A sacrificial polymer pole guide cover for the use of covering one or more pole guide tongs in a pole guide. The pole guide cover has a generally arcuate body presenting a length and that is curved along the length. The pole guide cover further presents a concave interior surface along the length and a convex exterior surface along the length. A channel is formed in at least a portion of the length of the convex exterior surface. The channel is shaped to complementally receive at least a portion of a pole guide tong. The pole guide cover also has a mounting assembly for removably mounting the pole guide cover to the pole guide tong.

A sacrificial polymer pole guide cover for the use of covering one or more pole guide tongs in a pole guide. The pole guide cover has a generally arcuate body presenting a length and that is curved along the length. The pole guide cover further presents a concave interior surface along the length and a convex exterior surface along the length. A channel is formed in at least a portion of the length of the convex exterior surface. The channel is shaped to complementally receive at least a portion of a pole guide tong. The pole guide cover also has a mounting assembly for removably mounting the pole guide cover to the pole guide tong.

It is intended to easily perform a work concerning lifting of the crawler. A crawler frame has a crawler frame outer surface that is opposite to a surface via which the crawler frame is attached to a traveling body main part in the left-right direction. A bracket includes an attaching part, a circuitous part, and a crawler lifting section. The attaching part is attached to the crawler frame outer surface. The circuitous part is partially arranged below and above a crawler belt on an outer side thereof in the left-right direction, and extends around the crawler belt. The crawler lifting section is connected to the circuitous part and arranged above the crawler belt for receiving the crawler lifting tool.

A bollard setting and installation system for efficiently installing a bollard wall without any restrictions relating to proximity to water or flood plains. The bollard setting and installation system generally includes a setting frame which is positioned on a ground surface. A plurality of bollards is positioned on the setting frame in a desired spacing and orientation to form a bollard wall. A vehicle having a vehicle arm connected to a lifting frame is positioned such that the bollards are secured to the lifting frame by clamps in the desired spacing and orientation. The vehicle may then move the lifting frame to position the lower ends of the bollards in an opening in the ground surface. Concrete may be poured to encapsulate the lower ends of the bollards. The lifting frame may then be removed, with the bollard wall being free-standing in the ground surface.

Presented are corner attachment assemblies for cargo suspension systems, methods for making/using such assemblies, and aircraft equipped with underbody suspension systems using corner attachment assemblies for securing payload containers. Mounting assemblies are presented for securing objects to tether cables of suspension systems. A representative cargo mounting assembly includes a pair of shoulder clamps, each of which includes a flap that projects from a cup. Each shoulder clamp flap mechanically attaches, e.g., via a flap through-hole with a structurally reinforcing grommet, to a respective segment of a tether cable of a cargo suspension system. In addition, each shoulder clamp cup includes multiple noncoplanar, mutually adjoining contact surfaces. For instance, the cup may have a tetrahedral geometry with three mutually orthogonal, triangular-shaped contact surfaces. Each contact surface attaches, e.g., via a high-strength adhesive, to a respective surface of a corner of a cargo container.

Presented are corner attachment assemblies for cargo suspension systems, methods for making/using such assemblies, and aircraft equipped with underbody suspension systems using corner attachment assemblies for securing payload containers. Mounting assemblies are presented for securing objects to tether cables of suspension systems. A representative cargo mounting assembly includes a pair of shoulder clamps, each of which includes a flap that projects from a cup. Each shoulder clamp flap mechanically attaches, e.g., via a flap through-hole with a structurally reinforcing grommet, to a respective segment of a tether cable of a cargo suspension system. In addition, each shoulder clamp cup includes multiple noncoplanar, mutually adjoining contact surfaces. For instance, the cup may have a tetrahedral geometry with three mutually orthogonal, triangular-shaped contact surfaces. Each contact surface attaches, e.g., via a high-strength adhesive, to a respective surface of a corner of a cargo container.

A pump mounting frame comprising a latching device for releasably mounting a pump apparatus. The latching device has a body portion having a latch aperture for receiving a latch pin; and a latching member for releasably retaining the latch pin in the latch aperture. The latching member is movable between a closed position and an open position. The latching member has a first arm for retaining the latch pin in the latch aperture when the latching member is in the closed position. The latching member has a second arm for biasing the latch pin out of the latch aperture when the latching member is displaced from the closed position to the open position. The present disclosure also relates to a method of moving one or more pumps using the pump mounting frame.

A pump mounting frame comprising a latching device for releasably mounting a pump apparatus. The latching device has a body portion having a latch aperture for receiving a latch pin; and a latching member for releasably retaining the latch pin in the latch aperture. The latching member is movable between a closed position and an open position. The latching member has a first arm for retaining the latch pin in the latch aperture when the latching member is in the closed position. The latching member has a second arm for biasing the latch pin out of the latch aperture when the latching member is displaced from the closed position to the open position. The present disclosure also relates to a method of moving one or more pumps using the pump mounting frame.

A carrying means (1) for transporting objects, having a carrying limb (2) and a load handling limb (3), wherein at least one rotatably mounted load support is arranged in the region of a free end (7) of the load handling limb (3), wherein the load support is a radial segment (4) which lies on the free end (7) of the load handling limb (3) and, together therewith, forms a load-carrying bearing and at least one inner surface of the load handling limb (3) forms a bearing shell (5) on the free end (7) and corresponds to the radial segment (4).

A tank cover lifting tool is configured to remove or attach tank covers. The tank cover lifting tool includes a handle center support, a first handle connected to one end of the handle center support, and a second handle connected to another end of the handle center support. In addition, the tank cover lifting tool includes a first lifting block that is locked on the handle center support and that is configured to engage a first tank cover handle of a tank cover. Further, the tank cover lifting tool includes a second lifting block that is locked on the handle center support and that is configured to engage a second tank cover handle of the tank cover.