A portable multidirectional surface device, which may include one or more slide bearing glides and one or more base lengths which may are positioned adjacent the one or more slide bearing glides. One or more connecting plates, positioned above the base length(s), is connect with the base length(s) and the slide bearing glide(s). Providing motion to the device are multidirectional contact point(s) which are connected to the one or more connecting plates. The slide bearing glide(s) in conjunction with the base length(s) enable the use and operation of tools with the device.

A portable multidirectional surface device, which may include one or more slide bearing glides and one or more base lengths which may are positioned adjacent the one or more slide bearing glides. One or more connecting plates, positioned above the base length(s), is connect with the base length(s) and the slide bearing glide(s). Providing motion to the device are multidirectional contact point(s) which are connected to the one or more connecting plates. The slide bearing glide(s) in conjunction with the base length(s) enable the use and operation of tools with the device.

The present disclosure provides an apparatus, method and kit to flatten wide boards with an apparatus. The apparatus comprises two sets of rails, one set spanning laterally and the second set spanning longitudinally. The second set of rails is operative to move along the first set of rails by use of short members attached to the second set that interface with the first set of rails. Then, a carriage is operative to sit on top of the second set of rails and move along them. This is done by the carriage arms engaged on the second set of rails.

The present disclosure provides an apparatus, method and kit to flatten wide boards with an apparatus. The apparatus comprises two sets of rails, one set spanning laterally and the second set spanning longitudinally. The second set of rails is operative to move along the first set of rails by use of short members attached to the second set that interface with the first set of rails. Then, a carriage is operative to sit on top of the second set of rails and move along them. This is done by the carriage arms engaged on the second set of rails.

A cutter head assembly includes a drive shaft, a blade carrier and a blade unit. The drive shaft has a longitudinal axis and is made of steel. The blade carrier is sleeved and retained on the drive shaft. The blade carrier has a length extending parallel to the longitudinal axis and is made of aluminum alloy. The blade unit is disposed on the blade carrier and surrounds the longitudinal axis.

A cutter head assembly includes a drive shaft, a blade carrier and a blade unit. The drive shaft has a longitudinal axis and is made of steel. The blade carrier is sleeved and retained on the drive shaft. The blade carrier has a length extending parallel to the longitudinal axis and is made of aluminum alloy. The blade unit is disposed on the blade carrier and surrounds the longitudinal axis.

The chip guiding device comprises a shield configured to be arranged at a rotating axis (A) of one of the machine moulder's cutter heads, such that the shield, when the machine moulder is in operation, guides the chips cut by the cutter head's cutter knives from a workpiece into a hose connected with the chip extractor. The shield may be configured to rotate together with the cutter head. The shield may be circular formed with a central hole for arranging the shield at the rotating axis (A). The shield may be provided with fan means to increase an airflow towards the hose. By providing the cutter heads of a machine moulder with chip guiding devices at the rotating axes, connected chip extractors may collect larger amounts of cut chips, and contribute to improved performance of the machine moulder.

A hand-held power tool includes a housing, a first shoe movably coupled to the housing, a second shoe fixedly coupled to the housing, a rotating cutting tool disposed between the first shoe and the second shoe, and a depth adjustment mechanism configured to adjust a position of the first shoe relative to the second shoe. The rotating cutting tool is configured to engage a workpiece. The depth adjustment mechanism includes a rotary handle and an inner shaft. The inner shaft is fixedly coupled to the first shoe and threadedly coupled to the rotary handle. The first shoe translates relative to the second shoe in response to rotation of the rotary handle.

A cutter head assembly includes a drive shaft, a blade carrier and a blade unit. The drive shaft has a longitudinal axis and is made of steel. The blade carrier is sleeved and retained on the drive shaft. The blade carrier has a length extending parallel to the longitudinal axis and is made of aluminum alloy. The blade unit is disposed on the blade carrier and surrounds the longitudinal axis.

A cutter head assembly includes a drive shaft, a blade carrier and a blade unit. The drive shaft has a longitudinal axis and is made of steel. The blade carrier is sleeved and retained on the drive shaft. The blade carrier has a length extending parallel to the longitudinal axis and is made of aluminum alloy. The blade unit is disposed on the blade carrier and surrounds the longitudinal axis.