Seat belt retractor having a comfort mechanism with full memory and slack set

An apparatus comprising a spindle on which belt webbing is wound. The spindle is supported for rotation in belt retraction and belt withdrawal directions. The spindle is biased to rotate in the belt retraction direction. The apparatus also includes a manually movable member. The spindle is rotated in the belt withdrawal direction in response to movement of the manually movable member to pay out a predetermined amount of belt webbing from the spindle. Thereafter, rotation of the spindle in the belt retraction direction is blocked.

BACKGROUND OF THE INVENTION 
1. Technical Field 
The present invention relates to a seat belt retractor for use in a 
vehicle. Particularly, the present invention relates to a seat belt 
retractor having a comfort mechanism to eliminate the force exerted by 
seat belt webbing against a vehicle occupant. 
2. Description of the Prior Art 
Seat belt retractors having comfort mechanisms for eliminating the force 
exerted by seat belt webbing against a vehicle occupant are known. One 
such seat belt retractor is disclosed in U.S. Pat. No. 3,682,412. The seat 
belt retractor disclosed in U.S. Pat. No. 3,682,412 includes seat belt 
webbing wound on a spool. The spool is supported for rotation in belt 
withdrawal and belt retraction directions. A return spring biases the 
spool to rotate in the belt retraction direction. The biasing force of the 
return spring tends to pull the belt webbing against the occupant, which 
may cause discomfort to the occupant. To avoid causing such discomfort, 
the retractor includes a comfort mechanism which, when actuated, blocks 
rotation of the spool in the belt retraction direction so the belt webbing 
is not pulled against the occupant. 
The comfort mechanism disclosed in U.S. Pat. No. 3,682,412 is manually set. 
When the belt webbing is withdrawn from the spool and buckled around the 
occupant, the return spring rotates the retractor spool in the belt 
retraction direction to pull the belt webbing against the vehicle 
occupant. The vehicle occupant then withdraws the belt webbing a 
relatively small amount to establish slack in the webbing and actuates the 
comfort mechanism by moving a handle. Rotation of the spool in the belt 
retraction direction is then blocked and the slack in the belt established 
by the occupant is maintained. 
In a nonemergency situation, if the occupant moves forward from an initial 
position, the slack in the belt webbing is taken up and the webbing is 
withdrawn from the spool and follows movement of the occupant. When the 
occupant moves back to the initial position, the spool rotates in the belt 
retraction direction, due to the bias of the return spring, to a position 
in which the slack in the belt webbing is reestablished. Thus, the 
retractor has a "memory" so that the amount of slack in the belt webbing 
set by the occupant is reestablished. The comfort mechanism includes a 
ratchet wheel connected to the spool. A pawl is pivotable into engagement 
with a tooth on the ratchet wheel to block rotation of the spool in the 
belt retraction direction. After slack is established in the webbing, the 
handle is manually moved to pivot the pawl into engagement with a tooth on 
the ratchet wheel. A spring is connected at one end to the pawl and at its 
other end to a shaft. When the belt webbing is withdrawn, for example, due 
to movement of the occupant forward from the seat back, gears rotate the 
shaft in one direction and the spring pivots the pawl away from engaging 
the tooth on the ratchet wheel. When the belt webbing then retracts onto 
the spool, the gears rotate the shaft in an opposite direction and the 
spring pivots the pawl toward the ratchet wheel to engage the tooth it 
previously engaged on the ratchet wheel and to reestablished the slack. 
SUMMARY OF THE INVENTION 
The seat belt retractor of the present invention includes a spindle on 
which belt webbing is wound. The spindle is supported for rotation in belt 
retraction and belt withdrawal directions. The spindle is biased to rotate 
in the belt retraction direction. The seat belt retractor of the present 
invention also includes a comfort mechanism which includes a manually 
movable member which when moved (i) effects rotation of the retractor 
spindle to pay out a predetermined amount of belt webbing to establish 
slack in the belt webbing and (ii) actuates the comfort mechanism to block 
the spindle from rotating in the belt retraction direction. The comfort 
mechanism has a "memory" which enables the predetermined amount of slack 
in the belt webbing to be reestablished in the event the occupant moves 
forward and the slack is taken up. 
The comfort mechanism of the present invention includes a member supported 
for movement relative to the spindle and a mechanism which when actuated 
blocks movement of the member. A latch is carried by the member. The latch 
is movable relative to the member between a first position blocking 
rotation of the spindle in the belt retraction direction and a second 
position enabling rotation of the spindle in the belt retraction 
direction. 
A stub shaft is connected to and rotatable with the spindle. A groove in 
the stub shaft receives a portion of the latch to block rotation of the 
stub shaft and, thus, the spindle in the belt retraction direction. The 
latch is moved away from the stub shaft during rotation of the spindle and 
stub shaft in the belt withdrawal direction through an angular 
displacement. Upon rotation of the spindle and stub shaft in a belt 
retraction direction through the same angular displacement, the latch 
moves into the groove in the stub shaft to block further rotation of the 
spindle and stub shaft in the belt retraction direction. The member 
supported for movement relative to the spindle is preferably a drum 
rotatably mounted on the stub shaft connected to the spindle. An elongate 
spring is carried by the drum and connected to the stub shaft adjacent the 
groove. The elongate spring winds onto the stub shaft during rotation of 
the spindle and stub shaft in the belt withdrawal direction. The spring 
also engages the latch to move the latch in a direction away from the 
groove in the stub shaft. During subsequent revolutions of the spindle and 
stub shaft, the elongate spring covers the groove to prevent the latch 
from entering the groove. When the spindle and stub shaft rotate in the 
belt retraction direction, the elongate spring unwinds from the stub shaft 
until the groove is uncovered to permit the latch to enter the groove. 
Rotation of the spindle in the belt retraction direction is blocked at the 
same position at which the slack was set by the vehicle occupant. Thus, 
the retractor has a "memory" so that the slack in the belt webbing set by 
the vehicle occupant is reestablished. 
A plurality of teeth extend from the drum. A movable pawl member connected 
with the manually movable member has a portion for engaging one of the 
plurality of teeth on the drum. When the pawl member engages one of the 
plurality of teeth on the drum and moves in one direction, belt webbing is 
paid out to establish the predetermined amount of slack in the belt. When 
the pawl member engages one of the plurality of teeth on the drum and is 
blocked from movement, rotation of the drum in the belt retraction 
direction is blocked.

DESCRIPTION OF A PREFERRED EMBODIMENT 
FIG. 1 illustrates a seat belt retractor 20 for use in an automotive 
vehicle. The seat belt retractor 20 includes a spool or spindle 22. A pair 
of stub shafts 32, 34 are connected to the spindle 22 and extend from 
axially opposite ends of the spindle. Each of the stub shafts 32, 34 is 
received in an opening in a respective side 36a, 36b of a frame 36 to 
support the spindle 22 for rotation. The spindle 22 is rotatable in a belt 
retraction direction 28 and a belt withdrawal direction 30. An opening 38 
in the frame 36 receives a fastener (not shown) to connect the retractor 
20 to the vehicle. 
Seat belt webbing 24 is connected at one end to the spindle 22 and is wound 
on the spindle for storage. The belt webbing 24 is extendible about an 
occupant of the vehicle. A return spring 42 biases the spindle 22 to 
rotate in the belt retraction direction 28 tending to pull the belt 
webbing 24 against the vehicle occupant. The return spring 42 has one end 
portion 44 connected top spring cover 46 which is attached to the frame 
side 36b. Another end portion 48 of the return spring 42 is connected to 
the stub shaft 34. 
Two ratchet wheels 52 are connected to the spindle 22, one adjacent each 
frame side 36. A plurality of ratchet teeth 54 extend radially outwardly 
from each of the ratchet wheels 52 and are equally spaced about the outer 
periphery of the ratchet wheel. A pawl 62 extends between and is supported 
for pivotal movement by the sides 36a, 36b of the frame 36. A 
pendulum-type inertia member 64 is supported for pivotal movement by a 
beam 66 extending between the sides 36a, 36b of the frame 36 adjacent the 
pawl 62. The inertia member 64 pivots relative to the beam 66 in response 
to acceleration or deceleration of the vehicle at a rate above a 
predetermined rate, as is known. 
Upon pivotal movement of the inertia member 64, an upper portion 68 of the 
inertia member engages the pawl 62 and pivots the pawl towards the ratchet 
wheels 52. A ratchet tooth 54 on each of the ratchet wheels 52 engages the 
pawl 62 to block the spindle 22 from rotating in the belt withdrawal 
direction 30. It should be apparent that any known type of locking system 
may be used in the retractor 20 to prevent rotation of the spindle 22 in 
the belt withdrawal direction 30 in an emergency situation. 
The retractor 20 also includes a comfort mechanism 72 (FIG. 2) located 
adjacent the frame side 36a. When actuated, the comfort mechanism 72 
blocks rotation of the spindle 22 in the belt retraction direction 28 so 
the belt webbing is not pulled against the occupant by the spring 42. The 
comfort mechanism 72 includes a ratchet member or drum 74 supported for 
rotation by the stub shaft 32. A plurality of radially outwardly 
projecting teeth 76 are equally spaced about the outer periphery of the 
drum 74. The drum 74 also has an inner cylindrical surface 78 (FIG. 1) and 
a recessed planar surface 80 that extends radially from the inner 
cylindrical surface 78 toward the stub shaft 32. 
The comfort mechanism 72 also includes a hook-shaped pawl member 82 (FIG. 
2), which is supported for reciprocating movement by a portion 84 of the 
frame 36. The pawl member 82 is movable in a direction generally 
tangential to the outer periphery of the drum 74. The shorter leg 92 of 
the pawl member 82 is resiliently deflectable and movable toward and away 
from the drum 74. An end portion 94 of the leg 92 is engageable with one 
of the plurality of teeth 76 on the drum 74. The end portion 96 of the 
longer leg of the pawl member 82 is connected to one end portion of an 
elongate member 102. Axial movement of the member 102, thus, moves the 
pawl member 82. 
The other end portion of the member 102 is connected to a manually movable 
member or button 104. The button 104 is supported for reciprocating 
movement in a frame 106 which is connectable with the vehicle. The button 
104 may be located remotely from the retractor 20. The button 104 is 
biased by a spring 112 upwardly, as viewed in FIG. 2. The spring 112 
biases the elongate member 102 and the pawl member 82 to a position in 
which the pawl member 82 engages a tooth 76 on the drum 74, as illustrated 
in FIG. 2, to block the drum from rotating in the belt retraction 
direction 28. 
A latch 122 is supported for pivotal movement by a pivot pin 124 extending 
axially away from the surface 80 of the drum 74. A spring 126 biases the 
latch 122 to pivot towards the stub shaft 32. A groove 132 (best seen in 
FIG. 3) is formed in the outer surface of the stub shaft 32. The groove 
132 extends in a direction generally parallel to the longitudinal central 
axis A (FIG. 1) of the spindle 22 and stub shaft 32. The groove 132 
receives an end portion 134 of the latch 122. When the end portion 134 of 
the latch 122 engages a radially extending surface 136 of the groove 132 
and the drum 74 is blocked from rotating, the spindle and stub shaft 32 
are blocked from rotating in the belt retraction direction 28. 
A spool 142 is supported on another pin 144 extending axially away from the 
surface 80 of the drum 74. The spool 142 is rotatable about the pin 144. 
The outer diameter of the spool 142 is smaller than the outer diameter of 
the stub shaft 32. An elongate flexible spring member 152, such as a known 
Negator spring manufactured by Hunter Spring Company, of Lansdale, 
Pennsylvania, is connected at one end to the spool 142 and at its other 
end to the stub shaft 32 adjacent the groove 132. The spring member 152 is 
baised to wind onto the spool 142, and thus biases the drum 74 to rotate 
in the belt withdrawal direction 30 about the stub shaft 32. 
When the belt webbing 24 is fully retracted onto the spindle 22, the parts 
are in the position illustrated in FIG. 2. In use, the occupant withdraws 
the belt webbing 24 from the retractor 20. When the belt webbing 24 is 
withdrawn, the spindle 22 and stub shaft 32 rotate in the belt withdrawal 
direction 30, from the position illustrated in FIG. 2. The drum 74 is 
blocked from rotation by the pawl member 82 and thus the spindle 22 and 
stub shaft 32 rotate in the belt withdrawal direction 30 relative to the 
drum 74. When the drum 74 is blocked from rotating by the pawl member 82 
and the stub shaft 32 rotates in the belt withdrawal direction 30, the 
spring member 152 winds off the spool 142 and onto the stub shaft 32. 
When the spring member 152 winds onto the stub shaft 32, a portion 154 
(FIG. 3) of the spring member 152 engages the end portion 134 of the latch 
122 and moves the end portion of the latch out of the groove 132 in the 
stub shaft 32. During rotation of the spindle 22 and stub shaft 32 in the 
belt withdrawal direction 30 through subsequent revolutions, the spring 
member 152 covers the groove 132 so the latch 122 cannot enter the groove, 
as illustrated in FIG. 9. The spindle 22 and stub shaft 32 rotate a 
sufficient number of times so that a portion of the belt webbing 24 
extends about the upper torso of the occupant and a tongue carried by the 
belt webbing is secured to a buckle, in a known manner. The return spring 
42 then biases the spindle 22 and stub shaft 32 to rotate in the belt 
retraction direction 28 and the parts take a position such as illustrated 
in FIG. 3. At this time the belt webbing 24 is pulled against the upper 
torso of the occupant by return spring 42 and the spindle 22 and stub 
shaft 32 stop rotating in the belt retraction direction 28. To actuate the 
comfort mechanism 72, the button 104 is manually depressed to the position 
illustrated in FIG. 4. Depressing the button 104 forces the elongate 
member 102 to move downwardly and, in turn, forces the end portion 94 of 
the pawl member 82 to move in a direction away from the drum 74. The end 
portion 94 of the pawl member 82 disengages a tooth, such as tooth 76a 
(FIG. 3), on the drum 74. The drum 74 is then free to rotate due to the 
bias of the spring member 152. The drum 74 rotates relative tot he stub 
shaft 32 in the belt withdrawal direction 30, from the position 
illustrated in FIG. 4 to the position illustrated in FIG. 5. The spring 
member 152 unwinds from the stub shaft 32 during rotation of the drum 74 
in the belt withdrawal direction 30 to uncover the groove 132. The end 
portion 134 of the latch 122 enters the groove 132 in the stub shaft 32. 
The occupant then releases the button 104. The button 104, elongate member 
102 and pawl member 82 move upwardly from their positions shown in FIG. 5 
to the positions shown in FIG. 6, due to the bias of the spring 112. The 
end portion 94 of the pawl member 82 again engages a tooth 76 on the drum 
74. The force of the spring 112 biasing the button 104, elongate member 
102 and pawl member 82 upwardly is greater than the force of the return 
spring 42 tending to rotate the drum 74 in the belt retraction direction 
28. Thus, the pawl member 82 moves further upwardly after engaging the 
drum 74 to the position illustrated in FIG. 7. During movement of the pawl 
member 82 from the position illustrated in FIG. 6 to the position 
illustrated in FIG. 7, the pawl member rotates the drum 74, latch 134, 
stub shaft 32 and spindle 22 in the belt withdrawal direction 30 an 
arcuate distance of approximately 30.degree.. This rotation of the drum 
74, stub shaft 32 and spindle 22 in the belt withdrawal 30 direction pays 
out a predetermined amount of belt webbing 24 to establish slack in the 
belt webbing. 
Stops 162 on the frame 106 block the button 104, elongate member 102 and 
pawl member 82 from moving upwardly beyond the position illustrated in 
FIG. 7. The pawl member 82 now blocks the drum 74 from rotating in the 
belt retraction direction 28. The stub shaft 32 and the spindle 22 are 
also blocked from rotating in the belt retraction direction 28 because the 
end portion 134 of the latch 122 is received in the groove 132. Thus, the 
force of the return spring 42 does not act through the belt webbing 24 and 
against the occupant. 
Movement by the occupant, during nonemergency situations, in a generally 
forward direction from an initial position a sufficient amount causes the 
belt webbing 24 to be withdrawn from the retractor 20. When the belt 
webbing 24 is withdrawn, the spindle 22 and stub shaft 32 rotate in the 
belt withdrawal direction 30 from the position illustrated in FIG. 7 to a 
position such as illustrated in FIG. 8. During this movement, the latch 
122 is moved out of engagement with the groove 132 by the portion 154 of 
the spring member 152. The spindle 22 and stub shaft 32 may rotate further 
in the belt withdrawal direction 30 a plurality of revolutions until the 
seat belt webbing 24 is fully extended. During subsequent revolutions of 
the spindle 22 and stub shaft 32 in the belt withdrawal direction 30, 
other portions 156 (FIG. 9) of the spring member 152 extending over the 
groove 132 prevent the latch 122 from reentering the groove 132. 
When the occupant then moves back to the initial position, the spindle 22 
and stub shaft 32 rotate in the belt retraction direction 28 due to the 
bias of the return spring 42. The spring member 152 unwinds from the stub 
shaft 32 and onto spool 142, and the end portion 134 of the latch 122 is 
again received in the groove 132 so rotation of the spindle 22 and stub 
shaft 32 in the belt retraction direction 28 is again blocked. When this 
occurs, the amount of slack initially established in the belt webbing 24 
is reestablished. Thus, the retractor 20 has a "memory" which enables the 
slack set by the occupant to be reestablished. 
In an alernate embodiment of the present invention, not illustrated, push 
button 104 could be replaced by an electric actuator, such as a motor to 
push and pull the elongate member 102. The motor could be controlled 
remotely through the use of electrical switches. From the above 
description of the preferred embodiment of the invention, those skilled in 
the art will perceive improvements, changes and modifications. Such 
improvements, changes and modifications within the skill of the art are 
intended to be covered by the appended claims.