A wearable canopy shade is provided. The wearable canopy shade includes a canopy secured a frame, wherein the frame includes a bulbous first end and a narrower second end. The frame is movable between an open position and a closed position, wherein the open position, the second end is perpendicular to the first end, such that the second end is configured to rest parallel to a back of a user wearing the shade and the first end rests above a head of the user, providing shade to a user positioned thereunder. The shade includes a pair of shoulder straps that can secure the frame to the user. A cord is securable between the first end of the frame and the pair of shoulder straps in order to prevent the rotation of the first end of the frame relative to the second end when the shade is in use.

The present invention relates to a support structure for a rucksack, including a support framework having a first and a second bearing point arranged at a spacing from one another along a first direction, and a first and a second rotation element. The first rotation element is mounted on the support framework at the first bearing point and is rotatable about a first rotation axis and the second rotation element is mounted on the support framework at the second bearing point and is rotatable about a further rotation axis. The first and second rotation elements are constructed for receiving a shoulder belt and hip belt, respectively, in a torsion-resistant manner. The first and the second rotation element are rotationally coupled to one another in a manner reversing the direction of rotation.

The present invention relates to a support structure for a rucksack, including a support framework having a first and a second bearing point arranged at a spacing from one another along a first direction, and a first and a second rotation element. The first rotation element is mounted on the support framework at the first bearing point and is rotatable about a first rotation axis and the second rotation element is mounted on the support framework at the second bearing point and is rotatable about a further rotation axis. The first and second rotation elements are constructed for receiving a shoulder belt and hip belt, respectively, in a torsion-resistant manner. The first and the second rotation element are rotationally coupled to one another in a manner reversing the direction of rotation.

Disclosed is a backpack, shelter, rain poncho/rainfly/pack cover combination. The combination is configured such that the tent is stored in a zippered front pocket of the backpack, a removable hooded rain poncho/rainfly/pack cover is stored in a pocket on the top of the pack, and a telescoping frame sits in an integrated sleeve within the pack, preferably against a foam backpanel. The front of the backpack is configured to form a wall of the tent, when the tent is erected. The telescoping frame typically consists of (i) one horizontal hollow tube arm; (ii) an adjustable hinge connected to each end of the horizontal tube arm, each hinge configured to lock at 90 degrees as well as a wider angle; and (iii) a vertical leg assembly connected to each adjustable hinge, each vertical leg assembly containing two telescoping hollow tubes.

A harness for a back-pack comprises a chest harness (A), a strut mechanism in the form of a flexible spine (B) and a hip belt (C). The flexible spine (B) provides a sprung, damped connection between the chest harness (A) and the hip belt (C), so that the load of the backpack is transferred through the flexible spine (B) to the hip belt (C), while the flexible spine can extend to accommodate movement of the wearer's body. The chest harness (A) comprises straps (12, 15) which are interconnected at the front of the wearer by a buckle (14). Abdominal straps (15) are connected to the buckle (14) by flexible wands (16) which flex under the breathing action of the wearer to retain the load securely against the wearer's back without restricting breathing.

A harness for a back-pack comprises a chest harness (A), a strut mechanism in the form of a flexible spine (B) and a hip belt (C). The flexible spine (B) provides a sprung, damped connection between the chest harness (A) and the hip belt (C), so that the load of the backpack is transferred through the flexible spine (B) to the hip belt (C), while the flexible spine can extend to accommodate movement of the wearer's body. The chest harness (A) comprises straps (12, 15) which are interconnected at the front of the wearer by a buckle (14). Abdominal straps (15) are connected to the buckle (14) by flexible wands (16) which flex under the breathing action of the wearer to retain the load securely against the wearer's back without restricting breathing.

Methods and systems are provided for a backpack system including a frame-less waterproof bag and a backpack frame. In one example, a frame-less waterproof bag may include a frame-cap welded to an outer surface of the frame-less waterproof bag. The frame-cap may be adapted to couple the frame-less waterproof bag with the backpack frame while maintaining a waterproof quality of the frame-less waterproof bag.

Methods and systems are provided for a backpack system including a frame-less waterproof bag and a backpack frame. In one example, a frame-less waterproof bag may include a frame-cap welded to an outer surface of the frame-less waterproof bag. The frame-cap may be adapted to couple the frame-less waterproof bag with the backpack frame while maintaining a waterproof quality of the frame-less waterproof bag.

Implementations described and claimed herein provide systems and methods for load carriage using a load carriage apparatus. In one implementation, a frame top is disposed at a proximal end of a load carriage frame. The frame top includes a proximal bar and a distal bar each extending between a first side bar and a second side bar. A frame base is disposed at a distal end of the load carriage frame, and the frame base includes a rear portion connected to a first side portion and a second side portion. A spine connects a center portion of the proximal bar of the frame top to the rear portion of the frame base. A first tube extends from the first side bar to the frame base relative to the first side portion. A second tube extends from the second side bar to the frame base relative to the second side portion.

Implementations described and claimed herein provide systems and methods for load carriage using a load carriage apparatus. In one implementation, a frame top is disposed at a proximal end of a load carriage frame. The frame top includes a proximal bar and a distal bar each extending between a first side bar and a second side bar. A frame base is disposed at a distal end of the load carriage frame, and the frame base includes a rear portion connected to a first side portion and a second side portion. A spine connects a center portion of the proximal bar of the frame top to the rear portion of the frame base. A first tube extends from the first side bar to the frame base relative to the first side portion. A second tube extends from the second side bar to the frame base relative to the second side portion.