Apparatus and process for handling food packaging

The invention claimed is: 1. An apparatus for separating a cone sleeve ( 4 ) from a nested stack of cone sleeves ( 1 ), the apparatus comprising a chamber ( 2 ) having an upper ( 7 ) and a lower ( 8 ) surface connected by a wall or walls ( 6 ), the upper surface ( 7 ) having an upper circular opening ( 3 ) and the lower surface ( 8 ) having a lower circular opening ( 5 ) characterised in that the upper circular opening ( 3 ) has a circumference from 100 to 135% of a maximum circumference of the cone sleeve ( 4 ), the lower circular opening ( 5 ) has a circumference from 95 to 99.5% of the maximum circumference of the cone sleeve ( 4 ), thereby creating an effective seal between a bottommost cone sleeve and the chamber, and the chamber ( 2 ) has inlets ( 9 ) connectable to a pressurised gas supply, wherein the inlets ( 9 ) are configured to direct gas horizontally or downwards into the chamber and at a rate greater than the gas can escape via the upper circular opening so as to create an elevated pressure within the chamber that causes the lowermost cone sleeve to be separated from the rest of the cone sleeve stack. 2. An apparatus according to claim 1 wherein the upper circular opening ( 3 ) has a circumference of at least 101% of the maximum circumference of the cone sleeve ( 4 ). 3. An apparatus according to claim 1 wherein the upper circular opening ( 3 ) has a circumference of at most 130% of the maximum circumference of the cone sleeve ( 4 ). 4. An apparatus according to claim 1 wherein the lower circular opening ( 5 ) has a circumference of at least 95.5% of the maximum circumference of the cone sleeve ( 4 ). 5. An apparatus according to claim 1 wherein the lower circular opening ( 5 ) has a circumference of at most 99.25% of the maximum circumference of the cone sleeve ( 4 ). 6. An apparatus according to claim 1 wherein the distance between the upper surface ( 7 ) and the lower surface ( 8 ) is at least 5 mm. 7. An apparatus according to claim 1 wherein the distance between the upper surface ( 7 ) and the lower surface ( 8 ) as measured inside the chamber is at most 100 mm. 8. An apparatus according to claim 1 wherein the inlets ( 9 ) are configured to direct gas downwards into the chamber. 9. An apparatus according to claim 1 wherein the apparatus comprises a cone sleeve stack holder. 10. An apparatus according to claim 9 wherein the cone sleeve stack holder comprises a nested stack of sleeves having rounded tips. 11. A process that employs the apparatus of claim 1 , the process comprising the steps of: a) providing a stack of nested cone sleeves ( 1 ); b) placing the lowermost end of the stack into the chamber ( 2 ) from above the chamber ( 2 ); and c) allowing the lowermost cone sleeve ( 4 ) to sit within the lower circular opening ( 5 ) and allowing the cone sleeves above the lowermost cone sleeve ( 4 ) to protrude from the top of the chamber ( 2 ) characterised in that pressurised gas is introduced into the chamber via the inlets ( 9 ) thereby to create an elevated pressure within the chamber ( 2 ). 12. A process according to claim 11 wherein the elevated pressure in the chamber ( 2 ) is at least 100 kPa. 13. A process according to claim 11 wherein the elevated pressure in the chamber ( 2 ) is at most 100 kPa. 14. An apparatus for separating a cone sleeve ( 4 ) from a nested stack of cone sleeves ( 1 ), the apparatus comprising a chamber ( 2 ) having an upper ( 7 ) and a lower ( 8 ) surface connected by a wall or walls ( 6 ), the upper surface ( 7 ) having an upper circular opening ( 3 ) and the lower surface ( 8 ) having a lower circular opening ( 5 ) wherein the ratio of the circumference of the upper circular opening ( 3 ) to the circumference of the lower circular opening ( 5 ) is at most 1.5:1 wherein the lower circular opening ( 5 ) has a circumference from 95 to 99.5% of the maximum circumference of the cone sleeve ( 4 ) thereby creating an effective seal between a bottommost cone sleeve and the chamber and wherein the inlets ( 9 ) are configured to direct air horizontally or downwards into the chamber and at a rate greater than the air can escape via the upper circular opening so as to create an elevated pressure within the chamber that causes the lowermost cone sleeve to be separated from the rest of the cone sleeve stack.