Abstract:
An ink jet transfer printer including an ink jet print head and a print drum, the ink jet print head for printing ink onto the print drum which transfers the ink to a print medium during a print cycle. The ink jet transfer printer comprising: a print surface defining a print plane located on the print drum, the print surface raised above the peripheral surface of the print drum; and wherein the ink jet print head prints onto the print surface and the ink on the print surface forms a contact angle substantially in a range of 20 to 60 degrees. The ink jet transfer printer further comprising: a wiper blade in engagement with the print surface during the print cycle for wiping waste ink from the print surface; and a cleaning device in engagement with the print surface during the print cycle for absorbing waste ink from the print surface; and wherein, following transfer of the ink from the print surface to the print medium, the cleaning device absorbs waste ink prior to the wiper blade wiping waste ink.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is a related to copending U.S. patent application Ser. No. 08/767,354 filed concurrently on Dec. 18, 1996 herewith, and entitled HYBRID PRINTING POSTAGE PRINTER, the disclosure of which is specifically incorporated herein by reference. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates generally to ink jet printers. More particularly, the invention relates to an ink jet transfer printer including an ink jet print head, a print surface and a maintenance apparatus. 
     BACKGROUND OF THE INVENTION 
     Ink jet printers are well known in the art. Generally, an ink jet direct printer includes a print head having an array of nozzles or orifices, a supply of ink and a plurality of ejection elements (typically either expanding vapor bubble elements or piezoelectric transducer elements) corresponding to the array of nozzles for ejecting the ink from the nozzles. The ink ejected in this manner forms drops which travel along a trajectory or flight path until they reach a print medium such as a sheet of paper, overhead transparency, envelope or the like. Once they reach the print medium, the drops dry and collectively form a print image. Typically, the ejection elements are selectively energized so that a predetermined or desired print image is achieved. 
     In some applications, it is desirable to employ an ink jet transfer printer instead of an ink jet direct printer. The ink jet transfer printer is similar to the ink jet direct printer except that the ink jet transfer printer does not print directly on the print medium. Instead, the ink jet transfer printer prints a negative of a desired image onto an intermediate print surface. The print surface is subsequently brought into contact with the print medium so that the image from the print surface transfers to the print medium. Thus, it is apparent that the maintenance of the print surface and the interaction of the ink with the print surface significantly influence print quality. For example, if the ink &#34;wets&#34; too much (spreads too thinly) upon contact with the print surface, then a distorted image will likely result. On the other hand, if the ink &#34;beads&#34; too much (forms a drop with little surface contact with the print surface per unit volume of ink), then a distorted image will also likely result. 
     Recently, the postage meter industry and other envelope printing industries have begun to incorporate ink jet printers. A typical postage meter applies evidence of postage, commonly referred to as a postage indicia, to an envelope or other mailpiece and accounts for the value of the postage dispensed. In this manner the dispensing of postal funds is accurately tracked and recorded. 
     In traditional postage meters, two types of printing means are employed: one being a die plate located on the peripheral surface of a print drum that is adapted to print the fixed portion of the postage indicia, such as the graphics design, town and state, while the other print means is adapted to print the variable portion of the postage indicia, such as the date and value of postage dispensed. In such traditional postage meters, this printing means usually includes a plurality of print wheels which project through suitable apertures formed in the curved surface of the die plate. Each print wheel contains a plurality of alpha-numeric characters which are selectively rotatable to project through the die plate. In order to print the postage indicia, the print drum is rotated and the die plate and the print wheels are suitably inked prior to the print drum coming into contact with the envelope. After inking, the print drum continues to rotate and the die plate and the print wheels are brought into contact with the envelope where the ink transfers to the envelope resulting in the postage indicia printed on the envelope. 
     In order to vary the postage value and the date, the operative positions of the print wheels, which are mounted to bodily rotate with the interior of the print drum, must be changed. Since these print wheels are not directly accessible to the operator, the print wheels are operatively connected to an associated setting mechanism which is also located primarily inside the print drum. The setting mechanism is normally connected to a motor for rotating the print wheels to a desired position in response to inputs from a keyboard. In the alternative, the setting mechanism is connected to levers which extend outside the postage meter housing so that the operator can manipulate the print wheels manually. Both of these arrangements necessitate a rather intricate, complex and costly mechanism to enable the print wheels to be set to a desired position and then rotated along with the print drum through a print cycle. 
     The postage meters disclosed in U.S. Pat. No. 3,869,986 entitled INK JET PRINTING POSTAGE PRINTING APPARATUS and U.S. Pat. No. 4,673,303 entitled OFFSET INK JET POSTAGE PRINTING, both of which are assigned to the assignee of the present invention, depart from the traditional postage meters described above by incorporating ink jet printing technology. The print wheels and associated setting mechanisms are dispensed with and replaced with an ink jet print head. 
     Ink jet printers are well known in the art. Generally, an ink jet printer includes an array of nozzles or orifices, a supply of ink and a plurality of ejection elements (typically either expanding vapor bubble elements or piezoelectric transducer elements) corresponding to the array of nozzles for ejecting the ink from the nozzles. The ink ejected in this manner forms drops which travel along a trajectory or flight path until they reach a print medium such as a sheet of paper, overhead transparency, envelope or the like. Once they reach the print medium, the drops dry and collectively form a print image. Typically, the ejection elements are selectively energized so that a predetermined or desired print image is achieved. 
     In U.S. Pat. No. 3,869,986, the ink jet print head is positioned to print directly on the envelope through suitable apertures in the print drum while the print drum is rotating through a print cycle. The print drum still contains a die plate for printing the fixed portion of the postage indicia while the ink jet print head prints the variable portion. 
     Although this system removes the complexity of the setting mechanism, it suffers from various drawbacks. For example, the nozzles of the print head must be energized at the precise moment when the aperture appears between the print head and the envelope. Otherwise, the ink will deposit on the inner surface of the print drum instead of the envelope. Thus, the timing of the rotation of the print drum and the energizing of the nozzles must be precisely controlled. As another example, no provisions are made for the maintenance of the print head. Left unattended, the print head may either drip ink or in the alternative become clogged due to evaporation of ink or an accumulation of paper dust and other contaminants. Clearly, either event is undesirable. Another drawback is that the print head is spaced far away from the envelope due to the thickness of the print drum. Thus, a large print gap is created which reduces print quality. 
     In U.S. Pat. No. 4,673,303, the ink jet print head is positioned to print on the print drum. The print drum includes a first region containing the die plate of the fixed portion of the postage indicia and a second region which receives ink from the print head. During a print cycle, the second region is depressed below the periphery of the print drum so that the inking rollers for the first region do not spread ink onto the second region. Then, the second region is brought back into alignment with the periphery of the print drum and the print head applies ink thereon to form the variable portion of the postage indicia. As the print drum comes into contact with the envelope, both the ink from the die plate and the second region are transferred to the envelope. 
     Although this system removes the complexity of the setting mechanism, it suffers from various drawbacks. For example, depressing and raising the second region during a print cycle requires a complex mechanism. Additionally, this system does not provide for maintenance of the print head. Therefore, it suffers from the same drawbacks as previously discussed above. As another example, this system makes no provisions for maintenance of the second region. Therefore, stray ink drops could collect on the second region and transfer to the envelope during printing which would result in a poor quality postage indicia. Still another example, residual ink which did not transfer to the envelope would remain on the second region and contaminate subsequent printing. 
     For all of the above reasons, it becomes apparent that there are difficulties and drawbacks associated with the prior art postage meters employing ink jet printers. Therefore, there is a need for an ink jet transfer printer which substantially overcomes the problems associated with the prior art. 
     SUMMARY OF THE INVENTION 
     It is an object of the present invention to present an ink jet transfer printer that substantially overcomes the disadvantages and problems associated with the prior art systems. 
     In accomplishing this and other objects there is provided an ink jet transfer printer including an ink jet print head and a print drum, the ink jet print head for printing ink onto the print drum which transfers the ink to a print medium during a print cycle. The ink jet transfer printer comprising: a print surface defining a print plane located on the print drum, the print surface raised above the peripheral surface of the print drum; and wherein the ink jet print head prints onto the print surface and the ink on the print surface forms a contact angle substantially in a range of 20 to 60 degrees. The ink jet transfer printer further comprising: a wiper blade in engagement with the print surface during the print cycle for wiping waste ink from the print surface; and a cleaning device in engagement with the print surface during the print cycle for absorbing waste ink from the print surface; and wherein, following transfer of the ink from the print surface to the print medium, the cleaning device absorbs waste ink prior to the wiper blade wiping waste ink. 
     Additional objects and advantages of the invention will be set forth in the description which follows, and in part will be obvious to those skilled in the art from the description, or may be learned by practice of the invention. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate a presently preferred embodiment of the invention, and together with the general description given above and the detailed description of the preferred embodiment given below, serve to explain the principles of the invention. 
     FIG. 1 is a schematic representation of a perspective view of a postage meter incorporating the present invention. 
     FIG. 2 is a schematic representation of a front elevational view of the postage meter with a print drum in a home position in accordance with the present invention. 
     FIG. 3 is a schematic representation of a top view of the postage meter with the print drum in the home position in accordance with the present invention. 
     FIG. 4 is a schematic representation of a front elevational view of the postage meter with the print drum in an intermediate position along a print cycle in accordance with the present invention. 
     FIG. 5 is an example of a postage indicia suitable for use in the postage meter of the present invention. 
     FIG. 6 is timing diagram showing the velocity of the print drum during the print cycle. 
     FIG. 7 is schematic representation, taken along lines 7--7 of FIG. 2, of an ink drop on the second print surface of the print drum. 
     FIG. 8 is a schematic representation, taken along the edge of a wiper blade, and second print surface interface. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Referring to FIGS. 1 and 2, a first embodiment of a postage meter 100 including a base 102, a frame 104, a print drum assembly 110, a print head module 130, an ink roller assembly 150 and a print head maintenance module 170 incorporating the present invention is shown. Generally, an envelope 20 is fed in a path of travel along a deck 30 of a mailing machine (partially shown) as indicated by arrow A so as to pass underneath the print drum assembly 110 of the postage meter 100 which prints a postage indicia thereon. 
     Referring to FIG. 5, an example of a postage indicia 50 suitable for use with the present invention is shown. The postage indicia 50 includes a fixed portion 52 containing a graphics design and a variable portion 54 containing the variable information which changes with each envelope or from postage meter to postage meter, such as: date, postage value, town, meter serial number and other information necessary to detect fraudulent use of the postage meter 100. Alternatively, the meter serial number could be located in both the fixed portion 52 as well as the variable portion 54, or just in the fixed portion 52. 
     Referring to FIGS. 1, 2 and 3, the print drum assembly 110 includes a print drum 111 fixably mounted to a print drum shaft 112 which is rotatively mounted to extend between walls 104a and 104b of the frame 104. Also fixably mounted to the print drum shaft 112 is a gear 114 which extends through an aperture 103 in the base 102 so that a drive gear (not shown) protruding from a mailing machine is brought into meshed engagement with the gear 114 when the postage meter 100 is placed on the mailing machine. In this manner, the mailing machine supplies the drive means necessary to cause the print drum 111 to rotate. The print drum 111 includes a first print surface 116 having a die plate (not shown) for printing a fixed portion of the postage indicia and a second print surface 118 for printing a variable portion of the postage indicia. It is important to note that the first print surface 116 and the second print surface second print surface 118 are in substantial alignment which each other so that they both contact the envelope 20 during the print cycle. Together, the first print surface 116 and the second print surface 118 form a print plane which contacts the envelope 20. 
     The print drum assembly 110 further includes a pair of blocks 118B, which will be described in greater detail below, and an encoder system (not shown) of any suitable conventional design for tracking the position of the print drum 111. In this manner, the rotation of the print drum 111 can be accurately controlled and coordinated with the operation of a print head 134 to produce a quality print. A more detailed description of the operation of the print drum assembly 110 including the print drum 111 will be set forth below. 
     The print head module 130 includes a print head frame 131 fixably mounted to wall 104a, a print head bracket 132 and the print head 134. The print head frame 131 includes an angled portion 131a on which the print head bracket 132 is fixably mounted while the print head 134 is detachably mounted to the print head bracket 132. In the preferred embodiment, the print head 134 includes an ink reservoir 135 for storing a supply of ink and a plurality of nozzles 136 through which the ink is ejected. Thus, the print head 134 is designed to be replaced as needed by the operator loading in a new print head 134. The print head bracket 132 and the print head 134 are designed such that the nozzles 136 are spaced apart from and in opposed relationship to the second print surface 118 of the print drum 111 for printing the variable portion 54 of the postage indicia 50. 
     The ink roller assembly 150 is detachably mounted to wall 140a by any suitable conventional means. Thus, it too is designed to be replaced as needed by the operator. The ink roller assembly 150 includes a inking roller 152, an ink supply roller 154 and an ink housing 156 which contains a supply of ink. The inking roller 152 and the ink supply roller 154 are both rotatively mounted to the ink housing 156 so as to be in rotational engagement with each other. The ink supply roller 154 remains in contact with the supply of ink and ensures that the inking roller 152 is sufficiently saturated with ink. The inking roller 152 is positioned to also be in rotational engagement with the first print surface 116 of the print drum 111. In this manner, ink is applied to the die plate of the first print surface 116 for printing the fixed portion 52 of the postage indicia 50. It is important to note that the ink contained in the ink roller assembly 150 may be the same as or different from the ink utilized by the print head 134. 
     The print head maintenance module 170 includes a print head cap 190 which is adapted to fit over the nozzles 136 of the print head 134 and a mechanism for repositioning the print head cap 190 into and out of engagement with the print head 134 in relation to the rotation of the print drum 111. In the preferred embodiment, the print head cap 190 is designed to provide an air tight seal around the print head 134 and is operatively connected to a suitable vacuum source (not shown) for sucking ink from the nozzles 136. Since the operation of print head maintenance modules is well known in the art and since it does not constitute a part of the present invention, no further description is being provided. 
     The mechanism for repositioning the print head cap 190 includes a cam 171 fixably mounted to the print drum shaft 112 so as to rotate along with the print drum 111 during a print cycle, a follower plate 174, a follower 176 and a cap plate 180. The follower plate 174 and the cap plate 180 are pivotally mounted along side each other to a pivot shaft 172 which is in turn fixably mounted to wall 104a. Rotatively mounted to the follower plate 174 is a follower 176 which is biased against the cam 171 by a follower spring 178 extending between the follower plate 174 and wall 104a. Thus, the follower 176 remains in rolling contact with the cam 171 and causes the follower plate 174 to pivot about the pivot shaft 172 in accordance with the position of the follower 176 on the cam 171. Fixably mounted to and extending outward from the cap plate 180 is a pin 194 which is in slotted engagement with a slot 175 in the follower plate 174. A plate spring 182 extends between a pin 192 fixably mounted on the follower plate 174 and the pin 194. In this manner, the follower plate 174 and the cap plate 180 are operatively coupled so that the cap plate 180 is biased outward. Thus, since the print head cap 190 is fixably mounted to the cap plate 180, the print head cap 190 is biased toward the print head 134. 
     Referring to FIGS. 1, 2, 3 and 8, in order to produce a quality print, the postage meter 100 includes further devices designed to maintain the print drum 111, and more particularly the second print surface 118. A wiper blade 142 is positioned to engage the second print surface 118 during the print cycle and prior to the print head 134 applying ink to the second print surface 118. In this manner, the second print surface 118 is wiped clean before each print cycle. The wiper blade 142 is mounted to a wiper blade leaf spring 144 which is in turn mounted to a wiper blade bracket 140 fixably attached to wall 104a. Thus, the wiper blade 142 is biased toward the print drum 111 to ensure that the wiper blade 142 remains in intimate contact with second print surface 118. Preferably, the wiper blade 142 is made from any suitably durable material which demonstrates appropriate elastomeric properties so as to clean the second print surface 118 without damaging or scratching the second print surface 118, such as urethane. Thus, the wiper blade 142 is compliant so that waste ink is pushed over rounded lateral edges 118a of the second print surface 118 into an area 119 which is below the print plane. Because area 119 is below the print plane, this waste ink will not transfer to the envelope 20. It is important to note that in the preferred embodiment the wiper blade 142 is wider than the second print surface 118 so that the wiper blade 142 conforms around edges 118a. 
     Additionally, the postage meter 100 includes a cleaning roller 160 which is rotatively mounted to a cleaning roller shaft 162 which is in turn fixably mounted to wall 104a. The cleaning roller 160 is located to be in contact with the second print surface 118 during the print cycle but only after the print head 134 has applied ink to the second print surface 118 and the ink has been transferred to the envelope 20. Thus, in contrast to the wiper blade 142, the cleaning roller 160 performs a post-printing cleaning operation. Preferably, the cleaning roller 160 is made of a resilient foam material having suitable ink absorption properties. Alternatively, the cleaning roller 160 could be a pad or web of absorbent material. In addition to cleaning the second print surface 118, the cleaning roller 160 also picks up any waste ink which has been pushed over into area 119. 
     It should now be apparent that the ink jet printer of the present invention has been designed so that the wiper blade 142 comes into contact with the second print surface 118 after the cleaning roller 160. In this manner, the cleaning roller 160 absorbs the majority of the waste ink that does not transfer to the envelope 20 and then the wiper blade 142 wipes any residual film of waste ink from the second print surface 118 before the print head 134 prints on the second print surface 118 for the next print cycle. 
     The postage meter 100 further includes a pair of conventional eject rollers 120 which are mounted to an eject roller frame 126 using eject roller arms 122 and eject roller brackets 124. Extending between the eject roller arms 122 and the eject roller brackets 124 are a pair of eject roller springs 128 which operate to bias the eject rollers 120 toward the eject pressure rollers 42. 
     With the structural aspects of the postage meter 100 described as above, the operational aspects of the postage meter 100 will now be described. Referring to FIG. 2, the print drum 111 is shown in the home position. In this position, the print head cap 190 is held firmly against the print head 134 so that the nozzles 136 are sealed off from the ambient air. In this position, various maintenance routines involving purges of the nozzles 136 and applying suction to the nozzles 136 can be performed. When the print drum 111 is in the home position, the wiper blade 142 is in contact with a lead beveled edge 118L of the print drum 111 which is in alignment with a beginning portion of the second print surface 118. In this manner, any ink that the wiper blade 142 has collected will drain onto this surface. Alternatively, those skilled in the art will recognize that the wiper blade 142 need not contact the lead beveled edge 118L when the print drum 111 is in the home position so long as at the beginning of the print cycle the wiper blade 142 contacts the lead beveled edge 118L before contacting the second print surface 118. In this manner, the wiper blade 142 will not leave a line of waste ink on the second print surface 118. 
     Since the lead beveled edge 118L is below the print plane (the second print surface 118), any ink collected in this area will generally not transfer to the envelope 20. Furthermore, as the print drum 111 rotates, the ink collected along the lead beveled edge 118L will be wiped up by the cleaning roller 160. In similar fashion, a trailing beveled edge 118T is in alignment with ending portion of the second print surface 118. As the print drum 111 rotates, any ink collected by the wiper blade 142 will be deposited along the trailing beveled edge 118T. This ink will also be cleaned up by the cleaning roller 160. 
     Generally, the wiper blade 142 will tend to leave a pool of waste ink on the second print surface 118 just as it touches the lead beveled edge 118T and as it leaves the trailing beveled edge 118T. Under certain conditions (envelope pillowing), this waste ink may transfer to the envelope 20 if not completely absorbed by the cleaning roller 160. Therefore, the blocks 118B are located on either side of the second print surface 118 are in radial alignment around the print drum 111 with the lead beveled edge 118T so as to prevent the lead beveled edge 118L from coming into contact with the envelope 20. The blocks 118B are also in substantial alignment with the print plane so that they contact and press the envelope 20 flat. In the preferred embodiment, the trailing beveled edge 118T would also have corresponding blocks (not shown) which would serve in the same capacity as those for the lead beveled edge 118L. 
     The print drum 111 remains in the home position until the print cycle is initiated. Referring to FIG. 4, the print drum 111 is shown just after the print cycle has been initiated. During the print cycle, the print drum 111 rotates in a counter clockwise direction as indicated by arrow B. Since the cam 171 rotates along with the print drum 111, the follower 176 repositions accordingly causing the follower plate 174 to pivot about the pivot shaft 172. As the follower plate 174 pivots, the cap plate 180 pivots in corresponding fashion and the print head cap 190 moves away from the print head 134 and toward the interior of the print drum 111. To accommodate this movement of the print head cap 190, the print drum 111 has a substantially hollow interior and a sufficiently large aperture 111a around its periphery. That is, the peripheral surface of the print drum 111 which contains the first print surface 116 and the second print surface 118 only extends approximately 180 degrees. The remainder of the print drum 111 is cut away to allow the print head cap 190 to reposition between a capped position up against the print head 134 while the print drum 111 is in the home position and an uncapped position interior to the print drum 111 while the print drum 111 is moving through the print cycle. 
     Referring to FIGS. 1, 3 and 4, as the print drum 111 rotates, the inking roller 152 applies ink to the die plate located on the first print surface 116. Additionally, the nozzles 136 of the print head 134 are selectively energized by any suitable controller to eject ink as the second print surface 118 passes by the nozzles 136. As the print drum 111 continues to rotate, it comes into contact with the envelope 20 which has been simultaneously fed along the deck 30 to pass underneath the print drum 111. The feeding of the envelope 20 and the rotation of the print drum 111 are synchronized so that the first print surface 116 and the second print surface 118 come into contact with the envelope 20 near its upper right hand corner. As the first print surface 116 and the second print surface 118 contact the envelope 20, the ink from these respective surfaces transfers to the envelope 20 leaving a printed image of the postage indicia 50 which includes both the fixed portion 52 and the variable portion 54. After printing, the print drum 111 continues to rotate until it again reaches the home position. 
     Located directly beneath the print drum 111, the mailing machine includes a print pressure roller 40 which is spring biased toward the print drum 111 in conventional fashion so as to accommodate the varying thicknesses of different envelopes 20. As the envelope 20 continues downstream from the print drum 111, it comes under the control of the eject rollers 120. The mailing machine further includes a pair of eject pressure rollers 42 in opposed relationship to the eject rollers 120 for assisting in feeding the envelope 20 from the postage meter 100. 
     It should now be apparent that the print head 134 is held stationary while the print head cap 190 is actuated into and out of engagement with the print head 134. On the other hand, those skilled in the art will recognize that with standard engineering modifications, print head cap 190 could be held stationary while the print head 134 is actuated into and out of engagement. Thus, relative movement between the print head and the cap can be achieved in a variety of ways. Those skilled in the art will also recognize that there are many mechanism suitable for providing relative movement between the print head and the cap. 
     Referring to FIG. 6, a timing diagram of a preferred velocity profile of the print drum during the print cycle is shown. It is important to note that this velocity profile is suitable for use with the present invention regardless of how the relative movement between the print head and the cap is achieved. Referring to FIGS. 4, 5 and 6, the print cycle occurs of a time interval between reference points T 0  and T 5 . At the beginning of the print cycle, the print drum 111 accelerates until it reaches a first velocity V 1  at point T 1 . The print drum 111 is held at velocity V 1  until point T 2 . During the interval from point T 1  to T 2 , the print head 134 produces the variable portion 54 of the postage indicia 50 on the second print surface 118 of the print drum 111. After the print head 134 finishes printing, the print drum 111 accelerates until it reaches a second velocity V 2  at point T 3 . The second velocity V 2  is selected so as to match the linear speed of the envelope 20 as it is fed underneath the print drum 111 by the mailing machine. After the inks from the first print surface 116 and the second print surface 118 have been transferred to the envelope 20, the print drum 111 begins to decelerate at point T 4  until it returns to the home position at point T 5 . 
     It will be appreciated by those skilled in the art that the first velocity V 1  and the second velocity V 2  are selected so as to produce quality printed postage indicia 50 at a high rate of throughput. Thus, the first velocity V 1 , which is dependent upon a variety of factors, such as: imaging speed, nozzle density and desired dot resolution, is selected so as to allow the print head 134 to produce a quality image on the second print surface 118 of the print drum 111. Generally, the second velocity V 2  is selected so as to increase throughput of the overall system. 
     It will be apparent to those skilled in the art that numerous other suitable velocity profiles could be derived depending upon the desired performance characteristics of the overall mailing machine. For example, if necessary, between points T 2  and T 3  the print drum 111 could be accelerated to a velocity greater than V 2  and then decelerated just prior to contact with the envelope 20 so as to match the speed of the envelope 20. In this manner, any time lost during the interval between points T 1  and T 2  can be made up. 
     Referring to FIG. 7, an ink drop D is shown on the second print surface 118. Empirical studies have indicated that a contact angle θ (formed by a line drawn tangent to the ink drop D at the point where the ink drop contacts the second print surface 118 and a horizontal line taken along the second print surface 118) in the range of 20 to 60 degrees yields a quality printed postage indicia 50. The contact angle θis a function of a variety of factors, such as: ink viscosity, ink surface tension, ink surface free energy and ink interaction with the second print surface 118. Depending upon the formulation of the ink and the material selection for the second print surface 118, those skilled in the art could formulate a wide variety of combinations which would achieve this contact angle. In the preferred embodiment, the second print surface 118 is made of polytetrafluoroethylene, such as teflon®, and the ink is hydrocarbon solvent and alcohol based with suitable pigments and resins. 
     Many features of the preferred embodiment represent design choices selected to best exploit the inventive concept as implemented in a postage meter. However, the present invention is applicable to other printers utilizing ink jet transfer printing. Those skilled in the art will recognize that the present invention is suitable for printing an entire image. Thus, the present invention should not be construed as restricted to employing dual printing technologies. Moreover, additional advantages than those described above and various other modifications will readily occur to those skilled in the art. Therefore, the inventive concept in its broader aspects is not limited to the specific details of the preferred embodiment but is defined by the appended claims and their equivalents.