A full pull-out guide for furniture parts, in particular for drawers, with a lower structural height, and including a body rail that can be attached to a stationary furniture part, a running rail that can be attached to a movable furniture part, a middle rail, an inner running path arranged between the body rail and the middle rail, on which a plurality of first force-transferring elements are movably arranged, and an outer running path arranged between the middle rail and the running rail, on which a plurality of second force-transferring elements are arranged. Due to the horizontal displacement of the outer first force-transferring element, the structural height of the full pull-out direction can be reduced. Furthermore, the horizontal displacement of the outer first force-transferring element in relation to other force-transferring elements has the effect that the contact surface to the rails exists in different vertical planes.

A drawer glide mechanism can include a first elongate guide member, a second elongate glide member, a ball bearing component, and a v-notch socket. The first elongate guide member includes a distal end that is configured to fit within an opening in the v-notch socket. The drawer glide mechanism can further include one or more floating members and fixed members.

Disclosed is a pullout apparatus having side access and designed for simple, adjustable, and accurate installation within a pre-existing cabinet space. The apparatus, slidably mounted within the cabinet space, comprises a top slide assembly mounted to a cabinet carcass and a drawer box. The drawer box is automatically centered on a base slide box. The base slide box is comprised of a slotted template slidingly engaged with a frame, where the frame is mounted to the cabinet carcass. Slide rail assemblies connect the slotted template to the frame. A pin block on the underside of a fixed shelf of the drawer box automatically centers the drawer box on the slotted template. A face plate adjustment mechanism provides for three dimensional alignment of the face plate with surrounding cabinets. An alternate embodiment comprises a mounting bracket providing three dimensional adjustability of the upper drawer slide.

A slide rail assembly includes at least two slide rails, a slide-facilitating device, and a supporting structure. The slide-facilitating device enables the two slide rails to be displaced smoothly with respect to each other. The supporting structure serves to support a rail section of one of the two slide rails.

A drawer latch comprising a base configured to couple to a first slide member, a drawer stop disposed on the base and positioned to contact a second slide member at a retracted position within the first slide member, and a least one arm extending from the base in a direction parallel to an axis of the first slide member and towards the second slide member, a distal portion of the arm having a protrusion configured to engage an indent disposed on a side of the second slide member when the second slide member is in the retracted position.

A refrigerator appliance includes a drawer slide synchronizer with a first cable and a second cable. A first bearing is mounted to a first one of a pair of drawer slides, and a second bearing is mounted to a second one of the pair of drawer slides. The first and second cables contact the first bearing, and the first and second cables also contact the second bearing.

A slide module is disclosed, which comprises an outer rail, a ball rail, a plurality of first balls and a plurality of second balls. The outer rail has a first inner surface and a second inner surface. The ball rail has a first holding section and a second holding section. The first balls are rollably disposed in a plurality of first limiting holes of the first holding section in which the first ball is contacted with the first inner surface and the second holding section and distant from the second inner surface. The second balls are rollably disposed in a plurality of second limiting holes of the second holding section in which the second ball is contacted with the second inner surface and the first holding section and distant from the inner surface. Thereby, the ball rail is capable of moving along the axial direction with respect to the outer rail through the first balls and the second balls.

A slide rail assembly includes a first rail, a second rail, and a supporting member. The second rail can be displaced with respect to the first rail. The supporting member is connected to the second rail and includes an upper supporting portion and a lower supporting portion. The upper supporting portion is used for supporting an upper wall of the first rail, and the lower supporting portion, for supporting a lower wall of the first rail.

A drawer system including: a drawer cabinet and a drawer mounted in said cabinet for forward and backward travel relative thereto; said cabinet having two opposed spaced apart side walls and at least two lower wheels mounted to each side wall and spaced apart in the intended direction of travel of the drawer; said drawer having two opposed spaced apart side panels and at least two lower wheels mounted to each side panel and spaced apart in the intended direction of travel of the drawer; and a runner mounted on said lower cabinet wheels of each side wall for forward and backward travel relative to said cabinet via a first track and each runner including a second track engaged by said spaced apart lower drawer wheels for forward and backward travel for said drawer relative to said runner.

A three-rows-of-ball bearings sliding rail is disclosed. An inner sliding rail body (1) is supported in outer sliding rail bodies (2-1, 2-2) through three rows of support ball bearings (3-1, 3-2, 3-3) which are arranged in parallel in a lengthwise direction of the inner sliding rail body. The three rows of support ball bearings (3-1, 3-2, 3-3) are respectively limited within a length range of the outer sliding rail bodies (2-1, 2-2) via ball retainers (4). Each of the outer sliding rail bodies (2-1, 2-2) includes a bottom plate (21), a first side wall (221) and a second side wall (222) which are respectively located at two sides in a widthwise direction of the bottom plate (21), are integrally formed with the bottom plate (21) and extended in a lengthwise direction of the bottom plate (21). The first side wall (221) includes a first arm and a supporting part (2211) which is bent inwardly and extends horizontally from a bottom end of the first arm. The second side wall (222) includes a second arm and an arc-shaped part (2221) which is bent inwardly from a bottom end of the second arm and integrally formed with the second arm. The three rows of support ball bearings (3-1, 3-2, 3-3) are respectively located within an upper inner corner end and a lower inner corner end of the first side wall (221), and the arc-shaped part (2221) in a cross section of the outer sliding rail bodies (2-1, 2-2); and connection lines of centers of the three rows of support ball bearings (3-1, 3-2, 3-3) form an equilateral triangle in the cross section of the outer sliding rail bodies (2-1, 2-2). This sliding rail can solve the problem of insufficient bearing capacity in the existing three-rows-of-ball bearings sliding rail, and can meet installation space requirements for a hidden sliding rail.