility vehicle equal to a difference between the loaded mass and an unloaded mass of the utility vehicle; and generate an alert to the operator when the payload mass exceeds a predetermined threshold. 14 . A utility vehicle configured for transporting goods, the utility vehicle comprising: a chassis; wheels mounted to the chassis; a motor configured to drive the wheels; a housing mounted to the chassis, the housing configured for storing the goods therein during transport; a handlebar extending into a chassis sleeve defined by the chassis, the handlebar is moveable forward and backward within the chassis sleeve; a strain gauge load cell sensor configured to sense a magnitude and a direction of a force exerted on the handlebar by an operator; a control module in communication with the strain gauge load cell sensor and the motor, the control module configured to control motor speed and motor direction of the motor based on the mag