A slide module comprises an outer rail, a ball rail, first balls and 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 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 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 linear guide bearing and an associated quick-connect system are provided. The linear guide bearing includes a carriage that moves linearly along a guide rail. The carriage includes an upper surface having a groove defined therein, and a depression formed in the groove. A tool is configured to connect to the carriage in a quick-connect fashion. To do so, the tool has a spring-loaded plunger biased downward toward the carriage. As the tool is slid along the groove of the carriage, the tip of the plunger is biased to depress into the depression in the groove. To release the tool from the carriage, a force can be applied sufficient to overcome the spring-bias force to allow the tool to lift off from the carriage.

A linear guide bearing and an associated quick-connect system are provided. The linear guide bearing includes a carriage that moves linearly along a guide rail. The carriage includes an upper surface having a groove defined therein, and a depression formed in the groove. A tool is configured to connect to the carriage in a quick-connect fashion. To do so, the tool has a spring-loaded plunger biased downward toward the carriage. As the tool is slid along the groove of the carriage, the tip of the plunger is biased to depress into the depression in the groove. To release the tool from the carriage, a force can be applied sufficient to overcome the spring-bias force to allow the tool to lift off from the carriage.

According to the disclosure, a sensor assembly, in particular for a guide, is provided, which has a sensor and an analysis device. The analysis device determines a movement profile of the guide component based on a vibration signal detected by the sensor, wherein a part of the movement profile is used for the fatigue detection. Alternatively or additionally, it can be provided that the vibration signal detected by the sensor is filtered or digitally filtered and the or a movement profile of the guide component is determined based on the filtered or digitally filtered signal.

A position detection apparatus is provided which eliminates the necessity of space to affix a scale to a track member. A track member of a motion guide apparatus is provided with a through hole into which a fastening member to fasten the track member to a base can be inserted. A carriage that is movably assembled to the track member via a rolling element is provided with magnets generating a magnetic field toward the track member. Magnetic sensors that detect a change in the magnetic fields of the magnets with the travel of the magnets relative to the track member are placed within the magnetic fields of the magnets.

A linear motion system utilizing one or more printed circuit boards embedded within a stage wherein the system components, including the controller, drive, and controller, may be mounted to a printed circuit board (PCB), and the electrical communications between the system components and the power to the system components are supplied through traces or etchings on the printed circuit board, thereby omitting the need for additional power and communication cables.

A seal member for a linear guide including a guide rail and slider movably set on the guide rail through rolling elements, the seal member, attached to the slider, configured to seal an opening of a gap between the guide rail and slider, the seal member includes: fibers having been impregnated with rubber or resin, wherein a sliding contact part of said seal member, which is in sliding contact with the guide rail, is made of the fibers.

A lubricant supply member of a linear guide includes a first recessed part formed above a guide rail, a pair of second recessed parts formed at both left and right side-surface positions of the guide rail, and protrusions slidable on rail side raceway surfaces of the guide rail. A lubricating unit includes a first cylindrical part, arranged in the first recessed part, to allow the first recessed part to move in a vertical direction of the slider, and to press the first recessed part to a widthwise outside of the slider, and a pair of second cylindrical parts, arranged in the pair of second recessed parts, to allow the pair of second recessed parts to move in a width direction of the slider, and to press the pair of second recessed parts in the vertical direction of the slider, respectively.

A linear slide rail includes a rail having four primary grooves respectively defined in two opposite sides of the rail. A first slide includes a first passage, and each of two opposite insides of the first passage has two first grooves. Multiple first balls contact the primary grooves and the first grooves. Each of the first grooves has a first contact angle. When a first wearing trace is formed along the rail by the first balls and the first slide, the first slide and the first balls are replaced with a second slide and multiple second balls. Each of the second grooves of the second slide has a second contact angle which is different from the first contact angle. A second wearing trace is formed along the rail by the second balls and the second slide. The first and second wearing traces are not overlapped with each other.

A motion guide apparatus ensures that a retaining portion retains a rolling element. A rolling element retainer having retaining portions that prevent a rolling element from falling out of a movable body, the retaining portions extending along a loaded rolling element rolling portion, is incorporated in the movable body of the motion guide apparatus. End plates are formed integrally with the retaining portions. Fall prevention portions to reduce the widths of openings between the retaining portions are provided to center parts of the retaining portions in a length direction thereof. The fall prevention portions are padding portions integrated with the retaining portions, the padding portions rising in such a manner as to reduce the widths of the openings, and/or projections integrated with the retaining portions, the projections touching the movable body in such a manner that the center parts of the retaining portions bend toward a track member.