A fusion welding device, comprising a fusion welding work motor, a fusion welding work moving assembly, and a fusion welding work fixed assembly, the fusion welding work motor being connected to the fusion welding work moving assembly by means of a transmission mechanism. The fusion welding device is provided with a central connection component that is able to rotate, and the central connection component is provided with a first input position, a second input position, and a locking structure connection position. The present fusion welding device is able to implement automatic band pressing and fusion welding work by means of relatively simple structural cooperation, and by means of differently transmitted front and back connections and changes in engagement, and is able to automatically lift the fusion welding work moving assembly without requiring a handle or related operations.

A fusion welding device, comprising an operating component, a fusion welding work motor, a fusion welding work moving assembly, and a fusion welding work fixed assembly, the fusion welding work motor being connected with the fusion welding work moving assembly by means of a transmission mechanism. The fusion welding device is provided with a central connection component that is able to rotate, and the central connection component is provided with a first input position, a second input position, and a locking structure connection position. The present fusion welding device is able to accomplish automatic band pressing and fusion welding work by means of a relatively simple structure and by means of differently transmitted front and back connections and changes in engagement.

An automated tying tool includes slider, guide rail, first guide claw, second guide claw, frame, tensioning wheel, cutter, stepwise material feeding mechanism, and material pushing rod. First and second guide claws are mounted on frame via rotation of central pin. Cutter and tensioning wheel are mounted in frame. Guide rail is adjacent to frame. Slider engages with guide rail. An automated tying method includes: stepwise material feeding mechanism being loaded with ties, and conveying ties at fixed interval in each binding cycle; slider driving ties to slide from predetermined position to binding position; tie body of ties being curled in guide slots in first and second guide claws; causing tail portion of ties to pass through a hole at head portion of ties; tensioning wheel rotating to tighten ties; and cutter cutting tightened ties. A tying tool may include a material feeding, distributing, and pushing mechanism.

Various embodiments of the present disclosure provide a mobile strapping device for strapping packaged products using a loop of wrapping strap. The strapping device includes a tensioning device for applying tension to the strap and a connecting device for connecting two overlapping portions of the strap. The tensioning device includes a rotatable tensioning wheel and a tensioning plate. The tensioning wheel is supported by a rocker that is pivotable to change a distance separating the tensioning wheel and the tensioning plate. The mobile strapping device includes a motor that is operably connectable to the rocker or the tensioning wheel such that the motor causes pivoting of the rocker or rotation of the tensioning wheel when operating in a first direction of rotation. In various embodiments, gearing, including a plurality of planetary gear sets, is used to operatively connect the motor to the rocker and the tensioning wheel.

A rotary translational strapping apparatus and strapping method thereof are provided including a support frame, a rotary module, and a translational strapping module, the rotary module includes a rotary guide, a rotary frame, and a first driving mechanism, the rotary guide is disposed on top of the support frame, the rotary frame is rotatably disposed on the rotary guide, the first driving mechanism is used for driving the rotary frame to rotate relative to the rotary guide. The translational strapping module includes a sliding mount, a strapping head, a strapping chute, and a second driving mechanism. The sliding mount is slidably disposed on the rotary frame.

A strapping machine of the type that feeds, retracts, tensions and seals strap to itself to form a loop of strap around a load, has a shock absorbing feed wheel assembly. The machine includes a frame, a feed head having a motor, a tension head, a sealing head and a strap chute mounted to the frame. The feed wheel assembly has a friction engaging surface and at least one pocket formed therein. A spring hub is engaged with the feed wheel and has at least one pocket formed therein corresponding to the feed wheel pocket. The spring hub is operably connected to the feed head motor. At least one spring is positioned in the feed wheel pocket and the spring hub pocket and is sandwiched between the feed wheel and the spring hub. The feed wheel is driven by rotation of the spring hub and engagement of the spring with the feed wheel pocket and spring hub pocket. The shock absorbing feed wheel assembly dampens the forces on the feed head motor and drive when the feed wheel comes to an abrupt stop and prevents strap slippage.

A strapping machine and head are provided including a mounting base, a sealing assembly including a cutter for cutting the strapping tape and a sealing element for welding a strapping tape. The sealing assembly, which is slidably disposed on the mounting base, includes a first, second, and third clamping mechanism, for clamping the strapping tape. A belt feeding assembly including a first motor, a driving wheel and a guide block fixedly disposed on the mounting base. The driving wheel is rotatably disposed on the mounting base and an arc-shaped belt feeding channel is formed between the driving wheel and the guide block. The first motor drives the driving wheel to rotate, and a driving assembly drives the sealing assembly close to or away from the driving wheel. A balanced tension is applied to a strapping tape through a strapping machine head to improve the strapping quality of the strapping machine.

Various embodiments of the present disclosure provide a mobile strapping device for strapping packaged products using a loop of wrapping strap. The strapping device includes a tensioning device for applying tension to the strap and a connecting device for connecting two overlapping portions of the strap. The tensioning device includes a rotatable tensioning wheel and a tensioning plate. The tensioning wheel is supported by a rocker that is pivotable to change a distance separating the tensioning wheel and the tensioning plate. The mobile strapping device includes a motor that is operably connectable to the rocker or the tensioning wheel such that the motor causes pivoting of the rocker or rotation of the tensioning wheel when operating in a first direction of rotation. In various embodiments, gearing, including a plurality of planetary gear sets, is used to operatively connect the motor to the rocker and the tensioning wheel.

A strapping device includes a handle, a body, and an actuator. The handle includes an input device and a switch, the input device spaced from the switch by a biasing element that applies a bias force to the input device. The input device moves from a first state spaced from the switch to a second state contacting the switch responsive to receiving a force greater than the bias force. A circuit of the switch is closed responsive to the input device moving from the first state to the second state. The switch outputs an actuation signal responsive to the circuit being closed. The body includes a tensioner and a base including a strap receiver opposite the tensioner. The actuator moves the tensioner from a first tensioner position to a second tensioner position further from the strap receiver based on a movement force greater than the bias force.

The invention relates to a drive unit for a strapping device for strapping an item to be packed with a plastic tape which is laid around it, having a motorized tensioning device and a motorized welding device for the plastic tape, wherein the tensioning and the welding device can be driven by the same electric motor which can be brought alternatively into an operative connection with said devices with freewheels being connected in between. The problem has occurred in drive units of this type that they are relatively complicated to assemble and have problematic operational reliability under certain boundary conditions. In order to bypass said problems, it is proposed to provide the electric motor with at least one shell extension which protrudes beyond it at one axial end, with the result that the drive elements which have up to now been mounted separately in the housing of a strapping device can be supported directly on the electric motor which then acts as a drive unit.