Provided is a device for supporting solar modules, including a base rail having a first receiving opening , a support, the support having a first connecting element which is arranged in the first receiving opening, and a securing rail which is arranged on the base rail so as to at least partially encompass the base rail and is movable along the base rail. The securing rail at least partially closes the first receiving opening in a second position so that a movement of the first connecting element out of the first receiving opening is prevented. The securing rail unblocks the first receiving opening in the first position in such a way that a movement of the first connecting element out of the first receiving opening is made possible. Furthermore, a kit, a method for manufacturing a device, and a solar module arrangement are provided.

Provided is a device for supporting solar modules, including a base rail having a first receiving opening , a support, the support having a first connecting element which is arranged in the first receiving opening, and a securing rail which is arranged on the base rail so as to at least partially encompass the base rail and is movable along the base rail. The securing rail at least partially closes the first receiving opening in a second position so that a movement of the first connecting element out of the first receiving opening is prevented. The securing rail unblocks the first receiving opening in the first position in such a way that a movement of the first connecting element out of the first receiving opening is made possible. Furthermore, a kit, a method for manufacturing a device, and a solar module arrangement are provided.

A series of photovoltaic panels (PV) arranged on a planar, horizontal support platform so as to form a PV array that is pivotally connected to a PV array support structure that can pivotally raise, angle and support the PV array above agricultural fields at heights that allow the passage of large mechanized farm equipment to pass beneath. The PV array support structure pivotally raises its PV array into its operating elevation and positional range with a system of motorized pivot arms operationally positioned between its array columns and the members of the support frame. Once in place, these PV arrays may be horizontally moved by tilting or angling the array columns within a specified operating range (by computer positioning known as dynamic shifting). At the same time, the PV panels may all be optimally tilted for sun sharing and sun shading for both the generation of electricity and to increase the agricultural efficiency of the underlying land.

An absorber system solves problems of known absorber systems for use in solar fields in that the absorber tube is suspended on a rail below an absorber cover. The design also makes it possible to move measuring and cleaning robots and the like along the absorber tube more and allows the absorber tube and the secondary reflector to be jointly suspended, whereby an exact mutual alignment between the two components is enabled.

An absorber system solves problems of known absorber systems for use in solar fields in that the absorber tube is suspended on a rail below an absorber cover. The design also makes it possible to move measuring and cleaning robots and the like along the absorber tube more and allows the absorber tube and the secondary reflector to be jointly suspended, whereby an exact mutual alignment between the two components is enabled.

An absorber system solves problems of known absorber systems for use in solar fields in that the absorber tube is suspended on a rail below an absorber cover. The design also makes it possible to move measuring and cleaning robots and the like along the absorber tube more and allows the absorber tube and the secondary reflector to be jointly suspended, whereby an exact mutual alignment between the two components is enabled.

An absorber system solves problems of known absorber systems for use in solar fields in that the absorber tube is suspended on a rail below an absorber cover. The design also makes it possible to move measuring and cleaning robots and the like along the absorber tube more and allows the absorber tube and the secondary reflector to be jointly suspended, whereby an exact mutual alignment between the two components is enabled.

Disclosed is an optomechanical system (10) for capturing and transmitting incident light (40) with a variable direction of incidence to at least one collecting element (31, 31′, 31″, 31″′, 31A, 31B), with an optical arrangement (20) able to capture a beam of the incident light (40), concentrate the captured beam of the incident light, and transmit one or more concentrated beams (50) of the incident light to the at least one collecting element (31, 31′, 31″, 31″′, 31A, 31B), and a shifting mechanism for moving the optical arrangement (20) with respect to the at least one collecting element (31, 31′, 31″, 31′″, 31A, 31B), wherein the moving of the shifting mechanism is controllable in such a way that, for any direction of incidence of the incident light (40), the one or more concentrated beams (50) of the incident light can be optimally collected by the at least one collecting element (31, 31′, 31″, 31′″, 31A, 31B), In this optomechanical system (10), the optical arrangement (20) comprises a first optical layer made of optical lenses having an aspheric curvature, and at least one surface of the lenses has a polynomial curvature with multiple orders. Furthermore, the present invention also relates to a corresponding method for capturing and transmitting incident light with a variable direction of incidence to at least one collecting element.

A supporting and handling system for optical devices, in particular telescopes, radio-telescopes or sun concentrators, and instrumentation, is described, comprising: a primary unit; an independent secondary unit; first motored means for moving the primary unit; second motored means for moving the secondary unit; an arc-shaped structure equipped with sliding guides in altitude with respect to the ground for the rotation of the secondary unit with respect to an altitude rotation axis; a hexapod system to move the primary unit; and a control system.

Shade house for casting an adjustable shadow over a surface, the shade house including: at least one frame extending in a longitudinal direction; a first set of photovoltaic panels mounted on the frame substantially orthogonally to a same orientation axis; a second set of opaque panels, for preference photovoltaic, mounted on the frame and movable in longitudinal translation relative to the frame at least between an open configuration, in which the panels are at least partially superposed over the panels in a view along the orientation axis, and a closed configuration, in which the panels at least partially extend beyond the panels in a view along the orientation axis; and an actuation system configured to actuate the second set at least from the open configuration to the closed configuration, and vice versa, the actuation system including pulleys mounted on the frame.