阅读说明：本技术 太阳能模块安装支架组合件 (Solar module mounting bracket assembly ) 是由 T·J·沃森 R·德尔加多-尼亚涅斯 于 2019-08-29 设计创作，主要内容包括：一种太阳能模块安装支架组合件包含经配置以在其上支撑太阳能模块的轨及一对支撑件。所述支撑件每一者具有可移动地耦合到所述轨的第一端部。所述支撑件可相对于所述轨在折叠配置与展开配置之间移动。在所述展开配置中,所述支撑件协作地界定通道,所述通道经确定尺寸用于接纳框架部件。(A solar module mounting bracket assembly includes a rail configured to support a solar module thereon and a pair of supports. The supports each have a first end movably coupled to the rail. The support is movable relative to the rail between a folded configuration and an unfolded configuration. In the deployed configuration, the supports cooperatively define a channel sized for receiving a frame member.)

1. A solar module mounting bracket assembly, comprising:

a rail configured to support a solar module thereon; and

a pair of supports each having a first end movably coupled to the rail, wherein the pair of supports are movable relative to the rail between a folded configuration and an unfolded configuration in which the pair of supports cooperatively define a channel sized for receiving a frame member.

2. The solar module mounting bracket assembly of claim 1, wherein the pair of supports are parallel to the rail in the folded configuration and perpendicular to the rail in the unfolded configuration.

3. The solar module mounting bracket assembly of claim 1, wherein the solar module mounting bracket assembly is substantially linear in shape when the pair of supports are in the folded configuration, and wherein the solar module mounting bracket assembly is substantially triangular in shape when the pair of supports are in the unfolded configuration.

4. The solar module mounting bracket assembly of claim 1, further comprising a fastener configured to attach to a second end of each of the pair of supports to secure the pair of supports in the deployed configuration.

5. A solar module mounting bracket assembly according to claim 1, further comprising a pair of truss arms, wherein each of the pair of truss arms includes:

a first end movably coupled to respective second ends of the pair of supports; and

a second end movably coupled to respective first and second ends of the rail.

6. The solar module mounting bracket assembly of claim 5, wherein the pair of truss arms are configured to move relative to the rail and the pair of supports between a folded configuration in which the pair of truss arms are parallel to the rail and the pair of supports and an unfolded configuration in which the pair of truss arms extend perpendicularly relative to the rail.

7. The solar module mounting bracket assembly of claim 6, wherein the second end of each of the pair of truss arms is configured to slide off a central portion of the rail when the pair of truss arms are moved to the collapsed configuration.

8. The solar module mounting bracket assembly of claim 6, wherein the second end of each of the pair of truss arms moves along the rail from an inward position in which the pair of truss arms are in the expanded configuration toward an outward position in which the pair of truss arms are in the collapsed configuration.

9. The solar module mounting bracket assembly of claim 6, wherein each of the first and second ends of the rail defines a track through which the respective second ends of the pair of truss arms slide.

10. The solar module mounting bracket assembly of claim 9, further comprising a fastener assembly coupled to the second end of a first truss arm of the pair of truss arms, wherein the fastener assembly is configured to selectively secure the second end of the first truss arm in position on the track of the track.

11. The solar module mounting bracket assembly of claim 10, wherein the fastener assembly includes:

a pair of washers disposed on opposite sides of the rail, at least a first washer of the pair of washers having a pair of first and second lugs extending therefrom, the pair of first and second lugs configured to be received in corresponding slots defined in the rail; and

a fastener coupling the pair of washers to each other and configured to adjust a distance between the pair of washers.

12. The solar module mounting bracket assembly of claim 11, wherein the first washer of the fastener assembly further includes a third lug extending therefrom, the third lug disposed in the track of the rail to guide the fastener assembly through the track.

13. The solar module mounting bracket assembly of claim 1, further comprising a protrusion projecting downward relative to a bottom side of the rail, wherein the protrusion extends into the channel defined by the pair of supports when the pair of supports are in the deployed configuration.

14. The solar module mounting bracket assembly of claim 1, wherein each of the pair of supports has a concave inner surface such that the channel cooperatively defined by the first and second supports has a circular shape.

15. The solar module mounting bracket assembly of claim 1, further comprising a plurality of coupling devices disposed on an upper side of the rail, wherein the plurality of coupling devices are configured to secure a solar module to the rail.

16. A PV module mounting bracket assembly, comprising:

a rail configured to support a PV module thereon and having a first end, a central portion, and a second end; a pair of supports, each comprising:

a first end movably coupled to the central portion of the rail; and

a second end, the pair of supports being movable relative to the rail between a folded configuration in which the pair of supports are parallel to the rail and an unfolded configuration in which the pair of supports are perpendicular to the rail and cooperatively define a channel sized to receive a frame member;

a fastener configured to attach to the second end of each of the pair of supports to secure the pair of supports in the deployed configuration; and

a pair of truss arms, each comprising:

a first end movably coupled to the respective second ends of the pair of supports; and

a second end movably coupled to the respective first and second ends of the rail.

17. The PV module mounting bracket assembly of claim 16, wherein the pair of truss arms are configured to move relative to the rail and the pair of supports between a folded configuration in which the pair of truss arms are parallel to the rail and the pair of supports and an unfolded configuration in which the pair of truss arms extend perpendicularly relative to the rail.

18. The PV module mounting bracket assembly of claim 16, wherein the second end of each of the pair of truss arms is configured to slide off the central portion of the rail when the pair of truss arms are moved toward the collapsed configuration.

19. The PV module mounting bracket assembly of claim 18, further comprising a fastener assembly coupled to the second end of a first truss arm of the pair of truss arms, wherein the fastener assembly is configured to selectively secure the second end of the first truss arm in a position on a track defined in the first end of the track.

20. The PV module mounting bracket assembly according to claim 19, wherein the fastener assembly includes:

a pair of washers disposed on opposite sides of the rail, at least a first washer of the pair of washers having a pair of first and second lugs extending therefrom, the pair of first and second lugs configured to be received in corresponding slots defined in the rail; and

a fastener coupling the pair of washers to one another, the fastener of the fastener assembly configured to adjust a distance between the pair of washers.

1. Field of the invention

The present invention generally relates to mounting brackets. More particularly, the present invention relates to mounting brackets for coupling solar modules to a frame.

2. Background of the related art

A solar mounting system is provided to support and couple one or more arrays of photovoltaic ("PV") modules to a frame, such as, for example, a plurality of parallel-oriented rotatable torque tubes. The solar energy mounting system is designed to maintain the PV module in a fixed position relative to the torque tube while the torque tube rotates during solar tracking.

Solar energy installation systems can add significant cost to solar power generation systems for at least two reasons. First, the components themselves are expensive to manufacture, transport, and install. Second, they are expensive to install and operate because they require time and skilled operators to perform quality control measures in the field. Therefore, there is a need for PV mounting systems that are easier and cheaper to package, transport, and install.

Background

Disclosure of Invention

In one aspect of the invention, a solar module mounting bracket assembly is provided. The solar module mounting bracket assembly includes: a rail configured to support a solar module thereon; and a pair of supports each having a first end movably coupled to the rail. The support is movable relative to the rail between a folded configuration and an unfolded configuration. In the deployed configuration, the supports cooperatively define a channel sized for receiving a frame member.

In aspects, the support may be parallel to the rail in the folded configuration and perpendicular to the rail in the unfolded configuration.

In aspects, the solar module mounting bracket assembly can be substantially linear in shape when the support is in the folded configuration. In a further aspect, the solar module mounting bracket assembly may be substantially triangular in shape when the support is in the deployed configuration.

In various aspects, the solar module mounting bracket assembly can further include a fastener configured to attach to the second end of each of the supports to secure the supports in the deployed configuration.

In various aspects, the solar module mounting bracket assembly can further include a pair of truss arms. Each of the truss arms may include a first end movably coupled to the respective second ends of the pair of supports, and a second end slidably coupled to the respective first and second ends of the rails.

In various aspects, the truss arm can be configured to move between a collapsed configuration and an expanded configuration relative to the rail and the support. In the folded configuration, the truss arm may be parallel to the rail and the pair of supports, and in the unfolded configuration, the truss arm may extend perpendicularly relative to the rail.

In aspects, the second end of each of the truss arms can be configured to slide off a central portion of the rail when the pair of truss arms move to the collapsed configuration.

In aspects, the second end of each of the truss arms is movable along the rails from an inward position to an outward position. In the inward position, the truss arms may assume the deployed configuration, and in the outward position, the truss arms may assume the collapsed configuration.

In various aspects, each of the first and second ends of the rail can define a track through which the respective second end of the truss arm slides.

In various aspects, the solar module mounting bracket assembly can further include a fastener assembly coupled to the second end of a first one of the truss arms. The fastener assembly may be configured to selectively secure the second end of the first truss arm in position on the track of the rail.

In various aspects, the fastener assembly can include a pair of washers disposed on opposite sides of the rail, and a fastener coupling the pair of washers to one another. The fastener may be configured to adjust a distance between the washers. At least one of the washers has a pair of first and second lugs extending therefrom. The first and second lugs may be configured to be received in corresponding slots defined in the rail.

In various aspects, the first washer can further include a third lug extending therefrom. The third lug may be disposed in the track of the rail to guide the fastener assembly through the track.

In various aspects, the solar module mounting bracket assembly can further include a protrusion that protrudes downwardly relative to a bottom side of the rail. The protrusion may extend into the channel defined by the support when the support is in the deployed configuration.

In various aspects, each of the supports can have a concave inner surface such that the channel cooperatively defined by the first and second supports has a circular shape.

In various aspects, the solar module mounting bracket assembly can further include a plurality of coupling devices disposed on an upper side of the rail. The coupling device can be configured to secure a solar module to the rail.

In a further aspect of the invention, a PV module mounting bracket assembly is provided that includes a rail, a pair of supports, a fastener, and a pair of truss arms. The rail is configured to support a PV module thereon and has a first end, a central portion, and a second end. Each of the supports includes a first end movably coupled to the central portion of the rail, and a second end. The support is movable relative to the rail between a folded configuration and an unfolded configuration. In the folded configuration, the support is parallel to the rail, and in the unfolded configuration, the support is perpendicular to the rail and cooperatively defines a channel sized for receiving a frame member. The fastener is configured to attach to the second end of each of the supports to secure the supports in the deployed configuration. Each of the truss arms includes a first end coupled to the respective second ends of the pair of supports, and a second end slidably coupled to the respective first and second ends of the rail.

Further details, advantages and aspects of exemplary embodiments of the invention are described in more detail below with reference to the drawings.

As used herein, the terms parallel and perpendicular are understood to include substantially parallel and substantially perpendicular relative configurations up to about + or-30 degrees from truly parallel and truly perpendicular.

Drawings

Embodiments of the invention are described herein with reference to the accompanying drawings, in which:

FIG. 1 is a top view of a solar power system according to an exemplary embodiment of the present invention;

FIG. 2A is a perspective view, partially broken away, of an exemplary embodiment of a solar module mounting bracket assembly of the solar power generation system of FIG. 1;

FIG. 2B is a top perspective view of an alternative embodiment of a coupling device for coupling a solar module to a rail;

FIG. 2C is a bottom perspective view of the coupling device of FIG. 2B;

FIG. 3 is an enlarged side view of the mounting bracket assembly of FIG. 2A shown in a deployed or in-use configuration;

FIG. 4 is an enlarged side view of the mounting bracket assembly of FIG. 2A shown in a folded or shipping configuration;

FIG. 5 is a side view, partially separated, of the mounting bracket assembly of FIG. 2A shown in a deployed configuration;

FIG. 5A is a top perspective view of an alternative embodiment of a coupling nut illustrated in an attached state and a detached state;

FIG. 6 is a side view of the mounting bracket assembly of FIG. 2A shown in a folded configuration;

FIG. 7A is an enlarged view of the detail area designated "7A" in FIG. 5, illustrating the fastener assembly disposed in an inward position relative to the rails of the mounting bracket assembly;

FIG. 7B is a cross section of the fastener assembly coupled to the rail of the mounting bracket assembly taken along line "7B" in FIG. 7A;

FIG. 8A is an enlarged view of the detail area designated "8A" in FIG. 6, illustrating the fastener assembly disposed in an outward position relative to the rails of the mounting bracket assembly;

FIG. 8B is a cross section of the fastener assembly coupled to the rail of the mounting bracket assembly taken along line "8B" in FIG. 8A;

FIG. 9A is a top perspective view of the mounting bracket assembly shown in a folded configuration and supported on the torque tube of the solar power generation system of FIG. 1;

FIG. 9B is a top perspective view of the mounting bracket assembly shown in a deployed configuration and supported on the torque tube of the solar power generation system of FIG. 1;

FIG. 9C is an enlarged side view of the mounting bracket assembly shown secured to the torque tube;

FIG. 9D is a bottom perspective view of a mounting bracket assembly attached to the underside of an alternative embodiment of a solar module having a wire management clip;

FIG. 9E is a top perspective view of the solar module of FIG. 9D shown in phantom, revealing a wire management clip; and

FIG. 10 is a side cross-sectional view of an alternative embodiment of a rail of the mounting bracket assembly.

Detailed Description

Embodiments of the presently disclosed solar module mounting bracket assembly and method of mounting the same are described in detail with reference to the drawings, wherein like reference numerals designate identical or corresponding elements in each of the several views. As described herein, the term "solar module" refers to any suitable solar panel or array of solar panels that converts energy from the sun into usable energy.

According to various example embodiments of the invention, the invention relates to a mounting bracket assembly for coupling one or more solar modules (e.g., PV modules) to a frame. The mounting bracket assembly has a rail for attaching one or more PV modules thereto, and a pair of supports pivotably coupled to the rail. The support is movable relative to the rail from a folded configuration to an unfolded configuration. The folded configuration reduces the overall footprint of the mounting bracket assembly, thereby reducing packaging and shipping costs. In the deployed configuration, the support grips the frame (e.g., the torque tube) to secure the mounting bracket assembly and then the one or more PV modules to the frame. The mounting bracket assembly may also include a pair of truss arms coupled to respective supports to provide support for the supports. The truss arms are configured to fold with the support. These and further details of the mounting bracket assembly will be described below.

Referring to fig. 1, a solar power generation system 10 is illustrated and generally includes an array of solar modules 12 (e.g., PV modules), a frame (e.g., torque tube 14, for example), and a mounting bracket assembly 100 for coupling the array of PV modules 12 to the torque tube 14. Each of the mounting bracket assemblies 100 may be oriented vertically with respect to the torque tube 14 and extend laterally under each of the PV modules 12. The torque tube 14 may be rotated about an axis to adjust the angular orientation of the PV module 12 relative to the sun.

Although not illustrated, the system 10 may include end-to-end connections, and wherein the torque tubes 14 of each set of end-to-end connections are arranged as more than one torque tube 14 oriented parallel to each other. Each torque tube 14 may have an array of PV modules 12 attached thereto via a plurality of mounting bracket assemblies 100. In an embodiment, two mounting bracket assemblies 100 may be used to couple four PV modules 12 to the torque tube 14. It is contemplated that any suitable number of mounting bracket assemblies 100 may be employed to attach any suitable number of PV modules 12 to the torque tube 14.

Referring to fig. 2A-9C, an exemplary mounting bracket assembly 100 is illustrated and generally includes an elongated rail 102, a pair of first and second supports 104, 106 movably coupled to the rail 102, and a pair of first and second truss arms 108, 110 for supporting the first and second supports 104, 106 relative to the rail 102. The rail 102 has a generally rectangular shape and a U-shaped cross-sectional configuration. The rail 102 includes an upper wall 112 and a pair of lateral side walls 114, 116 extending vertically downward from the upper wall 112, thus forming a U-shaped channel 118 in the underside of the rail 102. The rail 102 has opposite first and second ends 102a, 102b and defines a longitudinal axis "X" therebetween. It is contemplated that the rail 102 may be any suitable shape, such as square, circular, or the like.

With particular reference to fig. 2A, the rail 102 has a plurality of coupling devices 120 disposed on the upper wall 112 of the rail 102. The coupling devices 120 are spaced apart from each other along the longitudinal axis "X" of the rail 102. Each of the coupling devices 120 includes a support member 122 fixed to the upper wall 112 of the rail 102 and a clip 124 detachably coupled to the support member 122. Support member 122 may be fabricated from a relatively flexible material (e.g., an elastomer, for example) to provide a relatively tough (deforming) surface upon which PV module 12 will sit. The support member 122 defines an opening 126 therethrough, the opening 126 sized to receive a shroud 128. The shroud 128 extends upwardly from and is secured to the upper wall 112 of the rail 102. The clip 124 of the coupling device 120 includes a plate member 130 and a fastener 132 (e.g., a screw) extending downward from the plate member 130. The fastener 132 of the clip 124 is configured to couple with the shroud 128 (e.g., via a threaded engagement or a friction fit engagement).

Fig. 2B depicts a further aspect of the invention relating to the coupling device 120. Specifically, this aspect employs a pad 125, the pad 125 supporting the support member 122 and being received on the shroud 128 to attach the pad 125 to the rail 102. In an embodiment, the pad 125 may have a plurality of lugs 127, the plurality of lugs 127 configured to clamp the pad 125 to the upper wall 112 of the rail 102. It is contemplated that the pad 125 may have any suitable fastening mechanism for attachment to the rail 102, such as, for example, an adhesive. The pad 125 allows the width of the rail 102 to be reduced while providing sufficient support surface for the solar module 12. The pad 125 may be formed of a metal plate and placed under the support member 122. The increased width of the pads 125 compared to the width of the rail 102 allows the rail 102 to provide increased support for the module 12 while limiting the size of the rail 102 and thus reducing weight and potential cost. Fig. 2C depicts a bottom perspective view of the coupling device 120 attached to the rail 102, and showing the pad 125 and the support member 122 extending over the edge of the rail 102.

During assembly, with both longitudinal sides of a pair of adjacent PV modules 12 (fig. 1) positioned on support members 122 of coupling device 120, fasteners 132 of clips 124 are positioned through openings 126 of support members 122 and are threadably coupled to threaded inner surfaces of shrouds 128. In an embodiment, the fastener 132 of the clip 124 may be fastened to the shroud 128 via a friction fit engagement. Plate member 130 of clip 124 approaches (e.g., via rotation of fastener 132) toward support member 122 until PV module 12 is captured between plate member 130 of clip 124 and support member 122.

It is contemplated that the rail 102 may also have a coupling device in the form of a flexible, hook-shaped member 134 disposed on the opposing first and second ends 102a, 102b of the rail 102. Hook members 134 are configured to snap over the ends of PV module 12 to resist movement of PV module 12 along longitudinal axis "X" of rail 102.

The first end 102A of the rail 102 defines a first pair of linear rails 136 in the opposing lateral sidewalls 114, 116 of the rail 102 (only the rails 136 in the first sidewall 114 are illustrated in fig. 2A). Similarly, the second end 102b of the rail 102 defines a second pair of linear rails 138 in the opposing lateral sidewalls 114, 116 of the rail 102 (only the rails 138 in the first sidewall 114 are illustrated in fig. 2A). In embodiments, the rails 136, 138 may be curved or take any other suitable shape. As will be described in further detail below, the first pair of rails 136 allows slidable coupling of the first truss arm 108 to the rail 102, and the second pair of rails 138 allows slidable coupling of the second truss arm 110 to the rail 102.

As best shown in fig. 3 and 4, the rail 102 has a central portion 102c disposed between the first and second ends 102a, 102b of the rail 102. The central portion 102c of the rail 102 may have an insert 140 disposed within the channel 118 of the rail 102 and between the pair of supports 104, 106. The insert 140 has a concave inner surface 142 and a protrusion 144 extending downwardly from the inner surface 142 thereof. The protrusions 144 may have a circular configuration (e.g., dome-shaped) and be made of a pliable material (e.g., an elastomer, for example). In some embodiments, the protrusion 144 may be fabricated from any suitable material (e.g., metal, for example). The protrusions 144 are configured to enhance frictional engagement between the mount bracket assembly 100 and the torque tube (fig. 1) when the torque tube 100 is captured between the pair of supports 104, 106, as will be described.

Referring to fig. 2A-6, each of the first and second supports 104, 106 has a first end 104a, 106a and a second end 104b, 106 b. The first end 104a, 106a of each of the supports 104, 106 is coupled to the central portion 102c of the rail via a fastener (such as, for example, a nut and bolt assembly). The first ends 104a, 106a of the supports 104, 106 are pivotable relative to the rail 102 between a use or deployed configuration (as shown in fig. 3) and a transport or collapsed configuration (as shown in fig. 4). In the deployed configuration, the supports 104, 106 are disposed in a perpendicular relationship to the longitudinal axis "X" of the rail 102. In the folded configuration, the supports 104, 106 are coaxial with the longitudinal axis "X" of the rail 102, whereby the mounting bracket assembly 100 has a substantially reduced overall profile.

The supports 104, 106 may each have a concave inner surface 146, 148, respectively. When the supports 104, 106 are in the deployed configuration, the concave inner surfaces 146 of the supports 104, 106 and the concave inner surface 142 of the insert 140 cooperatively define a circular channel 150, the circular channel 150 sized for receiving the torque tube 14 (fig. 1). The supports 104, 106 each have a generally U-shaped cross-sectional configuration and define longitudinally extending U-shaped channels 152, 154, respectively. The U-shaped channels 152, 154 of each of the supports 104, 106 are configured to receive the lateral side walls 114, 116 of the rail 102 when the supports 104, 106 are moved toward the folded configuration.

The mounting bracket assembly 100 further includes primary fasteners 156, such as, for example, nuts 156a and bolts 156b, the primary fasteners 156 interconnecting the second portions 104b, 106b of the first and second supports 104, 106. The primary fasteners 156 are configured to extend through openings 158, 160 (fig. 4) defined in the respective second ends 104b, 106b of the supports 104, 106. The primary fasteners 156 are configured to selectively lock the supports 104, 106 and close the circular channel 150 in the deployed configuration. The second ends 104b, 106b of the nut 156a and bolt 156b proximate the drive supports 104, 106 are brought closer to each other to constrict the circular channel 150 around the torque tube 14.

A nut 157 that may be used with the present invention is depicted in fig. 5A. Specifically, the nut 157 is a split shear nut and may be used in place of the nut 156 a. The split shear nuts 157 may be pre-installed on the bolts 156 b. To install to the proper torque setting, all the installer must do is apply torque to the nut 157 until the hex head 157a disengages from the body 157 b. The stress concentration to separate the shear nuts 157 may be sized such that separation of the hex head 157a occurs upon application of a predetermined pressure to the bolts 156a that will hold the spider assembly 100 on the torque tube 14. The hex head 157a may then be discarded, but importantly, for field installation, proper torque application may be ensured without the need for any special tools or concern for excessive torque of the nut 157a which may cause damage to the torque tube 14 or other components.

With continued reference to fig. 2A-6, as briefly mentioned above, the mounting bracket assembly 100 further includes a pair of first and second truss arms 108, 110, the pair of first and second truss arms 108, 110 providing support for the supports 104, 106 when in the deployed configuration. Each of the truss arms 108, 110 has a first end 108a, 110a and a second end 108b, 110 b. The first end 108a, 110a of each of the truss arms 108, 110 is coupled to the respective second end 104b, 106b of the supports 104, 106 via fasteners (e.g., nut and bolt assemblies, for example). The first end 108a, 110a of each of the truss arms 108, 110 may be disposed within the U-shaped channels 152, 154 of the respective supports 104, 106.

The first end 108a, 110a of each of the truss arms 108, 110 is pivotable relative to the respective support 104, 106 between an in-use or deployed configuration (as shown in fig. 3) and a transport or collapsed configuration (as shown in fig. 4). In the deployed configuration, the truss arms 108, 110 are disposed in an oblique or transverse relationship to the longitudinal axis "X" of the rail 102 and supports 104, 106, thus imparting a generally triangular shape or a-shape to the mounting bracket assembly 100. In the collapsed configuration, truss arms 108, 110 are disposed in parallel relationship with rail 102 and supports 104, 106, thereby imparting a substantially linear configuration to mounting bracket assembly 100.

Referring to fig. 2A, 5 and 6, the second end 108b, 110b of each of the truss arms 108, 110 is slidably coupled to the respective first and second ends 102A, 102b of the rail 102. In particular, the second end 108b, 110b of each of the truss arms 108, 110 is configured to slide along the respective rails 136, 138 of the rail 102 between an inward position (fig. 5) and an outward position (fig. 6). When the second end 108b, 110b of each of the truss arms 108, 110 is in the inward position, the truss arms 108, 110 and the supports 104, 106 are in their respective deployed configurations, and when the second end 108b, 110b of each of the truss arms 108, 110 is in the outward position, the truss arms 108, 110 and the supports 104, 106 are in their respective collapsed configurations.

Referring to fig. 5-8B, the mounting bracket assembly 100 further includes a pair of first and second fastener assemblies 170, 172. A first fastener assembly 170 slidably couples the second end 108b of the first truss arm 108 to the track 136 of the first end 102a of the rail 100, and a second fastener assembly 172 slidably couples the second end 110b of the second truss arm 110 to the track 138 of the second end 102b of the rail 100. The fastener assemblies 170, 172 are configured to selectively lock the second end 108b, 110b of each of the respective truss arms 108, 110 in the inward position. Since the first and second fastener assemblies 170, 172 are the same or substantially similar, only the first fastener assembly 170 will be described in detail herein.

With particular reference to fig. 7A-8B, the first fastener assembly 170 includes a pair of washers 174, 176 and a fastener 178, such as, for example, a nut and bolt that couple the pair of washers 174, 176 to one another. Washers 174, 176 are disposed on respective first and second lateral sidewalls 114, 116 of rail 102, and a fastener 178 extends laterally through a pair of rails 136 in first and second lateral sidewalls 114, 116 of first end 102a of rail 102. The fastener 178 also extends through the second end 108b of the first truss arm 108, thereby slidably coupling the second end 108b of the truss arm 108 to the first end 102a of the rail 102.

The washers 174, 176 of the fastener assembly 170 each include a pair of first and second flanges or lugs 174a, 174b and 176a, 176b extending perpendicularly from their peripheries. The first and second lugs 174a, 174b and 176a, 176b of each of the washers 174, 176 are disposed on opposite sides of the respective washer 174, 176. The lugs 174a, 174b and 176a, 176b of the washers 174, 176 may have a square configuration and be sized to be received in a pair of corresponding slots 180, 180b defined in the first end 102a of the rail 102 (fig. 8A). The slots 180a, 180b are disposed on opposite longitudinal sides of the rail 136 and at inward ends of the rail 136.

As shown in fig. 7A, when the fastener assembly 170 is moved toward the inward position, the lugs 174a, 174b and 176a, 176b of the washers 174, 176 are aligned with the corresponding slots 180a, 180b in the first end 102a of the rail 102. Actuation of the fastener 178 drives the proximity of the washers 174, 176, whereby the lugs 174a, 174b of the washers 174, 176 are received in the corresponding slots 180a, 180b in the rail 102 to secure or lock the fastener assembly 170 to the rail 102, and then lock the second end 108b of the first truss arm 108 in the inward position.

The washers 174, 176 may further include a third flange or lug 174c extending perpendicularly from the outer periphery thereof. Third lug 174c is received in track 136 of first end 102a of rail 102 to guide fastener assembly 170 along track 136. A compression tube 179 (fig. 7B) may be provided, the compression tube 179 extending between the walls 114, 116 of the rail 102 and having a fastener 178 extending therethrough. The compression tube 179 prevents the walls 114, 116 of the rail 102 from folding during tightening of the fastener 178.

With respect to the compression tube 179 depicted in fig. 7B and 8B, aspects of the invention are shown with respect to capturing the compression tube 179 in the truss arm 108. Specifically, after forming the holes in the truss arms 108 for receiving the fasteners 178, the compression tube 179 can be placed opposite the holes, and the edges of the holes can be flared into the compression tube 179 using a hydraulic press, pressing the edges defining the holes around and on the inner periphery of the compression tube 179. The result is twofold. First, the flared holes are larger than the holes originally drilled in truss arms 108, thereby allowing fasteners 178 of a larger diameter than the holes originally formed to pass through. The second result is that the compression tube 179 is permanently captured in the truss arm 108, facilitating field installation, as the installer no longer needs to align the bore of the compression tube 179 with the hole in the truss arm 108.

During assembly, referring to fig. 9A, when in the folded or transport configuration, the mounting bracket assembly 100 is positioned over the torque tube 14 of the solar power generation system 1 (fig. 1) with the central portion 102c of the rail 102 overlapping the torque tube 14. In this position, the protrusions 144 (fig. 3) of the insert 140 abut the outer surface of the torque tube 14, and the supports 104, 106 are disposed on opposite sides of the torque tube 14. As shown in fig. 9B, the supports 104, 106 of the mounting bracket assembly 100 are rotated in the direction indicated by arrow "a" in fig. 9B outwardly from the rail 102 toward the deployed configuration. Rotation of the supports 104, 106 rotates the first end 108a, 110a of each of the truss arms 108, 110 relative to the respective second end 104b, 106b of the supports 104, 106. Rotation of the supports 104, 106 continues until the inner surfaces 146, 148 of the supports 104, 106 capture the torque tube 14 therebetween, as shown in figure 9C.

As the torque tube 14 is captured within the channel 150 defined by the insert 140 and the supports 104, 106, the primary fasteners 156 are actuated to approach the second ends 104b, 106b of the supports 104, 106, whereby the supports 104, 106 apply an upwardly directed force to the torque tube 14 to drive the torque tube 14 into engagement with the protrusions 144 of the insert 140. In an embodiment, the concave inner surfaces 146, 148 of the supports 104, 106 may be coated or lined with a material similar to the protrusion 144 to enhance frictional engagement with the torque tube 14.

As described above, when the supports 104, 106 are brought into the deployed configuration, the second ends 108b, 110b of each of the truss arms 108, 110 are simultaneously moved to an inward position on the respective rails 136, 138 of the rail 102. With the second ends 108b, 110b of the truss arms 108, 110 in the inward position, the first and second lugs 174a, 174b and 176a, 176b of the washers 174, 176 of the fastener assembly 170 are disposed adjacent the slots 180a, 180b defined in the rail 102. To secure the second ends 108b, 110b of the truss arms 108, 110 in the inward position along the respective rails 136, 138, the fasteners 178 of the fastener assembly 170 are actuated to drive the proximity of the washers 174, 176, whereby the lugs 174a, 174b and 176a, 176b of the washers 174, 176 are received in the corresponding slots 180a, 180b in the rail 102 to secure or lock the fastener assembly 170 to the rail 102, and then to lock the second end 108b of the first truss arm 108 in the inward position.

At this stage, the remaining fasteners of the mounting bracket assembly 100 may be tightened to ensure that the mounting bracket assembly 100 remains stationary in the deployed or in-use configuration. PV module 12 is then secured to rail 102 of mounting bracket assembly 100 via coupling devices 120, 134 in the manner described above.

Yet further aspects of the present invention can be seen in fig. 9D and 9E. Specifically, the rail 102 may have pre-installed wire management clips 162 attached to the lateral sides of the rail 102. The wire management clips 162 may be axially aligned with each other and spaced along the rail 102. In other embodiments, the clip 162 may be positioned at any suitable location on the rail 102 or other component of the mounting bracket assembly 100. By pre-installing the wire management clip 162, the installation of the solar modules 12 and their electrical connections is facilitated, and by making the pre-installed wire management clip 162 available to the installer both are made more efficient and the quality of those electrical connections is ensured.

Finally, although generally described in connection with a rail 102 having a generally C-shaped cross-section, the invention is not so limited. Rather, various cross-sectional shapes may be employed without departing from the scope of the present invention. For example, a top hat configuration as depicted in FIG. 10 may be employed. The top hat rail 102 is similar to a C-shaped rail, but includes two flanges 107a, 107b extending perpendicularly from the channel, which provides further stability to the rail 102. In various aspects, the flanges 107a, 107b can extend at any suitable angle relative to the body of the rail.

In embodiments, the fasteners described herein may be any suitable fastening mechanism, including but not limited to adhesives, hinges, clips, tethers, straps, belts, tapes, and/or fabric hook and loop fasteners.

It should be understood that various modifications may be made to the embodiments disclosed herein. Accordingly, the foregoing description should not be construed as limiting, but merely as exemplifications of the various embodiments. Those skilled in the art will envision other modifications within the scope and spirit of the claims appended hereto.