Self-strip media module

1 . A module, comprising: a peel bar rotatable from a first position on a discharge side of a platen roller to a second position on a feed side of the platen roller and to a third position on the discharge side of the platen roller; wherein, when the peel bar is in the second position, media is fed over the peel bar and between the platen roller and a mid-chassis of a printer; wherein, when the peel bar is rotated from the second position to the third position after the media is fed over the peel bar and between the platen roller and the mid-chassis, the peel bar pulls the media over the platen roller and over itself; wherein the printer comprises a thermal printhead configured to be lowered onto the media over the platen roller and to print on media, the media comprising a series of labels adhered to a liner; and wherein, when the printer advances the media over the peel bar when the peel bar is in the third position, the labels are stripped from the liner as the media advances around the peel bar and the printer advances the liner around the peel bar and over the platen roller. 2 . The module of claim 1 , wherein the media is fed between the platen roller and the mid-chassis on the feed side of the platen roller. 3 . The module of claim 1 , wherein the liner is fed between the platen roller and the mid-chassis on the feed side of the platen roller. 4 . The module of claim 1 , wherein the peel bar has N sides in cross-section, where N is a number greater than or equal to 3. 5 . The module of claim 1 , wherein: the thermal print head and the media have a coefficient of friction μ1 therein between; the media has a coefficient of friction μ2 when pulled over itself; the media and the platen roller have a coefficient of friction μ3 therein between; μ3 is greater than μ1; and μ3 is greater than μ2. 6 . The module of claim 1 , wherein: the thermal print head and the media have a coefficient of friction μ1 therein between; the media has a coefficient of friction μ2 when pulled over itself; the media and the platen roller have a coefficient of friction μ3 therein between; and μ3 is greater than the sum of μ1 and μ2. 7 . The module of claim 1 , wherein the peel bar has a longitudinally extending edge whereby the label strips from the liner as the media advances around the edge of the peel bar. 8 . The module of claim 1 , wherein the peel bar is rotatable about pivot points separate from the platen roller. 9 . A method, comprising: rotating a peel bar over the platen roller from a discharge side of the platen roller to a feed side of the platen roller; feeding media over the peel bar and between the platen roller and a mid-chassis, the media comprising a series of labels and a liner; rotating the peel bar back over the platen roller towards the discharge side of the platen roller; lowering a thermal print head over the media and the platen roller; printing on a label of the media; advancing the media over and around the peel bar; and stripping the printed label off the liner when the media advances around the peel bar. 10 . The method of claim 9 , comprising advancing the liner to a liner tear bar on the printer. 11 . The method of claim 9 , wherein the step of rotating the peel bar back over the platen roller towards the discharge side of the platen roller comprises pulling the media with the peel bar over the platen roller. 12 . A module, comprising: a peel bar rotatable from a first position on a discharge side of a platen roller to a second position on a feed side of the platen roller and to a third position on the discharge side of the platen roller; wherein, when the peel bar is in the second position, media is fed over the peel bar and between the platen roller and a mid-chassis of a printer; wherein, when the peel bar is rotated from the second position to the third position after the media is fed over the peel bar and between the platen roller and the mid-chassis, the peel bar pulls the media over the platen roller and over itself; wherein the printer comprises a thermal printhead configured to be lowered onto the media over the platen roller and to print on labels, the media comprising a series of labels adhered to a liner; and wherein, when the printer advances the media over the peel bar when the peel bar is in the third position, the labels are stripped from the liner as the media advances around the peel bar. 13 . The module of claim 12 , wherein the peel bar is rotatably engaged at the ends of the platen roller. 14 . The module of claim 12 , wherein the printer is configured to advance the liner around the peel bar, over the platen roller, and around the platen roller after the labels are stripped from the liner. 15 . The module of claim 12 , wherein the media is fed between the platen roller and the mid-chassis on the feed side of the platen roller. 16 . The module of claim 12 , wherein: the liner is fed between the platen roller and the mid-chassis on the feed side of the platen roller. 17 . The module of claim 12 , wherein: the thermal print head and the media have a coefficient of friction μ1 therein between; the media has a coefficient of friction μ2 when pulled over itself; the media and the platen roller have a coefficient of friction μ3 therein between; μ3 is greater than μ1; and μ3 is greater than μ2. 18 . The module of claim 12 , wherein: the thermal print head and the media have a coefficient of friction μ1 therein between; the media has a coefficient of friction μ2 when pulled over itself; the media and the platen roller have a coefficient of friction μ3 therein between; and μ3 is greater than the sum of μ1 and μ2. 19 . The module of claim 12 , wherein the peel bar is rotatable about pivot points separate from the platen roller. 20 . The module of claim 12 , wherein the peel bar has more than two longitudinally extending edges.