A power battery cooling system of an electric vehicle, including: a cooling circuit configured for cooling a power battery of the electric vehicle; a solar sunroof; and a sunroof control unit configured for controlling the operation of the cooling circuit and the electric energy output of the solar sunroof; wherein the sunroof control unit is configured to start a power battery cooling operation based on the solar sunroof in the condition that the power battery is not in a high voltage output state and the temperature of the power battery is higher than a temperature threshold, the power battery cooling operation including: controlling the solar sunroof to output electric energy to the cooling circuit so that the cooling circuit performs the cooling of the power battery using the electric energy from the solar sunroof.

At least first and second solar panels are provided, wherein: each of the first and second solar panels is comprised of a substrate having one or more solar cells bonded thereto, and a frame for supporting the substrate and the solar cells; the frame has a cutout or opening in a center of the frame under the solar cells and, when deployed, the cutout or opening enables cooling of the solar cells through the substrate by exposing a back side of the substrate for transferring or radiating heat directly through the cutout or opening of the frame; and the frame of the first solar panel is configured to be nested inside the cutout or opening of the frame of the second solar panel when the first and second solar panels are stowed in a stacked configuration.

At least first and second solar panels are provided, wherein: each of the first and second solar panels is comprised of a substrate having one or more solar cells bonded thereto, and a frame for supporting the substrate and the solar cells; the frame has a cutout or opening in a center of the frame under the solar cells and, when deployed, the cutout or opening enables cooling of the solar cells through the substrate by exposing a back side of the substrate for transferring or radiating heat directly through the cutout or opening of the frame; and the frame of the first solar panel is configured to be nested inside the cutout or opening of the frame of the second solar panel when the first and second solar panels are stowed in a stacked configuration.

A heat dissipation apparatus and a photovoltaic inverter are related to the field of heat dissipation device technologies, to improve a heat dissipation capability of the heat dissipation apparatus. The heat dissipation apparatus includes at least two stacked fan layers, and each fan layer includes at least one fan. A heat dissipation channel in a radiator has a first inlet, and the first inlet communicates with each air exhaust vent in at least one fan layer by using an air duct component. Compared with a solution in which fans are arranged along a width direction of the radiator, the at least two fan layers are stacked, which may not be limited by a width of the radiator. More fans can be arranged in a hierarchical stacking manner, and more fans can increase an overall amount of exhausted air, thereby improving the heat dissipation capability of the heat dissipation apparatus.

Systems, methods, and articles for a portable power case are disclosed. The portable power case is comprised of at least one battery and at least one PCB. The portable power case has at least two access ports and at least one USB port. The portable power case is operable to supply power to an amplifier, a radio, a wearable battery, a mobile phone, and a tablet. The portable power case is operable to be charged using solar panels, vehicle batteries, AC adapters, non-rechargeable batteries, and generators. The portable power case provides for modularity that allows the user to disassemble and selectively remove the batteries installed within the portable power case housing.

Systems, methods, and articles for a portable power case are disclosed. The portable power case is comprised of at least one battery and at least one PCB. The portable power case has at least two access ports and at least one USB port. The portable power case is operable to supply power to an amplifier, a radio, a wearable battery, a mobile phone, and a tablet. The portable power case is operable to be charged using solar panels, vehicle batteries, AC adapters, non-rechargeable batteries, and generators. The portable power case provides for modularity that allows the user to disassemble and selectively remove the batteries installed within the portable power case housing.

A method for control of a cooling device for the active cooling of a perovskite solar cell, wherein the perovskite solar cell is part of a perovskite photovoltaic module. The method includes determining a measure of the internal temperature of the perovskite solar cell and activating the cooling device when the determined measure of the internal temperature of the perovskite solar cell is greater than a corresponding measure of a predetermined temperature threshold value. A photovoltaic apparatus having a perovskite photovoltaic module includes at least one perovskite solar cell, and a cooling device for the active cooling of the perovskite solar cell.

A method for control of a cooling device for the active cooling of a perovskite solar cell, wherein the perovskite solar cell is part of a perovskite photovoltaic module. The method includes determining a measure of the internal temperature of the perovskite solar cell and activating the cooling device when the determined measure of the internal temperature of the perovskite solar cell is greater than a corresponding measure of a predetermined temperature threshold value. A photovoltaic apparatus having a perovskite photovoltaic module includes at least one perovskite solar cell, and a cooling device for the active cooling of the perovskite solar cell.

The present invention refers to a heat sink (5) for bi-facial photovoltaic modules (3) configured to be secured to the back side (3b) of at least one bi-facial photovoltaic module (3) wherein the heat sink (5) comprises a plurality of rods (11) having a thermal conductivity higher than 10 W.m.sup.−1.K.sup.−1 and arranged as a mesh configured to be in contact with the back side (3b) of the bi-facial photovoltaic module (3).

The present invention refers to a heat sink (5) for bi-facial photovoltaic modules (3) configured to be secured to the back side (3b) of at least one bi-facial photovoltaic module (3) wherein the heat sink (5) comprises a plurality of rods (11) having a thermal conductivity higher than 10 W.m.sup.−1.K.sup.−1 and arranged as a mesh configured to be in contact with the back side (3b) of the bi-facial photovoltaic module (3).