Comfort mechanism with slack limit

In a seat belt retractor having a comfort mechanism, a spindle having belt webbing wound thereon is supported for rotation in belt retraction and belt withdrawal directions. A wind-up spring biases the spindle to rotate in the belt retraction direction. A rotatable member is rotatable relative to the spindle. Actuating means has a first condition in which the rotatable member is free to rotate and a second condition in which rotation of the rotatable member is blocked. An auxiliary wind-up spring has one end connected to the rotatable member and another end connected to the spindle. The auxiliary wind-up spring is (i) wound about a portion of the spindle to a taut condition when the actuating means is in its first condition to cause the spindle and the rotatable member to rotate together, (ii) unwound upon rotation of the spindle in the belt withdrawal direction when the actuating means is in its second condition to enable the spindle to rotate relative to the rotatable member, and (iii) rewound about the portion of the spindle to the taut condition to limit rotation of the spindle in the belt retraction direction relative to the rotatable member after withdrawal of the belt webbing from the spindle when the actuating means is in its second condition. A predetermined amount of slack is set in the belt when the comfort mechanism is engaged.

BACKGROUND OF THE INVENTION 
1. Technical Field 
The present invention relates to a seat belt retractor and, in particular, 
the present invention relates to a seat belt retractor having a comfort 
mechanism. 
2. Description of the Prior Art 
Comfort mechanisms for seat belt retractors are known. U.S. Pat. No. 
4,467,982 discloses a comfort mechanism which is actuated after the belt 
wearer establishes a desired amount of slack in the belt webbing. The 
comfort mechanism, when actuated, blocks rotation of a seat belt retractor 
take-up spool in a belt retraction direction to maintain the slack in the 
belt webbing that was established. Thus, the biasing force exerted by a 
wind-up spring tending to rotate the take-up spool in a belt retraction 
direction is not transferred through the seat belt webbing to the belt 
wearer. 
U.S. patent application Ser. No. 138,838, filed Dec. 28, 1987 now U.S. Pat. 
No. 4,840,324 and assigned to the assignee of the present invention, 
discloses a comfort mechanism which establishes slack in belt webbing 
during actuation of the comfort mechanism. The comfort mechanism includes 
a drum having a plurality of ratchet teeth formed on the drum. The drum is 
connectable with a spindle of the retractor. A member is moved to engage 
one of the ratchet teeth on the drum and rotate the drum a predetermined 
amount. Rotation of the drum causes the spindle to rotate in a belt 
withdrawal direction to establish a predetermined amount of slack in the 
belt webbing. The member then blocks both the drum and the spindle from 
rotating in a belt retraction direction to maintain the slack in the belt 
webbing that was established. 
SUMMARY OF THE INVENTION 
The present invention is directed to a seat belt retractor including a 
comfort mechanism. The seat belt retractor includes a spindle supported 
for rotation in belt retraction and belt withdrawal directions. Seat belt 
webbing is wound onto the spindle. A wind-up spring biases the spindle to 
rotate in the belt retraction direction. A disk member is supported for 
rotation by a portion of the spindle. Actuatable means has a first 
condition in which the disk member is free to rotate and a second 
condition in which rotation of the disk member by the wind-up spring is 
blocked. An elongate flexible member has an end portion connected to the 
disk member and another end portion connected to the spindle. The elongate 
flexible member winds about a portion of the spindle to a taut condition 
when the actuatable means is in its first condition to cause the spindle 
and the disk member to rotate together. The elongate flexible member 
unwinds from the taut condition upon rotation of the spindle in the belt 
withdrawal direction when the actuatable means is in its second condition 
to enable the spindle to rotate relative to the disk member. When the 
actuatable means is in its second condition and after webbing has been 
withdrawn from the spindle, the elongate flexible member rewinds about the 
portion of the spindle to the taut condition during rotation of the 
spindle in the belt retraction direction to limit rotation of the spindle 
in the belt retraction direction relative to the disk member. 
The elongate flexible member is a metal coil spring having a spring rate 
lower than the spring rate of the wind-up spring. The metal coil spring 
biases the disk member to an initial position relative to the spindle and 
causes the disk member to rotate with the spindle when the actuatable 
means is in its first condition. 
In a first embodiment of the invention, the actuatable means includes a 
lever supported for pivotal movement and receivable in one of a plurality 
of recesses in the disk member to block rotation of the disk member in 
either direction. The seat belt retractor further includes means for 
preventing the lever from engaging the disk member, until the spindle 
rotates in the belt withdrawal direction a predetermined amount to allow a 
predetermined amount of slack to be established in the belt webbing. The 
preventing means includes a rotatable cam. The cam has a surface rotatable 
between a first position in which the lever is prevented from engaging the 
disk member and a second position in which the lever is permitted to 
engage the disk member. The cam rotates between its first and second 
positions in response to rotation of the disk member and the spindle. 
In a second embodiment of the invention, the actuatable means includes an 
electric motor drive which is energized when the vehicle occupant actuates 
a switch. The electric motor rotates a sector gear which is coaxial with 
the rotatable disk. A pawl is pivotally mounted on the sector gear. As the 
sector gear turns, the pawl is cammed into one of the recesses in the disk 
and blocks the wind-up spring from rotating the disk in the belt 
retraction direction. The electric motor remains energized, and the sector 
gear continues to turn. The pawl rotates the disk in the belt withdrawal 
direction by a predetermined amount, then the motor then shuts off. As the 
disk rotates the predetermined amount, the retractor spindle also rotates 
and a predetermined amount of belt webbing is paid out to set a 
predetermined amount of slack in the belt. 
In a third embodiment of the invention, an electric motor drives a worm 
gear. The worm gear drives an idler gear. The idler gear drives a rack 
gear linearly. The rack gear engages the rotatable disk which in this 
embodiment has spur gear teeth formed thereon. As the rack gear moves 
linearly, the disk is rotated in the belt withdrawal direction by a 
predetermined amount, to rotate the spindle and pay out a predetermined 
amount of belt webbing to establish slack in the belt. When the motor is 
de-energized, the disk is blocked from rotation by the wind-up spring due 
to a locking relationship between the teeth of the worm gear and the teeth 
of the idler gear.

DESCRIPTION OF A PREFERRED EMBODIMENT 
FIG. 1 illustrates a seat belt retractor 20 for use in a vehicle. The seat 
belt retractor 20 includes a spindle 22. A pair of stub shafts 32, 34 are 
connected to and extend from axially opposite ends of the spindle 22. Each 
of the stub shafts 32, 34 is received in an opening in a respective side 
36, 38 of a frame 42 to support the spindle 22 for rotation. An opening 44 
in the frame 42 receives a fastener (not shown) to connect the retractor 
20 to the vehicle. 
Seat belt webbing 52 (FIGS. 1 and 2) is connected at one end to the spindle 
22 and is wound onto the spindle for storage. The belt webbing 52 is 
extendable about an occupant of the vehicle for restraining the occupant. 
The spindle 22 is rotatable in a belt retraction direction 54 (FIG. 2) and 
a belt withdrawal direction 56. A wind-up spring 62 has one end portion 64 
connected to a spring cover 66 which is attached to the frame side 38. 
Another end portion 68 of the wind-up spring 62 is connected to the stub 
shaft 34. The wind-up spring 62 biases the spindle 22 to rotate in the 
belt retraction direction 54 which tends to pull the belt webbing 52 
against the vehicle occupant. 
A pair of ratchet wheels 82 (FIGS. 1 and 2) are connected to axially 
opposite end portions of the spindle 22 adjacent each frame side 36, 38. A 
plurality of ratchet teeth 84 extend radially outwardly from each of the 
ratchet wheels 82 and are equally spaced about the outer circumference of 
the ratchet wheel. A pawl 92 extends between and is supported for pivotal 
movement by the sides 36, 38 of the frame 42. A pendulum-type inertia 
member 94 is supported for pivotal movement by a beam 96 extending between 
the sides 36, 38 of the frame 42 adjacent the pawl 92. The inertia member 
74 pivots relative to the beam 96 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 94, an upper portion 98 of the 
inertia member engages the pawl 92 and causes the pawl to pivot toward the 
ratchet wheels 82. The pawl 92 engages a ratchet tooth 84 on each of the 
ratchet wheels 82 to block the spindle 22 from rotating in the belt 
withdrawal direction 56. While a vehicle sensitive type locking mechanism 
is described, it should be apparent that any known type of locking 
mechanism may be used to block rotation of the spindle 22 in the belt 
withdrawal direction 56 during an emergency. 
The retractor 20 also includes an actuatable comfort mechanism 112 in 
accordance with a first embodiment of the invention. The comfort mechanism 
112 is located within a housing 114 (FIG. 1) connected to the frame side 
36 of the retractor 20. When actuated, the comfort mechanism 112 blocks 
rotation of the spindle 22 in the belt retraction direction 54 so the belt 
webbing 52 is not pulled against the occupant by the biasing force exerted 
by the wind-up spring 62. 
The comfort mechanism 112 includes a circular disk 132 (FIGS. 2 and 3) 
supported on the stub shaft 32. The circular disk 132 is rotatable 
relative to the spindle 22 about the stub shaft 32. A plurality of 
recesses 134 are spaced equally about the outer circumference of the 
circular disk 132. 
An auxiliary coil spring 142 (FIGS. 2 and 3) connects the disk 132 with the 
spindle 22 through the stub shaft 32. The auxiliary spring 142 has one end 
portion 152 fixed to a projection 154 extending axially from the disk 132. 
Another end portion 156 of the auxiliary spring 142 is fixed to the stub 
shaft 32. The auxiliary spring 142 is wound around a portion 144 (FIG. 1) 
of the stub shaft 32 and in a direction opposite to that of the wind-up 
spring 62. The auxiliary spring 142 has a spring rate lower than the 
spring rate of the wind-up spring 62. When the disk 132 is free to rotate, 
the auxiliary spring 142 is wound to a taut condition around the stub 
shaft 32 in which adjacent coils 162 engage (shown in FIG. 3 slightly 
spaced for clarity). When the auxiliary spring 142 is in its taut 
condition and the disk 132 is free to rotate, the auxiliary spring biases 
the disk to an initial position relative to the stub shaft 32 to rotate 
the disk with the spindle 22 in either direction 54, 56. 
When the disk 132 is fixed against rotation and the auxiliary spring 142 is 
in its taut condition around the stub shaft 32, the auxiliary spring 
prevents the stub shaft and spindle 22 from rotating in a belt retraction 
direction 54 under the influence of the wind-up spring 62. Thus, the belt 
webbing 52 is not pulled against the occupant which could cause 
discomfort. 
When the disk 132 is fixed against rotation and some of the belt webbing 52 
is withdrawn from the retractor 20, the auxiliary spring 142 relaxes from 
its taut or coil bound condition. The adjacent coils 162 disengage one 
another and the auxiliary spring 142 increases in diameter to function as 
"memory" for the comfort mechanism 112. Thereafter, when the force causing 
the belt webbing 52 to be withdrawn from the retractor 20 is removed, the 
wind-up spring 62 rotates the spindle 22 in the belt retraction direction 
54. The auxiliary spring 142 then winds onto the portion 144 of the stub 
shaft 32. When the auxiliary spring 142 again reaches its taut condition, 
the auxiliary spring prevents rotation of the spindle 22 in the belt 
retraction direction 54. Rotation of the spindle 22 is stopped at 
approximately the same rotational position as when the comfort mechanism 
112 was actuated so the same amount of slack exists in the belt webbing 
52. This constitutes the "memory" of the comfort mechanism 112. The amount 
of memory is limited only by the diameter and number of coils 162 of the 
auxiliary spring 142 relative to the number of rotations that the spindle 
22 can rotate in the belt withdrawal direction 56 before the comfort 
mechanism 112 is deactuated. 
The comfort mechanism 112 includes a handle 182 attached to one end of a 
lever 184 (FIGS. 1, 2 and 5-7). The handle 182 extends from an opening 186 
in the housing 114. The lever 184 is supported for pivotal movement by a 
pin 188 (FIGS. 2 and 5) fixed to and extending axially from the frame side 
36. A resiliently deflectable arm 192 is fixed to the lever 184 (FIGS. 
5-7). The arm 192 has an end portion 194 which is receivable in one of the 
recesses 134 in the disk 132 to block rotation of the disk in either 
direction. A spring 202 has a pair of U-shaped detent portions 203 and 205 
for receiving the end 204 of the lever 184 which is opposite the handle 
182. The detent portion 203 of the spring 202 maintains the lever 184 in 
the position shown in FIG. 6 and the detent portion 205 maintains the 
lever 184 in the position shown in FIG. 5. 
The comfort mechanism 112 also includes a cam 222 (FIGS. 5-7) supported for 
rotation on the stub shaft 32. A cam lobe 224 extends radially outward 
from the cam 222. The cam lobe 224 has a radius R1 (FIG. 7) greater than 
the largest radius R2 of the disk 132. The cam 222 has a radius R3 less 
than the radius R4 to the bottom of each recess 134. A friction spring 242 
(FIGS. 1 and 2) drives the cam 222 in response to rotation of the disk 
132. The cam 222 has a projection 252 (FIGS. 2 and 5-7) extending axially 
into an arcuate slot 254 in the frame side 36. The arcuate slot 254 limits 
the amount of rotational movement of the cam 222. 
Another arcuate slot 262 is located in the cam 222. The arcuate length of 
the slot 262 in the cam 222 is greater than the arcuate length of the slot 
254 located in the frame side 36. A cam return link 282 (FIGS. 2 and 5-7) 
is pivotally supported at one end by a pin 284 extending through the end 
204 of the lever 184. Another pin 292 extends axially relative to the cam 
222 from the other end of the link 282 and is received in the arcuate slot 
262 in the cam 222. 
To actuate the comfort mechanism once the belt webbing is extended around 
the occupant, the occupant moves the lever 184 to the position illustrated 
in FIG. 6 so that the end 194 of the member 192 engages the cam lobe 224 
on the cam 222. The occupant then withdraws the belt webbing 52 from the 
retractor 20, causing the spindle 22, the disk 132 and the cam 222 to 
rotate in the belt withdrawal direction 56. When the spindle 22 rotates a 
predetermined amount in the belt withdrawal direction 56, setting a 
predetermined amount of slack in the belt webbing 52, the cam 222 rotates 
in the clockwise direction from the position illustrated in FIG. 6 to the 
position illustrated in FIG. 7 in which the cam projection 252 abuts the 
end of the slot 254 and the cam 222 stops rotating. The end 194 of the 
member 192 moves off the cam lobe 224 to engage the disk 132 and enters 
one of the recesses 134 to block rotation of the disk 132. Since the disk 
132 is fixed against rotation and the auxiliary spring 142 is wound about 
the stub shaft 32 in its taut condition, rotation of the spindle 22 in the 
belt retraction direction 54 by the wind-up spring 62 is blocked. In this 
position, the pin 292 on the clutch return link 282 is at one end of the 
cam slot 262. 
The comfort mechanism 112 may be deactuated in several ways. One way to 
deactuate the comfort mechanism 112 is by returning the handle 182 on the 
lever 184 to the position illustrated in FIG. 5, thus lifting the end 194 
of the member 192 out of engagement with the disk 132. Simultaneously, the 
cam return link 282 moves to the right, as viewed in FIG. 7. The pin 292, 
pushing against the end of the slot 262, rotates the cam 222 
counterclockwise until the pin 252 engages the end of the slot 254. The 
cam 222 is then in the position shown in FIG. 5 in which the cam lobe 224 
is disposed beneath the end 194 of the member 192. The disk 132 is free to 
rotate, enabling the wind-up spring 62 to rotate the spindle 22 in the 
belt retraction direction 54. 
The comfort mechanism 112 may also be deactuated with a pull-off which 
moves the lever 184 from the position illustrated in FIG. 7 to the 
position illustrated in FIG. 5. Such a pull-off includes a cable 312 
(illustrated schematically in FIG. 5) which is connected between the lever 
184 and a vehicle door (not shown). When the vehicle door is opened, the 
cable moves and pulls the lever 184 to the position shown in FIG. 5, 
deactuating the comfort mechanism 112. 
A comfort mechanism in accordance with a second embodiment of the invention 
is illustrated in FIGS. 8, 9 and 10, wherein parts which are identical to 
those in the first embodiment are given the same reference numeral with 
the suffix "a" added thereto to distinguish them from those of the first 
embodiment. The retractor of FIGS. 8, 9 and 10 includes a spindle 22a 
which is rotatable in a belt retraction direction 54a and a belt 
withdrawal direction 56a. A pair of stub shafts 32a and 34a extend from 
axially opposite ends of the spindle 22a. A wind-up spring 62a has one end 
64a for connection to a fixed location on the retractor frame or housing. 
The other end 68a of the wind-up spring 62a is connected to the stub shaft 
34a. The wind-up spring 62a biases the spindle 22a to rotate in the belt 
retraction direction 54a. The spindle 22a also includes a pair of ratchet 
wheels 82a which are engageable by a pawl locking mechanism (not shown) in 
a manner similar to that described with reference to the first embodiment 
of the invention. 
The comfort mechanism when actuated blocks rotation of the spindle 22a by 
the wind-up spring 62a in the belt retraction direction 54a. The comfort 
mechanism includes a circular disk 132a supported on the stub shaft 32a 
for rotation relative to the spindle 22a. A plurality of recesses 134a are 
spaced equally about the outer circumference of the disk 132a. An 
auxiliary coil spring 142a connects the disk 132a with the spindle 22a 
through the stub shaft 32a. One end portion 152a of the auxiliary spring 
142a is fixed to a projection 154a extending axially from the disk 132a. 
The other end portion 156a of the auxiliary spring 142a is fixed to a slot 
in the stub shaft 32a. When the disk 132a is blocked from rotation, the 
spindle 22a may rotate a certain amount against the bias of the auxiliary 
spring 142a, in the belt withdrawal direction, to allow a vehicle occupant 
to move forward in the seat. When the vehicle occupant moves back to his 
initial position in the seat, the auxiliary wind-up spring 152a will 
return the spindle 22a to its original position, retracting the belt to 
the previously set position. 
The spindle stub portion 32a extends through an opening 320 in a frame side 
portion 322 and through an opening 326 in a plate 324 which is fixed to 
the frame side portion 322. A boss 328 surrounds the opening 326. A sector 
gear 330 is fitted against the plate 324. An opening 332 in the sector 
gear 330 fits around the boss 328 on the plate 324. The sector gear 330 is 
rotatable relative to the plate 324. 
A DC reversible electric motor 334, powered by the vehicle electrical 
system, is mounted on the plate 324. An output shaft 336 of the electric 
motor 334 extends through an opening 338 in the plate 324. The output 
shaft 336 drives a spur gear 340. The spur gear 340 has a plurality of 
teeth 342 which meshingly engage teeth 344 on the sector gear 330. An 
L-shaped pawl 346 is pivotally mounted on the sector gear 330 at a pawl 
mount 348. A first end portion 350 of the pawl 346 is received in a cam 
slot 352 in the plate 324. A second end portion 354 of the pawl 346 
extends through a guide slot 356 in the sector gear 330 and into a slot 
358 in the plate 324. 
To actuate the comfort mechanism shown in FIGS. 8-10, the vehicle occupant 
actuates a switch (not shown) which may be mounted, for example, on the 
dashboard of the vehicle. The switch energizes the electric motor 334. The 
motor output shaft 336 rotates the spur gear 340 in a counterclockwise 
direction as viewed in FIGS. 9 and 10. As the spur gear 340 rotates, the 
teeth 342 on the spur gear engage the teeth 344 on the sector gear 330, 
and the sector gear 330 rotates in the clockwise direction as viewed in 
FIGS. 9 and 10. As the sector gear 330 rotates, the pawl mount 348 on the 
sector gear 330 moves arcuately, moving the pawl 346 as a whole arcuately. 
As the pawl 346 moves arcuately, the first end 350 of the pawl 346 is 
cammed outwardly by a first portion 360 of the cam slot 352. The pawl 346 
pivots about the pawl mount 348 and the second end 354 of the pawl 346 
moves inwardly, guided by the slot 356 in the sector gear 330, to engage 
one of the recesses 134a in the disk member 132a. When the pawl 346 is in 
engagement with the disk member 132a, the wind-up spring 62a is not strong 
enough to rotate the disk member 132a against the friction, gearing and 
resistance of the comfort mechanism. The disk member 132a is thereby 
blocked from rotation by the wind-up spring 62a in the belt retraction 
direction 54a. The "memory" feature of the comfort mechanism is also 
operative as described above with reference to the first embodiment of the 
invention. 
The electric motor 334 remains energized and continues to turn the spur 
gear 342. The sector gear 330 continues to rotate in the clockwise 
direction as viewed in FIGS. 9 and 10, drawing the pawl 346 arcuately 
along with it. The first end 350 of the pawl 346 moves along a second 
segment 362 of the cam slot 352 which extends arcuately along the plate 
324. The second end 354 of the pawl 346 rotates the disk member 132a in 
the clockwise direction as viewed in FIGS. 9 and 10, i.e., in the belt 
withdrawal direction 56a The disk member 132a continues to rotate 
predetermined amount until the pawl second end 354 reaches an end 364 of 
the cam slot 352, at which time the motor 334 is de-energized As the disk 
132a rotates, the spindle 22a also rotates in the belt withdrawal 
direction 56a to thus pay out a predetermined amount of belt webbing and 
provide a predetermined amount of slack in the belt webbing extending 
about the vehicle occupant. 
The comfort mechanism shown in FIGS. 8-10 may be deactuated by actuating a 
switch, by disengaging a seat belt tongue from a buckle assembly or by 
opening a vehicle door or shutting off the vehicle. When the comfort 
mechanism is deactuated, the electric motor 334 is energized in reverse 
and drives the sector gear 330 to rotate counterclockwise, as viewed in 
FIGS. 9 and 10. The pawl 346 is driven in the belt retraction direction 
54a and rotates the disk member 132a to its original position in which the 
pawl 346 does not engage the disk member 132a. The disk member 132a is 
free to rotate, and the comfort mechanism is disengaged. 
A comfort mechanism in accordance with a third embodiment of the invention 
is illustrated schematically in FIGS. 11 and 12 of the drawings. The 
comfort mechanism includes a DC reversible electric motor 400. The 
electric motor 400 drives a worm gear 402. The worm gear has gear teeth 
404 which intermesh with gear teeth 406 on a worm wheel or idler gear 408. 
The gear teeth 406 on the idler gear 408 intermesh with gear teeth 410 on 
a linearly movable rack gear 412. The gear teeth 410 on the rack gear 412 
are engageable with a plurality of gear teeth 414 on a rotatable disk 
member 416 which is rotatable in the belt retraction direction 54a and the 
belt withdrawal direction 56a. The rotatable disk member 416 is connected 
to the retractor spindle (not shown) by an auxiliary wind-up spring (not 
shown) in the same manner as described above with reference to the first 
and second embodiments of the invention, to provide the comfort mechanism 
with the "memory" feature described above. 
To actuate the comfort mechanism shown in FIGS. 11 and 12, the vehicle 
occupant actuates a switch to energize the electric motor 400. The 
electric motor 400 rotates the worm gear 402 and the idler gear 408. The 
rack gear 412 is driven linearly from the condition shown in FIG. 11 to 
the condition shown in FIG. 12. The teeth 410 on the rack gear 412 engage 
the gear teeth 414 on the rotatable disk member 416, and the disk member 
416 is rotated in the belt withdrawal direction 56a. The retractor spindle 
is thereby rotated also in the belt withdrawal direction 56a. The electric 
motor 400 remains energized for a predetermined period of time. The period 
of time is long enough so that the retractor spindle is rotated by an 
amount sufficient to pay out a predetermined amount of slack in the belt 
webbing. Preferably, the spindle is rotated enough to pay out one-half 
inch to one inch of belt webbing. 
The gear teeth 404 on the worm gear 402 are profiled as described in 
co-pending U.S. patent application Ser. No. 282,744, filed Dec. 9, 1988 
and assigned to the assignee of the present application, so that the idler 
gear 408 cannot drive the worm gear 402. The meshing engagement of the 
worm gear 402 and the worm wheel or idler gear 408 prevents the worm wheel 
408 from rotating. This occurs because of the helix angle of the worm gear 
402 and the pressure angle of the worm gear 402 engaging with the worm 
wheel 408. The helix angle of the worm gear 402 is less than five degrees. 
The pressure angle of the worm gear 402 engaging with the worm wheel 408 
is greater than fifteen degrees. Accordingly, when the electric motor 400 
is de-energized, the idler gear 408 cannot rotate in the counterclockwise 
direction as viewed in FIG. 12. Thus, the rack gear 412 cannot move 
linearly downwardly as viewed in FIG. 12, and the disk member 416 is 
blocked from rotation in the belt retraction direction 54a by the wind-up 
spring 62a. The retractor spindle is thus also blocked from rotation by 
the wind-up spring 62a in the belt retraction direction 54a. The electric 
motor 400, when de-energized, also resists rotation and thereby assists in 
blocking rotation of the disk member 416. 
To disengage the comfort mechanism of FIGS. 11 and 12, the vehicle occupant 
can actuate a switch, unbuckle the safety belt, open a vehicle door, or 
shut off the vehicle. Such action energizes the electric motor 400 in the 
opposite direction of rotation to turn the worm gear 402, the idler gear 
408 and the rack gear 412. The disk member 416 is rotated in the belt 
retraction direction 54a until the rack gear 412 is disengaged from the 
disk member 416. The electric motor 400 is de-energized. The disk member 
416 is free to rotate in the belt retraction direction 54 and the comfort 
mechanism is disengaged. 
From the above description of a 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.