System and method for adjusting pressing feeling by seat belt

What is claimed is: 1 . A system for adjusting seat belt pressure, the system comprising: multiple markers attached at regular intervals on an outer surface of each of an upper webbing and a lower webbing; a body pressure sensor attached on an inner surface of each of the upper webbing and the lower webbing, the body pressure sensor configured to detect a body pressure applied to a passenger's body by each of the upper webbing and the lower webbing; a camera configured to photograph positions of at least some of the multiple markers, an upper webbing pull-out guiding D-ring, a buckle, and a lower webbing fixing body; a controller configured to determine whether the body pressure at a maximum protrusion point of each of the upper webbing and the lower webbing is greater than or equal to a reference pressure based on a captured signal of the camera and a detection signal of the body pressure sensor; and webbing pressure adjustment drive devices configured to be driven to relieve the body pressure to be less than the reference pressure based on a control signal of the controller in response to the body pressure at the maximum protrusion point being greater than or equal to the reference pressure, wherein the webbing pressure adjustment drive devices comprise: a buckle length and angle adjustment device configured to perform one of or both of moving up and down the buckle, and rotating the buckle in a width direction of a vehicle body; an upper webbing guide device configured to raise the upper webbing pulled out from the upper webbing pull-out guiding D-ring; a lower webbing position adjustment device configured to move the lower webbing fixing body up and down; and a retractor driving device configured to further pull out webbing wound inside a retractor by a selected length. 2 . The system of claim 1 , wherein the controller comprises: a webbing shape recognition part configured to determine a shape of each of the upper webbing and the lower webbing based on the captured signal of the camera; a webbing maximum protrusion point determination part configured to determine the maximum protrusion point of each of the upper webbing and the lower webbing based on the shape of each of the upper webbing and the lower webbing determined in the webbing shape recognition part; a maximum body pressure determination part configured to determine a maximum pressure point of each of the upper webbing and the lower webbing applied to the passenger's body based on the detection signal of the body pressure sensor; a body pressure comparison part configured to determine whether the maximum protrusion point of each of the upper webbing and the lower webbing and the maximum pressure point of each of the upper webbing and the lower webbing correspond to each other; and a driving device control part configured to command a drive control signal for relieving webbing pressure to at least one of the webbing pressure adjustment drive devices in response to the maximum protrusion point of each of the upper webbing and the lower webbing and the maximum pressure point of each of the upper webbing and the lower webbing corresponding to each other. 3 . The system of claim 2 , wherein the webbing shape recognition part is further configured to calculate an inclination of each of the multiple markers of each of the upper webbing and the lower webbing photographed by the camera, recognize markers with inclinations greater than an inclination of 0.5 among the multiple markers as points on the upper webbing, recognize markers with inclinations smaller than the inclination of 0.5 as points on the lower webbing, and to determine longitudinal trajectory and shape of each of the upper webbing and the lower webbing by connecting each of the points. 4 . The system of claim 2 , wherein the webbing maximum protrusion point determination part is further configured to determine points divided into quartiles on a longitudinal trajectory of each of the upper webbing and the lower webbing determined in the webbing shape recognition part, calculate vertical distances between the points and the camera, and determine a closest point of the points having a shortest vertical distance from the camera as a webbing maximum protrusion point. 5 . The system of claim 2 , wherein the controller is further configured to re-determine the maximum protrusion point of each of the upper webbing and the lower webbing and the maximum pressure point of each of the upper webbing and the lower webbing by determining, as an error, a situation in which the maximum protrusion point of each of the upper webbing and the lower webbing and the maximum pressure point of each of the upper webbing and the lower webbing do not correspond to each other. 6 . The system of claim 1 , wherein the buckle length and angle adjustment device comprises: a hollow lifting bar connected to a lower side of the buckle; a support bar having an upper part inserted into the lifting bar and having a lower part rotatably coupled to the vehicle body; a first motor connected to a rotation shaft of the support bar; a rack formed on a side part of the lifting bar; a second motor mounted on a side of the support bar; and a pinion being connected to an output shaft of the second motor and engaged with the rack. 7 . The system of claim 1 , wherein the upper webbing guide device comprises: the upper webbing pull-out guiding D-ring mounted on a webbing entrance formed on a side panel inside a vehicle and configured such that the upper webbing pulled out from the retractor is guided in a direction of the webbing worn by the passenger; a second motor mounted under the webbing entrance; and a webbing guide connected rotatably to an output shaft of the second motor and configured to move up the upper webbing pulled out from the webbing entrance. 8 . The system of claim 1 , wherein the lower webbing position adjustment device comprises: a guide hole with a first length formed in a vertical direction on a side panel inside a vehicle; the lower webbing fixing body connected to an end part of the lower webbing; an up/downward movement block extending from a rear surface part of the lower webbing fixing body and arranged to be movable up and down inside the guide hole; and an actuator mounted inside the side panel, wherein a plunger of the actuator is connected to a lower side of the up/downward movement block. 9 . The system of claim 1 , wherein the retractor driving device comprises: the retractor having a drum on which webbing is wound to be pulled out; and a third motor mounted on a side part of the retractor, wherein an output shaft of the third motor is connected to a drum shaft of the drum. 10 . A method for adjusting seat belt pressure, the method comprising: photographing positions of multiple markers attached on each of an upper webbing and a lower webbing, an upper webbing pull-out guiding D-ring, a buckle, and a lower webbing fixing body by using a camera; detecting a body pressure applied to a passenger's body by each of the upper webbing and the lower webbing by a body pressure sensor attached on an inner surface of each of the upper webbing and the lower webbing; determining whether the body pressure at a maximum protrusion point of each of the upper webbing and the lower webbing is greater than or equal to a reference pressure based on a captured signal of the camera and a detection signal of the body pressure sensor; driving at least one of webbing pressure adjustment drive devices so that the body pressure at the maximum protrusion point is relieved to be less than the reference pressure in response to the body pressure at the maximum protrusion point being greater