Abstract: A method of fabricating a multijunction solar cell array on a carrier using one or more automated processes, the method comprising providing a first multijunction solar cell including a first contact pad and a second contact pad disposed adjacent the top surface of the multijunction solar cell along a first peripheral edge thereof attaching a first electrical interconnect to the first contact pad of said first multijunction solar cell using a pick and place process attaching a second electrical interconnect to the second contact pad of the first multijunction solar cell using a pick and place process positioning in the first multijunction solar cell over an adhesive region of a permanent carrier using an automated machine/vision apparatus and bonding the first multijunction solar cell to the adhesive region using pressure and/or heat.

Abstract: A method of fabricating a multijunction solar cell panel by providing a plurality of multijunction solar cells; dispensing out uncured silicone coating on the solar cells using an automated process with visual recognition, and curing the silicone coating on the solar cell to complete the Cell-Interconnect-Cover Glass (CIC) assembly.

Abstract: A method of fabricating a multijunction solar cell panel by providing a plurality of multijunction solar cells; dispensing out uncured silicone coating on the solar cells using an automated process with visual recognition, and curing the silicone coating on the solar cell to complete the Cell-Interconnect-Cover Glass (CIC) assembly.

Abstract: The present disclosure provides methods of fabricating a multijunction solar cell panel in which one or more of the steps are performed using an automated process. In some embodiments, the automated process uses machine vision.

Abstract: A solar cell receiver for use in a concentrating solar system which concentrates the solar energy onto a solar cell for converting solar energy to electricity. The solar cell receiver may include a solar cell mounted on a support and with one or more III-V compound semiconductor layers. An optical element may be positioned over the solar cell and have an optical channel with an inlet that faces away from the solar cell and an outlet that faces towards the solar cell. A frame may be positioned over the support and extend around the solar cell with the frame having an inner side that extends above the support and faces towards the optical element. An encapsulant may be positioned over the support and contained between the optical element and the frame. The encapsulant may have enlarged heights at contact points with the optical element and the frame and a reduced height between the contact points away from the optical element and the frame. The solar cell receiver may be used in a solar cell module.

Abstract: A solar cell module to convert light to electricity. The module may include a housing with a first side and an opposing spaced-apart second side. A plurality of lenses may be positioned on the first side of the housing, and a plurality of solar cell receivers may be positioned on the second side of the housing. Each of the plurality of solar cell receivers may include a III-V compound semiconductor multifunction solar cell. Each may also include a bypass diode coupled with the solar cell. At least one optical element may be positioned above the solar cell to guide the light from one of the lenses onto the solar cell. Each of said solar cell receivers may be disposed in an optical path of one of the lenses. The lens and the at least one optical element may concentrate the light onto the respective solar cell by a factor of 1000 or more to generate in excess of 25 watts of peak power.

Abstract: Solar cell modules for converting solar energy into electrical energy, such as used in a concentrating photovoltaic system. The modules have a first ventilating opening in the module housing; and a ventilating subassembly mounted on the module housing and disposed over the ventilating opening in the module housing. The ventilating subassembly has a housing having a first chamber adjacent to and in communication with the first ventilating opening in the module housing; a second chamber adjacent to the first chamber, the second chamber having a second ventilating opening to the external environment; and a filter membrane separating the first chamber from the second chamber to allow air to flow between the first chamber and the second chamber through the filter membrane.

Abstract: A solar cell receiver for use in a concentrating solar system which concentrates the solar energy onto a solar cell for converting solar energy to electricity. The solar cell receiver may include a solar cell mounted on a support and with one or more III-V compound semiconductor layers. An optical element may be positioned over the solar cell and have an optical channel with an inlet that faces away from the solar cell and an outlet that faces towards the solar cell. A frame may be positioned over the support and extend around the solar cell with the frame having an inner side that extends above the support and faces towards the optical element. An encapsulant may be positioned over the support and contained between the optical element and the frame. The encapsulant may have enlarged heights at contact points with the optical element and the frame and a reduced height between the contact points away from the optical element and the frame. The solar cell receiver may be used in a solar cell module.

Abstract: A solar cell receiver for use in a concentrating solar system which concentrates the solar energy onto a solar cell for converting solar energy to electricity. The solar cell receiver may include a solar cell mounted on a support and with one or more III-V compound semiconductor layers. An optical element may be positioned over the solar cell and have an optical channel with an inlet that faces away from the solar cell and an outlet that faces towards the solar cell. A frame may be positioned over the support and extend around the solar cell with the frame having an inner side that extends above the support and faces towards the optical element. An encapsulant may be positioned over the support and contained between the optical element and the frame. The encapsulant may have enlarged heights at contact points with the optical element and the frame and a reduced height between the contact points away from the optical element and the frame. The solar cell receiver may be used in a solar cell module.

Abstract: Solar cell modules for converting solar energy into electrical energy, such as used in a concentrating photovoltaic system. The modules have a first ventilating opening in the module housing; and a ventilating subassembly mounted on the module housing and disposed over the ventilating opening in the module housing. The ventilating subassembly has a housing having a first chamber adjacent to and in communication with the first ventilating opening in the module housing; a second chamber adjacent to the first chamber, the second chamber having a second ventilating opening to the external environment; and a filter membrane separating the first chamber from the second chamber to allow air to flow between the first chamber and the second chamber through the filter membrane.

Abstract: A solar cell receiver for use in a concentrating solar system which concentrates the solar energy onto a solar cell for converting solar energy to electricity. The solar cell receiver may include a solar cell mounted on a support and with one or more III-V compound semiconductor layers. An optical element may be positioned over the solar cell and have an optical channel with an inlet that faces away from the solar cell and an outlet that faces towards the solar cell. A frame may be positioned over the support and extend around the solar cell with the frame having an inner side that extends above the support and faces towards the optical element. An encapsulant may be positioned over the support and contained between the optical element and the frame. The encapsulant may have enlarged heights at contact points with the optical element and the frame and a reduced height between the contact points away from the optical element and the frame. The solar cell receiver may be used in a solar cell module.

Abstract: According to an embodiment, a solar cell receiver for converting solar energy to electricity includes a ceramic substrate, a solar cell and a heat sink. The ceramic substrate has a first metallized surface and an opposing second metallized surface. The first metallized surface of the ceramic substrate has separated conductive regions. The solar cell has a conductive first surface connected to a first one of the conductive regions of the ceramic substrate and an opposing second surface having a conductive contact area connected to a second one of the conductive regions. The heat sink is bonded to the second metallized surface of the ceramic substrate with a thermally conductive attach media, such as a metal-filled epoxy adhesive or solder.

Abstract: A solar cell module to convert light to electricity. The module may include a housing with a first side and an opposing spaced-apart second side. A plurality of lenses may be positioned on the first side of the housing, and a plurality of solar cell receivers may be positioned on the second side of the housing. Each of the plurality of solar cell receivers may include a III-V compound semiconductor multifunction solar cell. Each may also include a bypass diode coupled with the solar cell. At least one optical element may be positioned above the solar cell to guide the light from one of the lenses onto the solar cell. Each of said solar cell receivers may be disposed in an optical path of one of the lenses. The lens and the at least one optical element may concentrate the light onto the respective solar cell by a factor of 1000 or more to generate in excess of 25 watts of peak power.