A conversion apparatus is provided herein. The conversion apparatus includes a cutting member having an edge configured for cutting the dunnage material. The conversion apparatus also includes a biasing member that is located adjacent to the cutting member such that the dunnage material passes between the biasing member and the cutting member. The biasing member operably contacts the dunnage material thereby biasing the dunnage material against the cutting member. The position of the biasing member relative to the cutting member is such that in response to the dunnage material being retracted back into the conversion apparatus the cutting member begins to sever the dunnage material, but in response to the dunnage material traveling in the dispensing direction the cutting member does not begin to sever the dunnage material due to the relative position.

A machine for production of a packing product, and a method of manufacture, creates a double curl, spiral, twist, or coil in the shape of a B having elastic, cushioning, form-fitting, and coherent packing properties. The B is created from a dimension-controlled strip of preferably, but not necessarily, cohesive paper having a cohesive side and a non-cohesive side, a leading end, and a trailing end. The leading edge is wound into a spiral in a first direction with the cohesive side of the dimension-controlled cohesive paper facing outward. The trailing edge is wound into a spiral in a second direction that is opposite the first direction, with the cohesive side of the cohesive paper also facing outward. The machine and method can produce Bs of various sizes and number of windings per curl to accommodate various sized items and/or packaging.

A splicing unit is included with a dunnage conversion machine that converts a supply of stock material into a dunnage product, where the splicing unit includes: a support surface configured to provide backing for a first strip of stock material, and a sensor operatively connected to the dunnage conversion machine, the sensor being associated with the support surface for detecting a presence of the first strip of sheet material and upon determining that the first strip of stock material has passed the sensor, stopping operation of the dunnage conversion machine. A brake may be arranged adjacent to the support surface in order to contact the first strip of stock material arranged on the support surface upon stopping operation of the dunnage conversion machine.

The present invention provides void fill dispenser systems and methods that highly effectively enable the easy and usable creation of void fill with expanded slit sheet paper in a manner unattainable in the existing art. According to some illustrative embodiments, a void fill dispenser is provided that advantageously dispenses unique void fill in a manner not previously possible. In some embodiments, the void fill dispenser is made with a recyclable material, such as, e.g., a corrugated box made from paper. In some embodiments, the void fill dispenser is made with metal and/or other rigid and/or non-recyclable materials. In some embodiments, the void fill dispenser can comprise an automated metal dispensing system that dispenses expanded slit sheet paper particularly for void fill in an automated manner.

A dunnage conversion machine includes a drive mechanism configured to deform a stock material into a continuous length of dunnage. The machine also includes a cutting device configured to sever a piece of the dunnage from the continuous length of dunnage. The cutting device includes a grip configured to move to a closed position at which the grip exerts a force on the piece of dunnage to retain the piece on the machine until the piece is pulled away from the machine, at which point the grip moves to an open position and the machine advances the continuous length of dunnage to commence another cutting cycle.

A dunnage conversion machine includes a drive mechanism configured to deform a stock material into a continuous length of dunnage. The machine also includes a cutting device configured to sever a piece of the dunnage from the continuous length of dunnage. The cutting device includes a grip configured to move to a closed position at which the grip exerts a force on the piece of dunnage to retain the piece on the machine until the piece is pulled away from the machine, at which point the grip moves to an open position and the machine advances the continuous length of dunnage to commence another cutting cycle.

A dunnage conversion machine includes a drive mechanism configured to deform a stock material into dunnage. The drive mechanism may include a roller with an outer surface having a first shape, and another roller having an outer surface with a second shape different than the first shape. The dunnage conversion machine also may include a cutting mechanism that includes an anvil having a curvilinear surface, and a cutting portion, with the anvil and the cutting portion being configured to cut the dunnage. The dunnage conversion machine also may include an inlet chute configured to feed the stock material to the dunnage conversion machine. The inlet chute may include a protrusion located within an interior channel of the inlet chute and configured to restrict larger objects, such as the fingers and hands of an operator, from moving down the interior channel.

Palletized units of fan-folded stock material include a pallet having a deck configured to support the fan-folded stock material, and a stack of the stock material supportively positioned on the deck. The stock material includes an elongated web of sheet material configuration defined by folds in the web about fold lines that extend in a transverse direction of the web that segment the web into a plurality of sheet sections, with adjacent sheet sections folded onto one another.

A device for producing dunnage includes a jam detector located downstream of a crumpler and upstream of an outlet chute of the device and configured to detect a jam of the dunnage between the crumpler and the outlet chute.

A dunnage conversion machine includes a drive mechanism configured to deform a stock material into dunnage. The drive mechanism may include a roller with an outer surface having a first shape, and another roller having an outer surface with a second shape different than the first shape. The dunnage conversion machine also may include a cutting mechanism that includes an anvil having a curvilinear surface, and a cutting portion, with the anvil and the cutting portion being configured to cut the dunnage. The dunnage conversion machine also may include an inlet chute configured to feed the stock material to the dunnage conversion machine. The inlet chute may include a protrusion located within an interior channel of the inlet chute and configured to restrict larger objects, such as the fingers and hands of an operator, from moving down the interior channel.