1. Field of the Invention
The invention deals with the field of three dimensional printing, more specifically the printing of relief features on a rotating cylindrical support using a fluid depositing apparatus such as an inkjet printhead. Even more specifically, the invention deals with the field of creating a flexographic print master on a rotating drum by a depositing printhead that moves in a slow scan direction and deposits curable liquid such as a UV-curable liquid.
2. Description of the Related Art
In flexographic printing or flexography a flexible cylindrical relief print master is used for transferring a fast drying ink from an anilox roller to a printable substrate. The print master can be a flexible plate that is mounted on a cylinder, or it can be a cylindrical sleeve.
The raised portions of the relief print master define the image features that are to be printed.
Because the flexographic print master has elastic properties, the process is particularly suitable for printing on a wide range of printable substrates including, for example, corrugated fiberboard, plastic films, or even metal sheets.
A traditional method for creating a print master uses a light sensitive polymerisable sheet that is exposed by a UV radiation source through a negative film or a negative mask layer (“LAMS”-system) that defines the image features. Under the influence of the UV radiation, the sheet will polymerize underneath the transparent portions of the film. The remaining portions are removed, and what remains is a positive relief print plate.
In the unpublished applications EP08172281.1 and EP08172280.3, both assigned to Agfa Graphics NV and having a priority date of 2008-12-19, a digital solution is presented for creating a relief print master using a fluid droplet depositing printhead.
The application EP08172280.3 teaches that a relief print master can be digitally represented by a stack of two-dimensional layers and discloses a method for calculating these two-dimensional layers.
The application EP08172281.1 teaches a method for spatially diffusing nozzle related artifacts in the three dimensions of the stack of two-dimensional layers.
Both applications also teach a composition of a fluid that can be used for printing a relief print master, and a method and apparatus for printing such a relief print master.
An example of a printhead is shown in
Because in the apparatus in
In
A prior art system such as the one depicted in
The droplets that are ejected by the nozzles of the printhead 210, 440 have a finite velocity while they travel to their landing position. As a result it takes some time for them to reach their landing position on the rotating drum. The effect can be described as “landing position lag”. This landing position lag—by itself—poses no problem. However, in the prior art system shown in
In order to overcome the problems described above, preferred embodiments of the invention reduce the geometrical distortion of the matrix of cured droplets that make up the relief print master and that results from the effects of landing position lag in a prior art system as the one shown in
Preferred embodiments of the invention are realized by a system described below wherein the printhead is rotated in the plane that corresponds with its nozzle plate by an amount that reduces the effects of landing position lag.
Various specific preferred embodiments are also described below.
The above and other elements, features, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of the preferred embodiments with reference to the attached drawings.
In
In
Every nozzle of the printhead has an index number j that in
The Y dimension in
The X dimension in
The Z direction is orthogonal to both the X and Y dimensions and indicates the height with regard to a reference surface in an X-Y plane. In
In a more general preferred embodiment, a printhead unit according to the current invention can have any number of nozzles on a nozzle row higher than one. Also, in a more general preferred embodiment a printhead unit can optionally have multiple parallel nozzle rows that can be staggered, for example for increasing the resolution of the printhead unit compared with the resolution of the individual printheads. In that case, the multiple parallel rows are located in a plane that is parallel with a tangent plane of the rotating cylindrical support.
The nozzles 1, 2, 3, 4 and 5 of the printhead unit 520 eject droplets that land on the different layers 511, 512, 513, 514 and 515. The landing positions are indicated with the reference numbers 1′, 2′, 3′, 4′ and 5′.
The positions 1′, 2′, 3′, 4′ and 5′ of the landed droplets can be connected by a curve 550.
The printhead 440, 520 has a leading edge portion that contains a nozzle that jets onto a layer having a relatively smaller diameter and a trailing edge portion that comprises a nozzle that jets onto a layer having a relatively (with regard to the layer on which the nozzle belonging to the leading edge jets) larger diameter. For example, in
PART 1 of the Mathematical Analysis
In
The circumference of such a layer i is represented by the variable Circumference[i] and has a value equal to:
Circumference[i]=PI*Diameter[i]
The sleeve rotates in an X-direction at a frequency that is represented by the variable NumberofRevolutionsperSecond (revolutions per second frequency F). The circumferential speed of a given layer i of the sleeve is represented by the variable CircumferentialSpeed[i] and expresses the displacement Δx[i] of a surface point on the layer in the X dimension (x-dimension) per time unit.
CircumferentialSpeed[i]=Δx[i]/Δt
The value of CircumferentialSpeed[i] is equal to:
PART 2 of the Mathematical Analysis
A nozzle[j] ejects a droplet at a time point t1 with a speed equal to DropletVelocity (droplet velocity speed S) in the Z-dimension. The value of the speed DropletVelocity is a characteristic of the printhead unit and is expressed by:
DropletVelocity=dz/dt
Δz[i][j] is the distance between a nozzle[j] and the surface of a layer[i] on which the droplets ejected by nozzle[j] land. For example, in
If it is assumed that the droplet velocity is constant over the trajectory Δz[i][j], the time Δt[i][j] it takes for the droplet to travel over the distance Δz[i][j] is expressed by:
Δt[i][j]=Δz[i][j]/DropletVelocity
The droplet ejected by a nozzle[j] arrives at the surface of the layer[i] at a time t2 which is equal to:
t2=t1+Δz[i][j]/DropletVelocity
PART 3 of the Mathematical Analysis
Referring to
Similarly, x[j][i] (second coordinate (N1, L1) refers to the x-coordinate of a droplet that was ejected by nozzle[j] and that has landed on layer[i].
The difference between the x-coordinate x[j][0] of the nozzle[j] and the x-coordinate x[j][i] is referred to as Δx[j][i] (variable Δx) and is defined as:
Δx[j][i]=x[j][i]−x[j][0]
While a droplet ejected by a nozzle[j] travels from the orifice of the nozzle to the surface of a layer[i] of the drum, this surface has moved during a period Δt[i][j] over a distance Δx[i][j] in the x dimension that is equal to:
Δx[i][j]=CircumferentialSpeed[i]*Δt[i][j]
Substituting in the above expression the variables CircumferentialSpeed[i] and Δt[i][j] leads to:
Δx[i][j]=CircumferentialSpeed[i]*Δz[i][i]/DropletVelocity
Δx[i][j]=PI*Diameter[i]*NumberofRevolutionsperSecond*Δz[i][j]/DropletVelocity
If the nozzle plate of a printhead is located at a distance having a value NozzlePlateDistance from the axis of the drum, and a layer[i] on the drum has a diameter equal to Diameter[i], then the distance Az[i][j] between a nozzle[j] and a layer[i] can be expressed as:
Δz[i][j]=NozzlePlateDistance−Diameter[i]/2
By substituting this expression for Δz[i][j] into the expression for Δx[i][j], the following new expression is obtained for Δx[i][j]:
Δx[i][j]=PI*Diameter[i]*NumberofRevolutionsperSecond*(NozzlePlateDistance−Diameter[i]/2)/DropletVelocity
The above expression provides the value for the x-coordinate of the landing position:
x[j][i]=x[j][0]+Δx[j][i]
x[j][i]=x[j][0]+PI*Diameter[i]*NumberofRevolutionsperSecond*(NozzlePlateDistance−Diameter[i]/2)/DropletVelocity
Defining a constant K having a value equal to:
K=PI*NumberofRevolutionsperSecond/DropletVelocity
optionally simplifies the expression for Δx[i][j] to:
Δx[i][j]=K*Diameter[i]*(NozzlePlateDistance−Diameter[i]/2)
PART 4: Interpretation of the Mathematical Analysis
For a given nozzle[j], the expression for Δx[i][j] is a quadratic function of the Diameter[i] of the layer[i] on which its ejected droplets land.
K is a constant of which the sign depends on the sign of variable NumberofRevolutionsperSecond. In what follows it is assumed that both the variables NumberofRevolutionsperSecond and hence K have a positive sign.
The structural relation between the drum and the printhead dictates that for an arbitrary layer the following constraint must be met:
Diameter[i]/2<=NozzlePlateDistance
The value of Δx[i][j] becomes 0 in the special case that:
Diameter[i]/2=NozzlePlateDistance
As the value Diameter[i] of the diameter of a layer linearly decreases, the absolute value of Δx[i][j] quadratically increases.
In a practical situation the variations of the variable Diameter[i] are small compared with the value of NozzlePlateDistance.
In that case the quadratic function can be locally approximated by a straight line. The slope of this straight line is expressed by the first derivative of the quadratic function:
δ(Δx[i][j])/δ(Diameter[i])=K*(NozzlePlateDistance−Diameter[i])
For layers nearby the nozzle plate, the variable Diameter[i] has a value that is approximately equal to 2*NozzlePlateDistance, the value of the first derivative is equal to:
δ(Δx[i][j])/δ(Diameter[i])=−K*NozzlePlateDistance
In that case the local expression for Δx[i][j] becomes:
Δx[i][j]≈K*NozzlePlateDistance*(2*NozzlePlateDistance−Diameter[i])
PART 5: Correction
Referring to
Δx[1][1]=K*Diameter[1](NozzlePlateDistance−Diameter[1]/2)
Δx[5][5]=K*Diameter[5](NozzlePlateDistance−Diameter[5]/2)
The difference (Δx[5][5]−Δx[1][1]) in the x dimension between the landing positions of droplets ejected by nozzle[1] and nozzle[5] is expressed by:
(Δx[5][5]−Δx[1][1])=K*NozzlePlateDistance*(Diameter[5]−Diameter[1])−K*(Diameter[5]2−Diameter[1]2)/2
All the values in the above expression are design parameters of the system so that the value of (Δx[5][5]−Δx[1][1] can be easily evaluated.
In
As a result of this rotation, the landing position of a droplet that is ejected by the nozzle[5] is moved over a distance having a value ΔxRotatedHead[5] in the x direction.
The displacement of ΔxRotatedHead[5] is expressed by
ΔxRotatedHead[5]=sin(α)*(5−1)*NozzlePitch
By selecting an appropriate value for a, it is possible to obtain that the difference (Δx[5][5]−Δx[1][1]) between the landing positions of droplets ejected by nozzle[1] and nozzle[5] in the X-dimension is exactly compensated by the displacement ΔxRotatedHead[n] that results from rotating the printhead with an angle α.
Mathematically, this translates into the following requirement:
(Δx[5][5]−Δx[1][1])=ΔxRotatedHead[5]
The value for α that should be selected to meet this condition is:
α=α sin {(Δx[5][5]−Δ[1][1])/((5−1)*NozzlePitch)}
As
In a more general case a printhead has N nozzles having index numbers i (i=1, 2, 3, . . . N) and ejects droplets on M layers having index numbers j (j=1, 2, 3, . . . M).
The generalized formula for obtaining the angle α for rotating the printhead so that the droplets of two different nozzles, having index numbers j1 and j2 (1<=j1<j2<=N) and that jet on layers having index numbers i1 and i2 (1<=i1<=i2<=M), fall on a line parallel with the Y dimension is:
α=α sin {(Δx[i2][j2]−Δx[i1][j1])/((j2−j1)*NozzlePitch)}
In which:
Using the above formula leads to a compensation that—under the given assumptions—will bring the landing positions of droplets ejected by the nozzle[j1] (first nozzle N1) and nozzle[j2] (second nozzle N2) on a line that is parallel with the Y dimension.
In the example shown in
In
In the above mathematical analysis it was explicitly assumed that the speed of the droplets between the time they leave the nozzle plate and the time they land on a layer remains constant. This is only approximately true. In a real situation, the speed of a droplet ejected by a nozzle diminishes while it travels through space from the orifice towards its landing position. The effect of this is that the difference of the landing position along the X-dimension of droplets landing on layers with different diameters increases even more than what is predicted by the expression for Δx[j][i]. In that case compensation is necessary by rotating the printhead by an amount that is larger than the value of a that is predicted in the above formula for this angle. Consequently, a preferred embodiment of the current invention specifies the value for α using the following inequality:
α=r*a sin {(Δx[i2][j2]−Δx[i1][j1])/((j2−j1)*NozzlePitch)}
in which: 1.0<=r
In another preferred embodiment α meets the following constraint:
α=r*a sin {(Δx[i2][j2]−Δx[i1][j1])/((j2−j1)*NozzlePitch)}
In which: 1.0<=r<=2.0
In yet another preferred embodiment α meets the following constraint:
α=r*a sin {(Δx[i2][j2]−Δx[i1][j1])/((j2−j1)*NozzlePitch)}
In which: 1.0<=r<=1.1
There may be instances that it is not necessary or even desirable to rotate the printhead by an amount that achieves maximum compensation for the x coordinate of the landing positions of droplets ejected by nozzles on different layers.
In one preferred embodiment the rotation by the angle α meets the following constraint:
α=r*a sin {(Δx[i2][j2]−Δx[i1][j1])/((j2−j1)*NozzlePitch)}
In which: 0.1<=r<=1.0
In another preferred embodiment the rotation by the angle α meets the following constraint:
α=r*a sin {(Δx[i2][j2]−Δx[i1][j1])/((j2−j1)*NozzlePitch)}
In which: 0.5<=r<=1.0
In yet another preferred embodiment the rotation by the angle α meets the following constraint:
α=r*a sin {(Δx[i2][j2]−Δx[i1][j1])/((j2−j1)*NozzlePitch)}
In which: 0.9<=r<=1.0
Thus, a system for preparing a cylindrical relief object includes:
a cylindrical support having a central axis and rotating at a revolutions per second frequency F, a tangent line along the cylindrical support that is orthogonal to the central axis defining an x-dimension;
a fluid ejecting printhead including a row of nozzles including orifices in a nozzle plate, two adjacent nozzles of the row of nozzles being spaced at a nozzle pitch distance D1, the row of nozzles having a nozzle plate distance D2 from the central axis of the cylindrical support, the nozzles ejecting fluid droplets at a droplet velocity speed S towards the cylindrical support, the printhead moving parallel to the central axis of the cylindrical support at a speed that is locked to a frequency of the rotating cylindrical support; and
a curing source; wherein
the printhead includes a leading edge portion including a first nozzle N1 ejecting fluid droplets on a first layer L1, the first layer having a first diameter DI1, a radial line connecting the first nozzle N1 with the central axis defining a first coordinate (N1, 0) along the x-dimension;
a radial line that connects a landing position on the first layer L1 of a droplet ejected by the first nozzle N1 with the central axis defining a second coordinate (N1, L1) along the x-dimension that is equal to the following equation:
(N1,0)+PI*DI1*F*(D2−DI1)/2)/S;
a difference between (N1, 0) and (N1, L1) defining a first variable Δx1 that is equal to (N1, L1)-(N1, 0);
the printhead includes a trailing edge portion including a second nozzle N2 ejecting fluid droplets on a second layer L2, the second layer L2 having a second diameter DI2 that is larger than the first diameter D1, a radial line connecting the second nozzle N2 with the central axis defining a third coordinate (N2, 0) along the x-dimension;
a radial line that connects a landing position on the second layer L2 of a droplet ejected by the second nozzle N2 with the central axis defining a fourth coordinate (N2, L2) that is equal to the following equation:
(N2,0)+PI*DI2*F*(D2−DI2/2)/S;
a difference between (N2, 0) and (N2, L2) defining a second variable Δx2 that is equal to (N2, L2)-(N2, 0);
the nozzle plate in which the row of nozzles is located is rotated by an amount equal to the following equation:
r*a sin [(Δx2−Δx1)−((N2−N1)*D1],
in a plane that is parallel to a tangent plane of the cylindrical support,
with regard to a direction of the central axis of the cylindrical support; and
r>0.1.
Having explained the preferred embodiments of the invention in the context of preparing a relief print master, it should be clear to the person skilled in the art that the same inventive concepts can be used for creating other three-dimensional objects on a cylindrical drum than a relief print master for flexography. In general, any relief object that fits on a cylindrical drum and that can be printed using curable liquid can benefit from using the invention.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
Number | Date | Country | Kind |
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10173538 | Aug 2010 | EP | regional |
This application is a 371 National Stage Application of PCT/EP2011/063625, filed Aug. 8, 2011. This application claims the benefit of U.S. Provisional Application No. 61/375,251, filed Aug. 20, 2010, which is incorporated by reference herein in its entirety. In addition, this application claims the benefit of European Application No. 10173538.9, filed Aug. 20, 2010, which is also incorporated by reference herein in its entirety.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2011/063625 | 8/8/2011 | WO | 00 | 2/11/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/022650 | 2/23/2012 | WO | A |
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Number | Date | Country | |
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20130133572 A1 | May 2013 | US |
Number | Date | Country | |
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61375251 | Aug 2010 | US |