Seat belt force sensor
First Claim
Patent Images
1. A force-sensing mechanism (20) comprising:
- a housing (22, 24);
a plate (26) axially movable in relation to the housing along a first axis;
a magnetic sensor assembly including a magnet sensor (230) and a magnet (252) relatively movable to one another, on the first axis, in response to forces applied to the housing and to the plate;
a spring assembly (250) having one end in operative engagement with the plate and another end in operative engagement with the housing to provide a bias force, directed along the first axis to resist movement of the plate in response to forces applied thereto; and
an adjustment mechanism operatively connected between the housing and the plate, in colinear alignment with the first axis, to enable the calibration of the sensor and calibration of the force of the spring assembly (250).
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Accused Products
Abstract
A force-sensing mechanism (20) comprising: a housing having first (22) and second (24) housing members; a slidable plate positioned between plate portions of the first and second housing members and moveable thereto; various spacers located between the first housing member and the sliding plate to space and stabilize the plate relative to the first and second housing members; a magnetic sensor stationarily mounted between the first and second housing members, a magnet moveable with the sliding member in response to forces applied to the first and second housing members and to the sliding plate; a spring assembly (250) having one end in operative engagement with the sliding plate and another end in operative engagement with the housing while biasing the sliding plate within the housing. An adjustment mechanism (350) is used to assist in the calibration of the bias force acting between the housing members and the sliding plate.
18 Citations
14 Claims
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1. A force-sensing mechanism (20) comprising:
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a housing (22, 24);
a plate (26) axially movable in relation to the housing along a first axis;
a magnetic sensor assembly including a magnet sensor (230) and a magnet (252) relatively movable to one another, on the first axis, in response to forces applied to the housing and to the plate;
a spring assembly (250) having one end in operative engagement with the plate and another end in operative engagement with the housing to provide a bias force, directed along the first axis to resist movement of the plate in response to forces applied thereto; and
an adjustment mechanism operatively connected between the housing and the plate, in colinear alignment with the first axis, to enable the calibration of the sensor and calibration of the force of the spring assembly (250). - View Dependent Claims (2, 3, 4, 5, 6, 13)
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7. A force-sensing mechanism (20) comprising:
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a housing (22, 24);
a plate (26) slidably movable in relation to the housing;
a magnetic sensor assembly including a magnet sensor (230) and a magnet (252) relatively movable to one another in response to forces applied to the housing end to the plate;
a spring assembly (250) having one end in operative engagement with the plate and another end in operative engagement with the housing to provide a bias force to resist movement of the plate; and
an adjustment mechanism operatively connected between the housing and the plate to enable the calibration of the sensor;
wherein the housing includes;
first (22) and second (24) housing members, each of the first and second housing members including respective plate portions (28), which are spaced apart; and
whereinthe plate (26) is positioned between the plate portions of the first and second housing members and moveable thereto;
first and second spacers (150), a first spacer received between the first housing member and the plate and a second spacer received between the second housing member and the plate to space and stabilize the plate relative to the first and second housing members, the first and second spacers are received within corresponding apertures (112a,b) of the sliding plate 26;
third and fourth spacers (180) positioned between the first and second housing members, each of the third and fourth spacers including a longitudinal slot (182) thereon to receive a corresponding portion of the plate, each of the third and fourth spacers including slots (184) that are oriented generally perpendicular to the direction of movement of the sliding plate. - View Dependent Claims (8, 9, 10, 11)
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12. A force-sensing mechanism (20) comprising:
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a housing having first (22) and second (24) housing members;
a slidable plate positioned between plate portions of the first and second housing members and moveable thereto;
various spacers located between the first housing member and the sliding plate to space and stabilize the plate relative to the first and second housing members;
a magnetic sensor stationarily mounted between the first and second housing members, a magnet moveable with the sliding plate in response to forces applied to the first and second housing members and to the sliding plate;
a spring assembly (250) having one end in operative engagement with the sliding plate and another end in operative engagement with the housing while biasing the sliding plate within the housing; an adjustment mechanism operatively connected between the first and second housing members and colinear with the spring assembly and magnetic sensor to the calibration of a response force of the spring assembly (250).
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14. A force-sensing mechanism (20) comprising:
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a housing (22, 24);
a plate (26) axially movable in relation to the housing, along a first axis;
a Hall effect sensor for generating an output signal and a magnet (252) for producing a magnetic field, the Hall effect sensor and the magnet relatively movable one to the other along the first axis, in response to axially directed forces applied to the housing and to the plate, the sensor generating a first level of output signal when no external axial forces are applied to the housing or to the plate;
a spring assembly (250) having one end in operative engagement with the plate and another end in operative engagement with the housing to provide a bias force, along the first axis, to resist movement of the plate in response to axial forces applied thereto; and
an adjustment mechanism operatively connected between the housing and the plate to adjust the relative placement of the Hall effect sensor and magnet to null the output of the Hall effect sensor with no such axial forces applied, the adjustment mechanism having a bearing surface coupled to the spring assembly which is configured to adjust the biasing force of the spring assembly (250) along the first axis.
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Specification
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Current AssigneeKey Safety Systems, Inc. (Ningbo Junsheng Investment Group Co., Ltd.)
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Original AssigneeKey Safety Systems, Inc. (Ningbo Junsheng Investment Group Co., Ltd.)
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InventorsGrzic, Rudi
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Primary Examiner(s)Garber, Charles D.
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Application NumberUS10/104,215Publication NumberTime in Patent Office977 DaysField of Search738/623.91, 731/59, 738/26, 738/623.92, 738/623.93, 73/11.5, 701/45US Class Current73/1.15CPC Class CodesB60R 2022/1806 for bucklesB60R 2022/4841 for sensing belt tensionB60R 21/01544 detecting seat belt paramet...B60R 21/0155 sensing belt tensionB60R 22/16 using belts which become pe...B60R 22/18 Anchoring devicesB60R 22/1952 Transmission of tensioning ...B60R 22/48 Control systems, alarms, or...G01L 5/101 using sensors inserted into...G01L 5/103 using sensors fixed at one ...G01L 5/108 for measuring a reaction fo...
