The present invention relates to a workbench, and respective operating and manufacturing methods, for the cold intervention, folding, bending or deformation of metal plates or sheets, the constructive and functional features of which provide a solution to achieve an optimal balance between power and flexibility, such that it allows performing custom works on metal plates or sheets under power conditions that exceed human capacity. In that sense, the workbench provides a work area with multiple actuation and power options, constituting a plethora of possible combinations for the intervention, folding, bending, twisting or deformation of metal sheets of different shapes.

A truss designed folding Apparatus. The apparatus may be constructed of a first apparatus top section and a second apparatus top section which may be pivotally connected together by a center support structure. The apparatus may have two sets of legs. A first set of legs may be movably attached to the center support structure and a second set of legs may also be movably attached to the center support structure. Each set of legs may also be attached to the apparatus top via a first and a second leg support extending from the legs to the apparatus top sections. A shelf connection may be placed between the first and second leg support wherein, a shelf attached to each pair of legs the shelf may have a first section and second section, wherein the sections are attached to each other at opposite ends of the shelf connection.

A retainer is placed on a retainer holding portion formed on a sample chip worktable. With an operation of a button, a take-out support mechanism operates. That is, an upthrust pin moves upward. With this process, an orientation of a sample chip stored in the retainer is changed from a horizontal orientation to an inclined orientation. A plurality of openings through which the upthrust pin passes are formed in the retainer.

A retainer is placed on a retainer holding portion formed on a sample chip worktable. With an operation of a button, a take-out support mechanism operates. That is, an upthrust pin moves upward. With this process, an orientation of a sample chip stored in the retainer is changed from a horizontal orientation to an inclined orientation. A plurality of openings through which the upthrust pin passes are formed in the retainer.

Described herein is an arm supporting exoskeleton, comprising an arm link mechanism. The arm link mechanism comprises a proximal link, a distal link, an arm coupler, and a variable force generator. The distal link is rotatable relative to the proximal link. The arm coupler is adapted to couple an upper arm of a person to the distal link. The variable force generator comprises a first spring and a second spring, configured to create a torque between the proximal link and the distal link. In the first force mode, the variable force generator exhibits a first stiffness rate defined by the first spring that supports the upper arm of the person against gravity forces and. In the second force mode, the variable force generator exhibits a second stiffness rate defined by the first spring and the second spring that supports the upper arm of the person against the gravity forces.

Described herein is an arm supporting exoskeleton, comprising an arm link mechanism. The arm link mechanism comprises a proximal link, a distal link, an arm coupler, and a variable force generator. The distal link is rotatable relative to the proximal link. The arm coupler is adapted to couple an upper arm of a person to the distal link. The variable force generator comprises a first spring and a second spring, configured to create a torque between the proximal link and the distal link. In the first force mode, the variable force generator exhibits a first stiffness rate defined by the first spring that supports the upper arm of the person against gravity forces and. In the second force mode, the variable force generator exhibits a second stiffness rate defined by the first spring and the second spring that supports the upper arm of the person against the gravity forces.

The present disclosure relates to a support assembly, an assembling tooling and an assembling method, wherein the support assembly includes: a fixing member extending in a first direction; a first hinge member, stacked on the fixing member on a second direction and connected to the fixing member; a support member, spaced apart from the first hinge member in the first direction, and stacked on the fixing member on the second direction and connected to the fixing member; wherein in the second direction, a height of the support member is higher than that of the first hinge member, the first hinge member is adapted to rotatably connect with the tower tube segment and serve as a rotation fulcrum of the tower tube segment, and the support member is adapted to support the tower tube segment to maintain a position of the tower tube segment relative to the first hinge member.

The present disclosure relates to a support assembly, an assembling tooling and an assembling method, wherein the support assembly includes: a fixing member extending in a first direction; a first hinge member, stacked on the fixing member on a second direction and connected to the fixing member; a support member, spaced apart from the first hinge member in the first direction, and stacked on the fixing member on the second direction and connected to the fixing member; wherein in the second direction, a height of the support member is higher than that of the first hinge member, the first hinge member is adapted to rotatably connect with the tower tube segment and serve as a rotation fulcrum of the tower tube segment, and the support member is adapted to support the tower tube segment to maintain a position of the tower tube segment relative to the first hinge member.

A jig for finishing a workpiece with a handheld router or other handheld motor-driven rotational tool assembly is provided. The jig includes a baseplate that is precisely aligned and attached to a router. Guides, including a main guide and a support guide, are provided. The main guide is configured to precisely align with and fasten to the base plate in several different jig configurations. Right-angle adaptors attach to the guides and precisely align with and attach to the guides and the base plate to form several different jig configurations. Side plates secure the workpiece therebetween and provide a surface along which the main guide may slide to facilitate finishing operations on the workpiece.

A jig for finishing a workpiece with a handheld router or other handheld motor-driven rotational tool assembly is provided. The jig includes a baseplate that is precisely aligned and attached to a router. Guides, including a main guide and a support guide, are provided. The main guide is configured to precisely align with and fasten to the base plate in several different jig configurations. Right-angle adaptors attach to the guides and precisely align with and attach to the guides and the base plate to form several different jig configurations. Side plates secure the workpiece therebetween and provide a surface along which the main guide may slide to facilitate finishing operations on the workpiece.