FIELD OF THE INVENTION
[0001] The present invention relates to a self-opening and self-closing device, and more
particularly, to a self-opening and self-closing slide assembly that can be self-opening
when being pressed and self-closing when being pushed inward.
BACKGROUND OF THE INVENTION
[0004] The present invention intends to provide a self-close/open slide assembly which combines
the functions of self-open and self-close so that the rails automatically open or
close by applying a force thereto.
SUMMARY OF THE INVENTION
[0005] The present invention relates to a self-opening and self-closing slide assembly and
comprises a first rail having a side wall, a release portion, a guide groove and a
first passage. The release portion is located on the side wall and in the first passage.
The guide groove is located on the side wall and has a longitudinal groove and a transverse
groove which communicates with the longitudinal groove. A second rail is slidably
connected to the first rail and has a side wall, a protrusion and a second passage.
The protrusion is connected to the side wall of the second rail and faces the first
passage of the first rail. A third rail is slidably connected to the second rail and
has a push block facing the second passage of the second rail. A movable unit has
a base, a first resilient member, a push member, a movable member and a second resilient
member. The base is connected to the side wall of the first rail and has a longitudinal
section, a room and a guide passage. The room is substantially parallel to the longitudinal
section. The guide passage has a longitudinal guide groove and a transverse guide
groove which communicates with the longitudinal guide groove. The first resilient
member is biased between the base and the push member. The push member is located
corresponding to the second rail. The movable member is movably connected to the base
and has a first leg, a second leg, a guide path and an engaging portion. The first
leg and the second leg are respectively located corresponding to the guide passage
and the room of the base. The guide path has a first longitudinal guide path, a second
longitudinal guide path and a mediate path. The first and second longitudinal guide
paths are located on two sides of the engaging portion. The mediate path communicates
with the first and second longitudinal guide paths and located corresponding to the
engaging portion. The second resilient member is located in the room of the base and
contacts the second leg of the movable member. A passive unit has a link, a connection
unit and a first spring. The link has a first protrusion and a second protrusion.
The first protrusion is located in the guide groove of the first rail and the second
protrusion is located corresponding to the protrusion of the second rail. The connection
unit is connected between the movable member and the link. The first spring is connected
between the link and the connection unit. A synchronic unit has a synchronic member
and a second spring. The synchronic member is pivotably connected to the second rail
and has a first contact portion and a second contact portion. The first contact portion
faces the side wall of the first rail and is located corresponding to the release
portion. The second contact portion is located corresponding to the push block of
the third rail. The second spring is connected between the synchronic member and the
second rail. A hooking unit has a hooking member and a contact member. The hooking
member is pivotably connected to the third rail and has a hooking portion. The contact
member is fixed to the third rail and located corresponding to the movable member.
When the third rail is located at a retracted position relative to the first rail,
the second rail is retracted in the first rail. The hooking portion of the hooking
member is engaged with the engaging portion of the movable member. The push member
is pushed by the second rail and compresses the first resilient member. The first
resilient member generates a force in a first direction and the force is applied to
the push member. The second leg of the movable member contacts the second resilient
member. The push block of the third rail is located corresponding to the second contact
portion of the synchronic member. When the third rail is pushed by a pushing force,
the hooking portion of the hooking member is disengaged from the engaging portion
of the movable member and is moved to the first longitudinal guide path of the movable
member. When the pushing force is disappeared, the force in the first direction of
the first resilient member is released. The second rail is pushed by the push member
and moves relative to the first rail. When the third rail is continuously pulled,
the push block of the third rail contacts the second contact portion of the synchronic
member so that the second rail is pulled along with the movement of the third rail.
The protrusion of the second rail pushes the second protrusion of the link so that
the first protrusion of the link moves along the longitudinal groove of the guide
groove of the first rail. The movable member is moved by the link and the connection
unit. The movable member moves along the longitudinal guide groove of the guide passage
of the base. When the first protrusion is engaged with the transverse groove of the
guide groove, the protrusion of the second rail presses on a top of the second protrusion
of the link. The first leg is located in the transverse guide groove of the guide
passage and the second resilient member is compressed by the second leg and generates
a force in a second direction. When the first contact portion of the synchronic member
contacts the release portion of the first rail, the synchronic member swings an angle
and the second contact portion of the synchronic member is disengaged from the push
block of the third rail. When the third rail is retracted relative to the first rail,
the first contact portion of the synchronic member is separated from the release portion
of the first rail and the second contact portion returns to a position located corresponding
to the push block. When the contact member pushes the movable member, the movable
member is disengaged from the transverse guide groove of the guide passage and the
hooking portion of the hooking member contacts the engaging portion of the movable
member. The force of the second resilient member retracts the third rail relative
to the first rail and the first protrusion of the link is separated from the transverse
groove of the guide groove.
[0006] Preferably, the slide assembly further comprises a threaded block and an adjustment
member, and both of which are located corresponding to the room. The adjustment member
has a threaded rod and a head which extends from one end of the threaded rod. The
threaded rod of the adjustment member threadedly extends through the threaded block.
The threaded rod in the room contacts the second leg of the movable member.
[0007] Preferably, the connection unit comprises a first connector and a second connector
which is connected to the first connector. The first connector is fixed to the movable
member by a fixing member. The second connector is pivotably connected to the link.
[0008] Preferably, the link has a first hook and the second connector has a second hook.
The first spring is hooked between the first and second hooks.
[0009] Preferably, a support member is fixed to the side wall of the first rail and has
a support passage in which the second connector is movably located. The support member
has at least one stop wall to maintain the second connector in the support passage.
[0010] Preferably, the side wall of the second rail has a window and the synchronic member
is located beside the window and pivotably connected to the second rail by a pivot.
The first contact portion of the synchronic member extends through the window and
toward the side wall of the first rail.
[0011] Preferably, the first contact portion of the synchronic member has an inclined face
which is located corresponding to the release portion of the first rail. The synchronic
member has a third hook and the second rail has a fourth hook. The second spring is
hooked between the third and fourth hooks.
[0012] Preferably, the third rail has an opening. The hooking unit comprises a cover which
is located corresponding to the opening and is fixed to the third rail. The hooking
member is pivotably connected to the cover by a pin. The cover has a curved slot which
is located corresponding to the hooking portion of the hooking member. The hooking
portion of the hooking member extends through the curved slot.
[0013] Preferably, the first rail has a buffering member connected thereto and comprises
a plunger which is extendable from the buffering member. The distance that the plunger
extends forms a buffering travel to the second rail.
[0014] Alternatively, the present invention also provides a self-close/open slide assembly
and comprises a first rail having a top wall, bottom wall, a side wall, a release
portion and a guide groove. The side wall is connected between the top and bottom
walls. The top wall, the bottom wall and the side wall define a first passage. The
release portion is located on the side wall and in the first passage. The guide groove
is located on the side wall and has a longitudinal groove and a transverse groove
which is located at the distal end of the longitudinal groove and communicates with
the longitudinal groove. A second rail is slidably connected to the first rail and
has a top wall, a bottom wall, a side wall and a protrusion. The side wall is connected
between the top and bottom walls of the second rail. The top wall, the bottom wall
and the side wall define a second passage. The protrusion is connected to the side
wall of the second rail and faces the first passage of the first rail. A third rail
is slidably connected to the second rail and has a push block facing the second passage
of the second rail. A movable unit has a base, a fixing frame, a first resilient member,
a push member, a movable member and a second resilient member. The base is connected
to the side wall of the first rail and has a longitudinal section, a room and a guide
passage. The room is substantially parallel to the longitudinal section. The guide
passage has a longitudinal guide groove and a transverse guide groove which is located
at the distal end of the longitudinal guide rove and communicates with the longitudinal
guide groove. The fixing frame is connected to the base and comprises a longitudinal
rod. The first resilient member is mounted to the longitudinal rod. The push member
is slidably connected to the longitudinal section of the base and movably mounted
to the longitudinal rod of the fixing frame and contacts the first resilient member.
The movable member is movably connected to the base and has a first leg, a second
leg, a guide path and an engaging portion. The first leg and the second leg are respectively
located corresponding to the guide passage and the room of the base. The guide path
has a first longitudinal guide path, a second longitudinal guide path and a mediate
path. The first and second longitudinal guide paths are located on two sides of the
engaging portion. The mediate path communicates with the first and second longitudinal
guide paths and is located corresponding to the engaging portion. The second resilient
member is located in the room of the base and contacts the second leg of the movable
member. A passive unit has a link, a connection unit and a first spring. The link
has a first protrusion and a second protrusion. The first protrusion is located in
the guide groove of the first rail and the second protrusion is located corresponding
to the protrusion of the second rail. The connection unit is connected between the
movable member and the link. The first spring is connected between the link and the
connection unit. A synchronic unit has a synchronic member and a second spring. The
synchronic member is pivotably connected to the second rail and has a first contact
portion and a second contact portion. The first contact portion faces the side wall
of the first rail and is located corresponding to the release portion. The second
contact portion is located corresponding to the push block of the third rail. The
second spring is connected between the synchronic member and the second rail. A hooking
unit has a hooking member and a contact member. The hooking member is pivotably connected
to the third rail and has a hooking portion. The contact member is fixed to the third
rail and located corresponding to the movable member.
[0015] The present invention will become more obvious from the following description when
taken in connection with the accompanying drawings which show, for purposes of illustration
only, a preferred embodiment in accordance with the present invention.
BRIEF DESCRIPTION OF THE DRAWINGS
[0016]
Fig. 1 is a perspective view to show the slide assembly of the present invention;
Fig. 2 is an exploded view to show the slide assembly of the present invention;
Fig. 3 is an exploded view to show the synchronic unit of the slide assembly of the
present invention;
Fig. 4 is an exploded view to show the hooking unit of the slide assembly of the present
invention;
Fig. 5 is an exploded view to show the movable unit of the slide assembly of the present
invention;
Fig. 6 is an exploded view to show part of the movable unit of the slide assembly
of the present invention;
Fig. 7 is a perspective view to show the passive unit of the slide assembly of the
present invention;
Fig. 8 is a perspective view to show that the slide assembly of the present invention
is completely retracted;
Fig. 9 shows the slide assembly of the present invention wherein the third rail is
pushed;
Fig. 10 shows the slide assembly of the present invention wherein the third rail is
pushed and then released;
Fig. 11 shows another status of the slide assembly of the present invention wherein
the third rail is pushed and then released;
Fig. 12 shows that the third rail is pushed and then pulled, and the second rail is
also pulled with the third rail;
Fig. 13 shows that the third rail is pushed and then pulled, and the second rail is
also pulled with the third rail, the passive unit and the synchronic unit are activated;
Fig. 14 shows that the third rail is pushed and then pulled, and the second rail is
also pulled with the third rail, the movable member of the passive unit is activated;
Fig. 15 shows the two respective statuses of the passive unit and the synchronic unit
when the third and second rails are pushed and retracted into the first rail;
Fig. 16 shows the status of the movable unit when the third and second rails are pushed
and retracted into the first rail;
Fig. 17 shows that the movable member of the movable unit is pushed back to its initial
position by the contact member when the third and second rails are pushed and retracted
into the first rail;
Fig. 18 shows that the link of the passive unit is pushed back to its initial position
when the third and second rails are pushed and retracted into the first rail;
Fig. 19 shows that the slide assembly of the present invention has a buffering member,
and
Fig. 20 shows that the buffering member is functioned to the second rail.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
[0017] Referring to Figs. 1 and 2, the self-opening and self-closing slide assembly of the
present invention comprises a first rail 10, a first bearing assembly 12, a second
rail 14, a second bearing assembly 16, a third rail 18 and an open-close device 20.
The first bearing assembly 12 is connected to the first rail 10 so that the second
rail 14 is slidably connected to the first rail 10. The second bearing assembly 16
is connected to the second rail 14 so that the third rail 18 is slidably connected
to the second rail 14.
[0018] The first rail 10 has a top wall 22a, bottom wall 22b, a side wall 24, a release
portion 26 and a guide groove 28. The side wall 24 is connected between the top and
bottom walls 22a, 22b. The top wall 22a, the bottom wall 22b and the side wall 24
define a first passage 30. The release portion 26 is located on the side wall 24 and
in the first passage 30. The guide groove 28 is located on the side wall 24 and has
a longitudinal groove 32 and a transverse groove 34 which is located at the distal
end of the longitudinal groove 32 and communicates with the longitudinal groove 32.
[0019] The second rail 14 is slidably connected to the first passage 30 of the first rail
10 by the first bearing assembly 12. The second rail 14 comprises a top wall 36a,
a bottom wall 36b, a side wall 38, a protrusion 40 and a window 42 as shown in Fig.
3. The side wall 38 is connected between the top and bottom walls 36a, 36b of the
second rail 14. The top wall 36a, the bottom wall 36b and the side wall 38 define
a second passage 44. The protrusion 40 is connected to the side wall 38 of the second
rail 14 and faces the first passage 30 of the first rail 10. The window 42 is defined
in an end of the side wall 38.
[0020] The third rail 18 is slidably connected to the second passage 44 of the second rail
14 by the second bearing assembly 16, and has a push block 46 and an opening 48 as
shown in Fig. 4. The push block 46 faces the second passage 44 of the second rail
14.
[0021] The open-close device 20 comprises a movable unit 50, a passive unit 52, a synchronic
unit 54 and a hooking unit 56.
[0022] The movable unit 50, as shown in Fig. 5 and 6, comprises a base 58, a fixing frame
60, a first resilient member 62, a push member 64, a movable member 66 and a second
resilient member 68. The base 58 is connected to one end of the side wall 24 of the
first rail 10 and comprises a longitudinal section 70, a room 72 and a guide passage
74. The distal end of the longitudinal section 70 has a stop portion 76. The room
72 is substantially parallel to the longitudinal section 70. The guide passage 74
has a longitudinal guide groove 78 and a transverse guide groove 80 which is located
at the distal end of the longitudinal guide rove 78 and communicates with the longitudinal
guide groove 78.
[0023] The fixing frame 60 is connected to the base 58 and comprises a longitudinal rod
82.
[0024] The first resilient member 62 is mounted to the longitudinal rod 82 and has one end
thereof contacting the fixing frame 60.
[0025] The push member 64 is slidably connected to the longitudinal section 70 of the base
58 and movably mounted to the longitudinal rod 82 of the fixing frame 60 and contacts
the first resilient member 62. When the push member 64 is pushed to compress the first
resilient member 62, the first resilient member 62 generates a force in a first direction
and the force is applied to the push member 64.
[0026] The movable member 66 is movably connected to the base 58 and has a first leg 84a,
a second leg 84b, a guide path 86 and an engaging portion 88. The first leg 84a and
the second leg 84b are respectively located corresponding to the guide passage 74
and the room 72 of the base 58. The initial status of the first leg 84a is contacting
the longitudinal guide groove 78 of the guide passage 74 and the second leg 84b is
located in the room 72 of the base 58. The guide path 86 has a first longitudinal
guide path 90, a second longitudinal guide path 92 and a mediate path 94. The first
and second longitudinal guide paths 90, 92 are located on two sides of the engaging
portion 88. The mediate path 94 communicates with the first and second longitudinal
guide paths 90, 92 and is located corresponding to the engaging portion 88. Preferably,
the movable member 66 has a driving end 96 which is located close to the engaging
portion 88.
[0027] The second resilient member 68 is located in the room 72 of the base 58. When the
second leg 84b moves to compress the second resilient member 68, the second resilient
member 68 is compressed by the second leg 84b and generates a force in a second direction.
The force of the second resilient member 68 is applied to the second leg 84b. The
first and second directions are in opposite to each other.
[0028] A preferable embodiment further comprises a threaded block 98 and an adjustment member
100 both located corresponding to the room 72. The adjustment member 100 has a threaded
rod 102 and a head 104 which extends from one end of the threaded rod 102. The threaded
rod 102 of the adjustment member 100 threadedly extends through the threaded block
98, so that the threaded rod 102 in the room 72 contacts the second leg 84b of the
movable member 66. When the user rotates the head 104 of the adjustment member 100,
the threaded rod 102 is moved forward or backward relative to the room 72 such that
the initial position of the second leg 84b in the room 72 of the base 58 can be adjusted.
[0029] The passive unit 52, as shown in Fig. 7, has a link 106, a connection unit 108 and
a first spring 110. The link 106 has a first protrusion 112 and a second protrusion
114. The first protrusion 112 is located in the guide groove 28 of the first rail
10. The second protrusion 114 is located longitudinally and corresponding to the protrusion
40 of the second rail 14. The connection unit 108 is connected between the movable
member 66 and the link 106. In a preferable embodiment, the connection unit 108 comprises
a first connector 116 and a second connector 118 which is connected to the first connector
116. The first connector 116 is fixed to the movable member 66 by a fixing member
120 as shown in Fig. 6. The second connector 118 is pivotably connected to the link
106. The first spring 110 is connected between the link 106 and the second connector
118 of the connection unit 108. In a preferable embodiment, the link 106 has a first
hook 122 and the second connector 118 has a second hook 124. The first spring 110
is hooked between the first and second hooks 122, 124.
[0030] In a preferable embodiment, the movable unit 52 comprises a support member 126 fixed
to the side wall 24 of the first rail 10 and has a support passage 128 in which the
second connector 118 is movably located. The support member 126 has at least one stop
wall 130 to maintain the second connector 118 in the support passage 128 of the support
member 126.
[0031] The synchronic unit 54, as shown in Fig. 3, has a synchronic member 132 and a second
spring 134. The synchronic member 132 is pivotably connected to the side wall 38 of
the second rail 14 by a pivot 136 and has a first contact portion 138 and a second
contact portion 140. The first contact portion 138 extends through the window 42 of
the second rail 14 and toward the side wall 24 of the first rail 10. The first contact
portion 138 of the synchronic member 132 has an inclined face 142 which is located
corresponding to the release portion 26 of the first rail 10. The second contact portion
140 is located corresponding to the push block 46 of the third rail 18. The second
spring 134 is connected between the synchronic member 132 and the second rail 14.
In a preferable embodiment, the synchronic member 132 has a third hook 144 and the
second rail 14 has a fourth hook 146. The second spring 134 is hooked between the
third and fourth hooks 144, 146.
[0032] The hooking unit 56, as shown in Fig. 4, has a hooking member 148, a cover 150 and
a contact member 152. The hooking member 148 is pivotably connected to the cover 150
by a pin 156. The cover 150 is securely connected to the third rail 18 and located
corresponding to the opening 48 of the third rail 18. The cover 150 has a curved slot
158 which is located corresponding to the hooking portion 154 of the hooking member
148. The hooking portion 154 of the hooking member 148 extends through the curved
slot 158 and is movable within the curved slot 158. The contact member 152 is fixed
to the third rail 18 and located corresponding to the driving end 96 of the movable
member 66.
[0033] As shown in Fig. 8, when the third rail 18 is located at a retracted position relative
to the first rail 10, the second rail 14 is retracted in the first rail 10. The hooking
portion 154 of the hooking member 148 is engaged with the engaging portion 88 of the
movable member 66. The second resilient member 68 contacts the second leg 84b of the
movable member 66. The push member 64 is pushed by the second rail 14 and compresses
the first resilient member 62, the first resilient member 62 generates a force in
a first direction F1 and the force is applied to the push member 64. Under the retracted
status, the push block 46 of the third rail 18 is located corresponding to the second
contact portion 140 of the synchronic member 132 of the second rail 14. The first
resilient member 62 stores a force relative to the second rail 14. The force of the
second resilient member 68 is applied to the movable member 66. The second leg 84b
of the movable member 66 contacts the threaded rod 102 of the adjustment member 100.
[0034] As shown in Fig. 9, when the third rail 18 is pushed by a pushing force F (as shown
in the direction shown by the arrow head), the hooking portion 154 of the hooking
member 148 is disengaged from the engaging portion 88 of the movable member 66 and
is moved to the first longitudinal guide path 90 of the movable member 66. When the
pushing force is disappeared, the force in the first direction F1 of the first resilient
member 62 is released, as shown in Figs. 10 and 11, the second rail 14 is pushed by
the push member 64 and the third rail 18 is also moved by the second rail 14 relative
to the first rail 10.
[0035] As shown in Fig. 11, when the third rail 18 is continuously pulled relative to the
first rail 10, as shown in Figs. 12 and 13, the push block 46 of the third rail 18
contacts the second contact portion 140 of the synchronic member 132 so that the second
rail 14 is pulled along with the movement of the third rail 18. The protrusion 40
of the second rail 14 pushes the second protrusion 114 of the link 106 so that along
with the continuous movement of the second rail 14, the first protrusion 112 of the
link 106 moves along the longitudinal groove 32 of the guide groove 28 of the first
rail 10. As shown in Figs. 13 and 14, the connection unit 108 is connected between
the movable member 66 is moved by the link 106, the movable member 66 moves along
the longitudinal guide groove 78 of the guide passage 74 of the base 58. When the
first protrusion 112 is guided and engaged with the transverse groove 34 of the guide
groove 28, the protrusion 40 of the second rail 14 presses on the top of the second
protrusion 114 of the link 106. The first protrusion 112 of the link 106 is located
in the transverse groove 34 of the guide groove 28. The movable member 66 is guided
and moved, the first leg 84a is located in the transverse guide groove 80 of the guide
passage 74 and the second resilient member 68 is compressed by the second leg 84b
and generates a force in the second direction F2.
[0036] As shown in Fig. 13, when the first contact portion 138 of the synchronic member
132 contacts the release portion 26 of the first rail 10, the first contact portion
138 contacts the release portion 26 by the inclined face 142 and is temporarily positioned.
The synchronic member 132 swings an angle and the second contact portion 140 of the
synchronic member 132 is disengaged from the push block 46 of the third rail 18. Therefore,
the third rail 18 can be completely pulled relative to the first rail 10 and the distance
is prolonged by the second rail 14.
[0037] As shown in Fig. 15, when the third rail 18 is retracted relative to the first rail
10, the third rail 18 is first retracted into the second rail 14, and then the third
rail 18 and the second rail 14 are retracted relative to the first rail 10. The push
block 46 of the third rail 18 moves to the position where the push block 46 is located
corresponding to the second contact portion 140 of the synchronic member 132. The
first contact portion 138 of the synchronic member 132 is separated from the release
portion 26 of the first rail 10. The protrusion 40 of the second rail 14 does not
press on the second protrusion 114 of the link 106 after the second rail 14 moves.
[0038] As shown in Figs. 16 and 17, when the second and third rails 14, 18 are retracted
relative to the first rail 10, and the contact member 152 pushes the driving end 96
of the movable member 66 so that the first leg 84a of the movable member 66 is disengaged
from the transverse guide groove 80 of the guide passage 74 and the hooking portion
154 of the hooking member 148 is moved to the second longitudinal guide path 92 of
the movable member 66 and contacts the engaging portion 88 of the movable member 66.
The force of the second resilient member 68 in the second direction F2 is applied
to the movable member 66, the engaging portion 88 of the movable member 66 contacts
the hooking portion 154 of the hooking member 148 to retract the third rail 18 relative
to the first rail 10 to the status as shown in Fig. 8.
[0039] Alternatively, as shown in Fig. 17, a connection unit 108 is connected to the movable
member 66 and the link 106 so that the movable member 66 moves the link 106 as shown
in Fig. 18. The first protrusion 112 of the movable member 66 removes from the transverse
groove 34 of the guide groove 28 and returns to the longitudinal groove 32 of the
guide groove 28. The first spring 110 provides assistance to allow the link 106 to
swing smoothly.
[0040] As shown in Figs. 19, 20, a preferable embodiment further comprises a buffering member
160 connected to the first rail 10 and comprises a plunger 162 which is extendable
from the buffering member 160. The plunger 162 is located corresponding to the second
rail 14 and the distance that the plunger 162 extends forms a buffering travel to
the second rail 14. When the second rail 14 is retracted with the third rail 18 relative
to the first rail 10, the plunger 162 contacts the second rail 14 so that the retraction
action of the slide assembly is more stable.
[0041] While we have shown and described the embodiment in accordance with the present invention,
it should be clear to those skilled in the art that further embodiments may be made
without departing from the scope of the present invention.
1. A self-opening and self-closing slide assembly comprising:
a first rail (10) having a side wall (24), a release portion (26), a guide groove
(28) and a first passage (30), the release portion (26) located on the side wall (24)
and in the first passage (30), the guide groove (28) located on the side wall (24)
and having a longitudinal groove (32) and a transverse groove (34) which communicates
with the longitudinal groove (32);
a second rail (14) slidably connected to the first rail (10) and having a side wall
(38), a protrusion (40) and a second passage (44), the protrusion (40) connected to
the side wall (38) of the second rail (14) and facing the first passage (30) of the
first rail (10);
a third rail (18) slidably connected to the second rail (14) and having a push block
(46) facing the second passage (44) of the second rail (14);
a movable unit (50) having a base (58), a first resilient member (62), a push member
(64), a movable member (66) and a second resilient member (68), the base (58) connected
to the side wall (24) of the first rail (10) and having a longitudinal section (70),
a room (72) and a guide passage (74), the room (72) substantially parallel to the
longitudinal section (70), the guide passage (74) having a longitudinal guide groove
(78) and a transverse guide groove (80) which communicates with the longitudinal guide
groove (78), the first resilient member (62) being biased between the base (58) and
the push member (64), the push member (64) located corresponding to the second rail
(14), the movable member (66) movably connected to the base (58) and having a first
leg (84a), a second leg (84b), a guide path (86) and an engaging portion (88), the
first leg (84a) and the second leg (84b) respectively located corresponding to the
guide passage (74) and the room (72) of the base (58), the guide path (86) having
a first longitudinal guide path (90), a second longitudinal guide path (92) and a
mediate path (94), the first and second longitudinal guide paths (90, 92) located
on two sides of the engaging portion (88), the mediate path (94) communicating with
the first and second longitudinal guide paths (90, 92) and located corresponding to
the engaging portion (88), the second resilient member (68) located in the room (72)
of the base (58) and contacting the second leg (84b) of the movable member (66);
a passive unit (52) having a link (106), a connection unit (108) and a first spring
(110), the link (106) having a first protrusion (112) and a second protrusion (114),
the first protrusion (112) located in the guide groove (28) of the first rail (10),
the second protrusion (114) located corresponding to the protrusion (40) of the second
rail (14), the connection unit (108) connected between the movable member (66) and
the link (106), the first spring (110) connected between the link (106) and the connection
unit (108);
a synchronic unit (54) having a synchronic member (132) and a second spring (134),
the synchronic member (132) pivotably connected to the second rail (14) and having
a first contact portion (138) and a second contact portion (140), the first contact
portion (138) facing the side wall (24) of the first rail (10) and located corresponding
to the release portion (26), the second contact portion (140) located corresponding
to the push block (46) of the third rail (18), the second spring (134) connected between
the synchronic member (132) and the second rail (14);
a hooking unit (56) having a hooking member (148) and a contact member (152), the
hooking member (148) pivotably connected to the third rail (18) and having a hooking
portion (154), the contact member (152) fixed to the third rail (18) and located corresponding
to the movable member (66);
when the third rail (18) is located at a retracted position relative to the first
rail (10), the second rail (14) is retracted in the first rail (10), the hooking portion
(154) of the hooking member (148) is engaged with the engaging portion (88) of the
movable member (66), the push member (64) is pushed by the second rail (14) and compresses
the first resilient member (62), the first resilient member (62) generates a force
in a first direction and the force is applied to the push member (64), the second
leg (84b) of the movable member (66) contacts the second resilient member (68), the
push block (46) of the third rail (18) is located corresponding to the second contact
portion (140) of the synchronic member (132);
wherein, when the third rail (18) is pushed by a pushing force, the hooking portion
(154) of the hooking member (148) is disengaged from the engaging portion (88) of
the movable member (66) and is moved to the first longitudinal guide path (90) of
the movable member (66), when the pushing force is disappeared, the force in the first
direction of the first resilient member (62) is released, the second rail (14) is
pushed by the push member (64) and moves relative to the first rail (10), when the
third rail (18) is continuously pulled, the push block (46) of the third rail (18)
contacts the second contact portion (140) of the synchronic member (132) so that the
second rail (14) is pulled along with movement of the third rail (18), the protrusion
(40) of the second rail (14) pushes the second protrusion (114) of the link (106)
so that the first protrusion (112) of the link (106) moves along the longitudinal
groove (32) of the guide groove (28) of the first rail (10), the movable member (66)
is moved by the link (106) and the connection unit (108), the movable member (66)
moves along the longitudinal guide groove (78) of the guide passage (74) of the base
(58), when the first protrusion (112) is engaged with the transverse groove (34) of
the guide groove (28), the protrusion (40) of the second rail (14) presses on a top
of the second protrusion (114) of the link (106), the first leg (84a) is located in
the transverse guide groove (80) of the guide passage (74) and the second resilient
member (68) is compressed by the second leg (84b) and generates a force in a second
direction, when the first contact portion (138) of the synchronic member (132) contacts
the release portion (26) of the first rail (10), the synchronic member (132) swings
an angle and the second contact portion (140) of the synchronic member (132) is disengaged
from the push block (46) of the third rail (18), and
wherein, when the third rail (18) is retracted relative to the first rail (10), the
first contact portion (138) of the synchronic member (132) is separated from the release
portion (26) of the first rail (10) and the second contact portion (140) returns to
a position located corresponding to the push block (46), when the contact member (152)
pushes the movable member (66), the movable member (66) is disengaged from the transverse
guide groove (80) of the guide passage (74) and the hooking portion (154) of the hooking
member (148) contacts the engaging portion (88) of the movable member (66), the force
of the second resilient member (68) retracts the third rail (18) relative to the first
rail (10) and the first protrusion (112) of the link (106) is separated from the transverse
groove (34) of the guide groove (28).
2. The slide assembly as claimed in claim 1 further comprising a threaded block (98)
and an adjustment member (100) both located corresponding to the room (72), the adjustment
member (100) having a threaded rod (102) and a head (104) which extends from an end
of the threaded rod (102), the threaded rod (102) of the adjustment member (100) threadedly
extending through the threaded block (98), the threaded rod (102) in the room (72)
contacting the second leg (84b) of the movable member (66).
3. The slide assembly as claimed in claim 1, wherein the connection unit (108) comprises
a first connector (116) and a second connector (118) which is connected to the first
connector (116), the first connector (116) is fixed to the movable member (66) by
a fixing member (120), the second connector (118) is pivotably connected to the link
(106).
4. The slide assembly as claimed in claim 3, wherein the link (106) has a first hook
(122) and the second connector (118) has a second hook (124), the first spring (110)
is hooked between the first and second hooks (122, 124).
5. The slide assembly as claimed in claim 3, wherein a support member (126) is fixed
to the side wall (24) of the first rail (10) and has a support passage (128) in which
the second connector (118) is movably located, the support member (126) has at least
one stop wall (130) to maintain the second connector (118) in the support passage
(128).
6. The slide assembly as claimed in claim 1, wherein the side wall (38) of the second
rail (14) has a window (42) and the synchronic member (132) is located beside the
window (42) and pivotably connected to the second rail (14) by a pivot (136), the
first contact portion (138) of the synchronic member (132) extends through the window
(42) and toward the side wall (24) of the first rail (10).
7. The slide assembly as claimed in claim 6, wherein the first contact portion (138)
of the synchronic member (132) has an inclined face (142) which is located corresponding
to the release portion (26) of the first rail (10), the synchronic member (132) has
a third hook (144) and the second rail (14) has a fourth hook (146), the second spring
(134) is hooked between the third and fourth hooks (144, 146).
8. The slide assembly as claimed in claim 1, wherein the third rail (18) has an opening
(48), the hooking unit (56) comprises a cover (150) which is located corresponding
to the opening (48) is fixed to the third rail (18), the hooking member (148) is pivotably
connected to the cover (150) by a pin (156), the cover (150) has a curved slot (158)
which is located corresponding to the hooking portion (154) of the hooking member
(148), the hooking portion (154) of the hooking member (148) extends through the curved
slot (158).
9. The slide assembly as claimed in claim 1, wherein a buffering member (160) is connected
to the first rail (10) and comprises a plunger (162) which is extendable from the
buffering member (160), a distance that the plunger (162) extends forms a buffering
travel to the second rail (14).