Patent Description:
<CIT> discloses a post-processing apparatus and an image forming apparatus. <CIT> discloses sheet stacking trays. <CIT> discloses a device for disposing of printed books. <CIT> discloses an apparatus for preparing batches of sheets.

Various features of the present disclosure will be apparent from the detailed description which follows, taken in conjunction with the accompanying drawings, which together illustrate features of the present disclosure, and wherein:.

In the following description, for purposes of explanation, numerous specific details of certain examples are set forth. Reference in the specification to "an example" or similar language means that a particular feature, structure, or characteristic described in connection with the example is included in at least that one example, but not necessarily in other examples.

As described herein, an example stacking system comprises a stacking member, movable between a first position in which the stacking member is configured to partially support a first stack of printed substrates, and a second position in which the stacking member is disengaged from the first stack. The stacking system may further comprise a receptacle positioned below the stacking member that is configured to hold a second stack of printed substrates. A controller may be configured to cause the stacking member to move between the first position and the second position when the first stack satisfies a criterion, thereby depositing the first stack into the receptacle on top of the second stack.

The example stacking system can more precisely position printed substrates in a stack. For example, the use of one or more stacking members, and stacking the first stack independently of the second stack, may allow the positioning of the substrates to be accurately controlled.

For example, a first stacking scheme may specify a stack quality specification. The stack quality specification may specify that the maximum offset between substrates in a stack is no greater than a predetermined measurement value, such as about <NUM>, about <NUM>, or about <NUM> for example. Hence the stack quality specification may specify that the stack of printed substrates is well-ordered, and each substrate within the stack is well-aligned with the other substrates in the stack. In the stacking system described herein, by sequentially receiving and stacking a plurality of printed substrates on the stacking member to create a first stack of substrates, the stack can be positioned and adjusted accurately before depositing the first stack onto a second stack of substrates located below.

In addition, by keeping the first stack initially at least partially separate from the second stack, the substrates within the first stack can be ordered and aligned before placing onto the second stack. This ordering and alignment can be achieved by agitating the substrates within the first stack in one or more directions. For example, the substrates can be vibrated back and forth along a first axis to align the substrates along the first axis, and the substrates can be vibrated back and forth along a second, perpendicular axis, to align the substrates along the second axis. The first axis may be aligned with a length direction of the substrate, perpendicular to a transport direction. The second axis may be aligned with a width direction of the substrate, parallel to the transport direction.

A second stacking scheme may specify how substrates of different sizes/dimensions are stacked on top of each other. For example, a first batch of substrates may be of the same size, whereas a second subsequent batch of substrates may be of a different size to the first batch. The second batch may have different length and/or width dimensions to the first batch. Rather than creating a new, separate stack, the second batch may be stacked on top of the first batch in different ways. For example, the first and second batches may be aligned along a predetermined edge of the substrates, such as a trailing edge, a leading edge, a left edge and a right edge relative to a transport direction. In the stacking system described herein, allowing for a second stacking scheme can be achieved by using one or more stacking members. By sequentially receiving and stacking a plurality of printed substrates on the stacking member to create a first stack of substrates, the stack can be moved relative to the second stack of substrates below. One or more other elements may also be used to aid movement in other spatial dimensions, such as a direction or axis parallel to the transport direction. Alternatively, or additionally, spacing between the stacking members and/or other elements can be adjusted so that substrates of different sizes can be received.

A third stacking scheme may specify how batches of substrates are distinguished from other batches. For example, batches or print-jobs may be offset or displaced from each other. The offset may be along a length direction of the substrate, perpendicular to a transport direction. Each batch may then be easily identifiable from other batches. In the stacking system described herein, an offset may be achieved by using one or more stacking members. By sequentially receiving and stacking a plurality of printed substrates on the stacking member to create a first stack of substrates, the stack can be moved relative to the second stack of substrates below. In some examples, the batches may be offset by about <NUM>, about <NUM> or about <NUM>.

By using one or more stacking members to create a first stack of substrates before stacking these on a second stack of substrates, the stacking system may stack substrates that are received at irregular intervals.

In some examples, the system may be able to stack substrates in all the ways discussed above. No rigorous calibration process may be needed to ensure that substrates being stacked are well-aligned before deposited on a stack. For example, vacuum belt stacking systems involve calibration specific to each job/batch being printed. This process is labour intensive, and is prone to noise which can result in the stack failing to meet the stack quality specification for example.

<FIG> is a schematic diagram showing a printer system <NUM> in accordance with an example. The printing system <NUM> comprises a printer <NUM> and a stacking system <NUM>. The printing system <NUM> is configured to deposit printing fluid, such as ink, onto unprinted, or partially printed substrates <NUM>. Once printed upon, the printed substrates <NUM> may travel along a conveyor belt <NUM>, or any other conveying assembly, towards the stacking system <NUM> in a transport direction indicated by arrow <NUM>. The stacking system <NUM> is configured to stack the plurality of printed substrates <NUM>.

Components of the printing system <NUM> may be controlled by one or more controllers <NUM>. The controller <NUM> may comprise one or more processors for example. The controller <NUM> may further comprise memory, configured to store instructions that when executed, cause the processor(s) to implement one or more methods. For example, the controller may control the printer <NUM>, the conveyor assembly <NUM> and the stacking system <NUM>. The memory may be a non-transitory computer-readable storage medium in some examples. The controller <NUM> may be connected directly or indirectly to the various components of the printing system <NUM> via one or more communication paths <NUM>, <NUM>, shown depicted as dashed lines. In the example of <FIG>, the controller <NUM> is communicatively coupled to the printer <NUM> and the stacking system <NUM>, however, greater or fewer communication paths may also be present. In other examples, the printer <NUM> and stacking system <NUM> each have their own controller, which may operate independently of each other.

<FIG> depicts a plan, or top-down view of an example stacking system <NUM> arranged according to a first configuration. <FIG> depicts a side view of the stacking system <NUM> in the first configuration. The stacking system <NUM> may be part of a printing system <NUM>, for example. <FIG> shows printed substrates <NUM> being received in the stacking system <NUM> on a receiving assembly <NUM>. In the example of <FIG>, the receiving assembly comprises a conveyor belt, such as a vacuum belt, however in other systems the receiving assembly <NUM> may comprise a roller, a gripper bar, or flipping wheel, for example. The receiving assembly <NUM> is configured to receive the printed substrates <NUM> and position the substrates <NUM> within the stacking system <NUM>. In <FIG>, the receiving assembly <NUM> causes the substrates <NUM> to travel in a transport direction indicated by arrow <NUM>.

The stacking system <NUM> comprises a first stacking member <NUM> and a second stacking member <NUM> upon which a plurality of printed substrates <NUM> are sequentially received and stacked, to form a first stack <NUM>. The stacking members may have a generally flat or planar portion positioned underneath at least an edge region of the substrate and may be arranged either side of the transport direction. In other examples there may be one stacking member, or there may be more than two stacking members. The plurality of printed substrates <NUM> stacked on the stacking members <NUM>, <NUM>, may be partially supported by the stacking members <NUM>, <NUM>. For example, in <FIG> and <FIG> the stacking members <NUM>, <NUM> are positioned to engage with a peripheral or edge region of the substrates <NUM> stacked on the stacking members <NUM>, <NUM>. A peripheral or edge region may extend about <NUM>, about <NUM>, about <NUM> or about <NUM> from the edge of the substrate.

In some examples, the first stack <NUM> of printed substrates may bend slightly under the force of gravity as they are partially supported by the stacking members <NUM>, <NUM>. This is depicted in <FIG>. According to the invention, a second stack <NUM> of printed substrates positioned underneath the first stack <NUM> also partially supports the first stack <NUM> while the first stack <NUM> is being stacked on the stacking members <NUM>, <NUM>. In some examples, the first stack <NUM> may be supported by a base of the receptacle <NUM>. The extent to which the substrates bend may be dependent upon a variety of factors, such as thickness and material of the substrates, the area of substrate supported by the stacking members <NUM>, <NUM> and the spacing between the stacking members <NUM>, <NUM>. Hence, in some examples, the substrates may experience little or no bending while supported by the stacking members <NUM>, <NUM>, the second stack <NUM> and/or the receptacle base.

In the configuration of <FIG> and <FIG> the first stacking member <NUM> is positioned in a first position, such as a support position, in which the stacking member <NUM> is configured to partially support the first stack <NUM> of printed substrates. In this position, the first stacking member <NUM> engages the first stack <NUM> and an edge of the first stack <NUM> rests upon the first stacking member <NUM>. The first stacking member <NUM> may be moveable between this first position and a second position, such as a drop position, in which the stacking member is disengaged from the first stack <NUM>. For example, the first stacking member <NUM> may be moved along a first axis, in a direction <NUM> transverse to the transport direction <NUM> by an actuator, such as a piston <NUM>. Similarly, in the configuration of <FIG> and <FIG>, the second stacking member <NUM> is positioned in a third position, such as a support position, in which the stacking member <NUM> is configured to partially support the first stack <NUM> of printed substrates. Hence an edge of the first stack <NUM> rests upon the second stacking member. The second stacking member <NUM> may be moveable between this third position and a fourth position, such as a drop position, in which the stacking member is disengaged from the first stack <NUM>. For example, the second stacking member <NUM> may be moved along the first axis, in a direction <NUM> transverse to the transport direction by an actuator, which again is a piston <NUM>. Direction <NUM> may be opposite to direction <NUM>. Hence, the first and second stacking members may be moved along the first axis, but in opposite directions as they disengage from the first stack <NUM>.

<FIG> depicts a plan view of the example stacking system <NUM> arranged according to a second configuration after the first stacking member <NUM> has moved into the second position and after the second stacking member <NUM> has moved into the fourth position. <FIG> depicts a side view of the stacking system in the second configuration. In this configuration, the pistons <NUM> can be seen partially or fully extended as both stacking members <NUM> and <NUM> have been disengaged from the first stack <NUM>. Accordingly, the first stack <NUM> is no longer supported by the stacking members <NUM>, <NUM> and the first stack <NUM> may be deposited on a second stack <NUM> of printed substrates below.

Before receiving substrates to form the first stack, the first and second stacking members may be positioned in the first and third support positions respectively, so that the stacking members <NUM>, <NUM> sequentially receive a plurality of substrates <NUM> to form the first stack <NUM> of substrates. Once the first stack <NUM> of substrates has been created, a controller may cause the stacking members <NUM>, <NUM> to disengage from the first stack <NUM> by moving to the second and fourth drop positions, thereby causing the first stack <NUM> to deposit onto the second stack <NUM> arranged below the first stack <NUM>. The second stack <NUM> may therefore comprise previously stacked printed substrates. The first stack <NUM> moves downwards under the action of gravity as the stacking members <NUM>, <NUM> are removed from under the first stack <NUM>. Any bending of the substrates will then be removed by the action of gravity, such that the substrates will lay substantially flat within the newly formed stack. After this new stack has been created, the procedure may be repeated; the stacking members <NUM>, <NUM> move towards each other again, perpendicular to the transport direction, before receiving another stack of substrates.

To maintain the alignment of the first stack during the movement of the stacking members, the stacking members may be moved symmetrically relative to each about the transport direction. For example, the stacking members may move in opposite directions transverse to the transport direction at the same speed.

As mentioned, the first and second stacking members <NUM>, <NUM> may each move. For example, they may move along a first axis in either direction. The movement direction may be defined relative to a first axis, such as the x-axis shown depicted in each of <FIG>. Movement along the first axis includes any motion substantially parallel to the x-axis, and includes both forwards and backwards motion along the x-axis. In some examples, the first axis and therefore the x-axis is defined as being perpendicular to the direction in which the plurality of printed substrates <NUM> are received from the printer (the transport direction indicated by arrow <NUM>). In other examples, the first axis and therefore the x-axis is defined as an axis extending between the second and first stacking members. In other examples, the first axis and therefore the x-axis is defined as an axis parallel to an edge of the printed substrates once received in the first stack <NUM>. For example, in <FIG>, the x-axis is aligned with the length dimension of the substrates <NUM>.

Similarly, a second axis may also be defined that is perpendicular to the first axis. For example, the second axis may be the y-axis shown depicted in <FIG>. In <FIG>, the y-axis extends out of the page. Movement in along the second axis includes any motion substantially parallel to the y-axis and includes both forwards and backwards motion along the y-axis. In some examples, the second axis and therefore the y-axis is defined as being parallel to the direction in which the plurality of printed substrates <NUM> are received from the printer. In other examples, the second axis and therefore the y-axis is defined as a direction parallel to a longitudinal axis of the first and second stacking members. In other examples, the second axis and therefore the y-axis is defined as a direction parallel to an edge of the printed substrates once received in the first stack <NUM>. For example, in <FIG>, the y-axis is aligned with the width dimension of the substrates <NUM>.

After the first stack <NUM> has been deposited onto the second stack <NUM>, the vertical position of the new stack can be adjusted so that another stack can be received. As mentioned, the second stack may be stacked within a receptacle <NUM>. The receptacle may be a container, or a platform for example. The vertical position of the receptacle may be altered by the actuator <NUM>. For example, the controller may cause the position of the receptacle to be adjusted by instructing the actuator <NUM> to move the receptacle <NUM>. The controller is therefore configured to adjust a position of the receptacle <NUM> in the vertical direction, along a vertical axis, such that the second stack <NUM> of printed substrates is positioned to partially support the first stack <NUM> of printed substrates while the stacking member is in the first position. Hence, the vertical position of the receptacle <NUM>, and the second stack <NUM> can be adjusted so that it is at the correct height to receive, and partially support the first stack <NUM>. In one example, the vertical axis may be defined as being perpendicular to both the first and second axes, and therefore perpendicular to both the x-axis and the y-axis. Movement along the vertical axis can mean both upwards motion and downwards motion, for example.

As mentioned, a controller, such as controller <NUM>, may cause the stacking members <NUM>, <NUM> to disengage from the first stack <NUM>. For example, the controller may instruct the actuators to adjust the position of the stacking members <NUM>, <NUM>. This disengagement may be caused to occur when the first stack <NUM> of substrates satisfies a criterion. For example, the controller may be continuously or periodically monitoring at least one of: (i) a count/quantity of the plurality of printed substrates within the first stack <NUM>, (ii) a height dimension of the plurality of printed substrates within the first stack <NUM> or (iii) a total mass of the plurality of printed substrates within the first stack <NUM>. Hence, the controller may determine that the criterion is satisfied when at least one of: (i) the count of the plurality of printed substrates within the first stack <NUM> reaches a predetermined threshold count, (ii) the height dimension of the plurality of printed substrates within the first stack <NUM> reaches a predetermined threshold height or (iii) the mass of the plurality of printed substrates within the first stack <NUM> reaches a predetermined threshold mass.

In some examples these parameters are calculated or inferred. For example the current height of the stack <NUM> may be calculated by multiplying the number of substrates in the stack <NUM> by a predetermined thickness dimension of a single substrate. Similarly, the current mass of the stack <NUM> may be calculated by multiplying the number of substrates in the stack <NUM> by a predetermined mass of a single substrate. The number of substrates in the stack <NUM> may be measured by a sensor, estimated based on the period of time elapsed if the printing speed is known, or determined based on information received from the printing system. In other examples height or mass of the stack <NUM> may be measured using one or more sensors, such as optical sensor to measure the height or a weight sensor to measure a force applied by the stack on a stacking member. Once the threshold has been reached, the criterion is satisfied, and the controller instructs the first and second stacking members to disengage. Any "noise" present in the first stack, for example caused by vertical misalignment, can be reduced by beginning a new stack, for example the size of a first stack may be smaller than the second stack. Vertical misalignment may be as a result of one or more warped substrates or folded corners of one or more substrates, for example.

In some examples one or more of the first and second stacking members <NUM>, <NUM> may comprise upright members against which an edge of the substrates can engage. For example, as best depicted in <FIG>, the first stacking member <NUM> may comprise a first upright member <NUM>, and the second stacking member <NUM> may comprise a second upright member <NUM>. The first and second upright members extend generally perpendicular to a flat surface of the stacking member that received the substrate. In this example the first and second upright members <NUM>, <NUM> are integrally formed with the first and second stacking members <NUM>, <NUM> respectively, however, in other examples the first and second upright members <NUM>, <NUM> may be separate from the first and second stacking members <NUM>, <NUM>. In examples where the upright members are components of the stacking members, the stacking members may be said to have an "L-shape" or an "inverted T-shape". In some examples an upright member comprises one or more upright components. Hence, the upright member may not be a continuous upright member. An upright member may be a wall, or an elongate protrusion, for example or a series of spaced protrusions. The upright members <NUM>, <NUM> are positioned adjacent to edges of the first stack of substrates. For example they are positioned along opposite edges parallel to the second axis, and therefore parallel to the transport direction into the stacking system.

In some examples the first and second upright members <NUM>, <NUM> move independently of the first and second stacking members <NUM>, <NUM>. The first and second upright members <NUM>, <NUM> may move relative to the first and second stacking members <NUM>, <NUM>, or movement of the first and second upright members <NUM>, <NUM> may be fixed relative to the first and second stacking members <NUM>, <NUM>.

In the examples of <FIG>, the first and second upright members <NUM>, <NUM> are spaced from each other to receive the plurality of printed substrates therebetween, and are arranged parallel to each other. As shown in <FIG>, the first and second upright members <NUM>, <NUM> are arranged parallel to the second axis, such as parallel to the transport direction <NUM>, and each abut an edge of the first stack <NUM>. In some examples, the first and second upright members <NUM>, <NUM> can be used to align the plurality of printed substrates received between them, so that the edges of the substrates in contact with the first and second upright members <NUM>, <NUM> can be aligned, and thereby meet any stack quality specifications. Aligning the substrates along an axis means that the substrates are aligned within an acceptable limit, such as less than about <NUM>, or about <NUM> between the edge of a substrate forming the outermost point of the stack and a corresponding edge of a substrate forming the innermost point of the stack, for example. Alignment along an axis may mean that the maximum difference in the position of corresponding edges of substrates in the stack in the direction perpendicular to the edge of the substrate less than or equal to the acceptable limit.

The alignment along the first axis can be achieved by repeatedly-moving/vibrating one, or both, of the first and second upright members <NUM>, <NUM> back and forth along the first axis. Hence the substrates within the first stack <NUM> are agitated by the motion.

<FIG> depicts the system <NUM> in which some of the substrates within the first stack <NUM> are misaligned. Region <NUM> shows a number of substrates within the stack <NUM> that are offset relative to the substrate on the top of the stack <NUM>. To align the substrates within the stack along the first axis, one or more of the first and second upright members <NUM>, <NUM> may be caused to vibrate along the first axis, such as perpendicular to the transport direction <NUM>. For example, this may include causing one or more of the first and second stacking members <NUM>, <NUM> to vibrate along the first axis, for example by causing one or more of the actuators <NUM> to move the stacking members. This instruction may be received from a controller, for example. This motion/vibration is indicated by arrows <NUM> and <NUM>, hence vibrating along the first axis includes both forwards and backwards motion parallel to the first axis.

This vibration causes the substrates within the first stack <NUM> to be agitated and move into alignment along the first axis. For example, the plurality of printed substrates within the first stack <NUM> are agitated between the first and second upright members <NUM>, <NUM>. "Agitating" the first stack <NUM> may also be described as vibrating, oscillating or manipulating the first stack.

<FIG> depicts the first stack <NUM> after the vibration has occurred. Region <NUM> shows that the substrates within the first stack have been substantially aligned, and may therefore meet any stack quality specifications, should any be in place. As can be seen in <FIG>, this alignment is performed on the first stack <NUM>, while the substrates are being supported by the first and second stacking members <NUM>, <NUM>. After this alignment has occurred, the stacking members <NUM>, <NUM> can disengage from the first stack <NUM> so that the substrates are stacked on the second stack located underneath. Hence, the first stacking member <NUM> may move away from the first stack <NUM> and from the second stacking member <NUM> in the direction of arrow <NUM>. Similarly, the second stacking member <NUM> may move away from the first stack <NUM> and from the first stacking member <NUM> in the direction of arrow <NUM>.

In addition to the above described motion of the first and second stacking members <NUM>, <NUM>, one or more of the stacking members <NUM>, <NUM> may also move relative to each other along the first axis to accommodate different sized substrates. Hence, in one example, a controller may be configured to adjust a spacing between the first and second stacking members <NUM>, <NUM> based on a size dimension of the printed substrates by causing at least one of the first and second stacking members to move along the first axis. In this example therefore, the size dimension may be a first size dimension measured along the first axis. For example, in <FIG>, the first size dimension is a length dimension, however in other examples, the first size dimension may be a width dimension if the substrates are orientated differently. Here a length dimension is the dimension of the substrate that has the longest length, and a width dimension is the dimension of the substrate that has the shortest length.

As described in relation to <FIG>, one or both of the first and second stacking members <NUM>, <NUM> can be vibrated along the first axis to align the substrates along the first axis. In some instances, the substrates within the first stack <NUM> may also be misaligned along the second axis, such as along an axis parallel to the transport direction. To align the first stack along the second axis, the first stack may also be agitated along the second axis. To achieve this, one or more additional members may be used.

<FIG> depicts a top-down view of another example stacking system <NUM> and <FIG> depicts a side view of the stacking system <NUM>. The stacking system <NUM> may be substantially similar to the stacking system <NUM>, but with additional components. The stacking system <NUM> comprises a first stacking member <NUM> with a first upright member <NUM>, a second stacking member <NUM> with a second upright member <NUM>, and a first stack <NUM> of substrates being supported by the stacking members <NUM>, <NUM>. The positioning of the first and second stacking members <NUM>, <NUM> along the first axis can be adjusted by the actuators <NUM>. In addition to these components, the stacking system <NUM> further comprises a first end member <NUM> and a second end member <NUM>. The first end member <NUM> and second end member <NUM> are spaced from each other and are parallel to each other. The end members are configured to receive a plurality of printed substrates therebetween. The end members each comprise upright components that engage with peripheral edges of the printed substrates within the first stack <NUM>. In this example the end members are aligned parallel to the first axis, and therefore the x-axis, which may be perpendicular to the transport direction <NUM> in some examples. In this example the first end member <NUM> is positioned adjacent to a leading edge of the first stack <NUM>, and the second end member <NUM> is positioned adjacent to a trailing edge of the first stack <NUM>. For example, the leading edge may be defined as the edge of the substrate first received within the stacking system <NUM> in the transport direction indicated by arrow <NUM>. The trailing edge is therefore the opposite edge of the substrate. In other examples the first and second end members are positioned adjacent to first and second edges, respectively.

In the example of <FIG>, the system <NUM> comprises two separate end members <NUM>, <NUM>, however the first and second end members <NUM>, <NUM> may each be two or more end members in other examples.

<FIG> depicts the first and second end members <NUM>, <NUM> arranged perpendicular to the transport direction <NUM>, and are therefore also parallel to an edge of the substrates within the first stack <NUM>. One or more actuators <NUM> allow the positioning of the end members <NUM>, <NUM> to be adjusted. For example, a controller may be configured to adjust the spacing between the first and second end members <NUM>, <NUM> based on a size dimension of the printed substrates, by causing at least one of the first and second end members <NUM>, <NUM> to move along the second axis, and therefore the y-axis, which may be parallel to the transport direction <NUM> in some examples. The size dimension may be a second size dimension measured along the second axis, for example a size dimension measured in a direction along the transport direction <NUM>. In <FIG>, the second size dimension is a width dimension however in other examples, the second size dimension may be a length dimension if the substrates are orientated differently. Here a length dimension is the dimension of the substrate that has the longest length, and a width dimension is the dimension of the substrate that has the shortest length. Accordingly, the spacing between the end members can be adjusted to accommodate different sized substrates.

The positioning of the first and second end members <NUM>, <NUM> may also be adjusted to align the first stack <NUM> along the second axis so that the edges of the substrates in contact with the first and second end members <NUM>, <NUM> can be aligned, and thereby meet any stack quality specifications. The alignment along the second axis can be achieved by repeatedly-moving/vibrating one, or both, of the first and second end members <NUM>, <NUM> along the second axis. Hence the substrates within the first stack <NUM> become agitated as a result of this motion.

<FIG> depicts the system <NUM> in which some of the substrates within the first stack <NUM> are misaligned. Region <NUM> shows a number of substrates within the stack <NUM> that are offset relative to the substrate on the top of the stack <NUM>. To align the substrates within the stack along the second axis, one or both of the first and second end members <NUM>, <NUM> may be caused to vibrate along the second axis, for example back and forth along the transport direction <NUM>. This motion may be achieved by causing one or more of the actuators <NUM> to move the end members. This instruction may be received from a controller, for example. This motion/vibration is indicated by arrows <NUM> and <NUM>, hence vibrating along the second axis includes both forwards and backwards motion parallel to the second axis.

This vibration causes the substrates within the first stack <NUM> to be agitated and align along the second axis. For example, the plurality of printed substrates within the first stack <NUM> are agitated between the first and second end members <NUM>, <NUM>. The alignment along the second axis may occur in addition to the alignment along the first axis. The first and second stacking members <NUM>, <NUM> may remain stationary while the alignment along the second axis occurs. Either of these alignment procedures may be performed first, and in some examples both occur simultaneously such that the first and second stacking members are not stationary.

After the vibration has occurred, the substrates within the first stack <NUM> will be substantially aligned, and may therefore meet any stack quality specifications, should any be in place. As can be seen in <FIG>, this alignment is performed on the first stack <NUM>, while the substrates are being supported by the first and second stacking members <NUM>, <NUM>. After this alignment has occurred, the stacking members <NUM>, <NUM> disengage from the first stack <NUM> so that the substrates are stacked on the second stack <NUM> located on a receptacle <NUM> underneath. Hence, the first stacking member <NUM> may move away from the first stack <NUM> and from the second stacking member <NUM> in the direction of arrow <NUM>, such as transverse to the transport direction <NUM>. Similarly, the second stacking member <NUM> may move away from the first stack <NUM> and from the first stacking member <NUM> in the direction of arrow <NUM>, such as transverse to the transport direction <NUM> in the opposite direction to the first stacking member.

The above discussion therefore describes how a first stacking scheme can be realised using the example stacking system. <FIG> depicts a perspective view of an example stack of substrates. The first stacking scheme may specify a stack quality specification, that may need to be adhered to. The stack quality specification may specify that the maximum offset between substrates in a stack along any axis is no greater than a predetermined measurement value, such as about <NUM>, <NUM>, or <NUM> for example. <FIG> shows the maximum offset measured along the first axis <NUM>, and the maximum offset measured along the second axis <NUM>. Hence, to avoid the substrates within the first stack <NUM>, <NUM> being offset by a value greater than this, the substrates may be aligned along both the first and second axes according to the procedures described above.

A second stacking scheme may specify how substrates of different sizes/dimensions are stacked on top of each other. <FIG> depicts a perspective view of three stacks of substrates. Substrates within a first batch <NUM>, <NUM>, <NUM> may be of the same size, whereas second subsequent batches <NUM>, <NUM>, <NUM> may be of a different size to the first batches. As is shown, the first and second batches may be aligned along any edge of the substrates, such as the trailing edge <NUM>.

To position a second batch relative to a first batch, the example stacking system can move and/or position substrates being stacked by using one or more of the stacking members and/or one or more of the end members.

In a first example, to offset the second batch <NUM> from the first batch <NUM> as shown, the first stack of substrates being received on the first and second stacking members can be positioned relative to the second stack. This can be achieved by causing the position of the first end member to be adjusted along the second axis, such as in a direction parallel to the transport direction. For example, with reference to <FIG>, the first end member <NUM> may move inwards and towards the second end member <NUM>, whereas the second end member <NUM> may remain stationary. Accordingly, the substrates within the first stack <NUM> may be aligned along the trailing edge of the stack. This motion can be performed before the first stack is created, or once the first stack has been created.

In a second example, to offset the second batch <NUM> from the first batch <NUM> as shown, the first stack of substrates being received on the first and second stacking members can be positioned relative to the second stack. This can be achieved by causing the position of both first and second stacking members to be adjusted along the first axis. For example, with reference to <FIG>, both first and second stacking members <NUM>, <NUM> may move inwards and towards each other, perpendicular to the transport direction, whereas the first and second end members <NUM>, <NUM> may remain stationary. Because the substrates within both batches have the same width dimension, the end members <NUM>, <NUM> may not need to adjust their position. Accordingly, the substrates within the first stack <NUM> may be aligned along the trailing edge of the stack. Again, this motion can be performed before the first stack is created, or once the first stack has been created.

In a third example, to offset the second batch <NUM> from the first batch <NUM> as shown, the first stack of substrates being received on the first and second stacking members can be positioned relative to the second stack. This can be achieved by causing the position of both first and second stacking members to be adjusted along the first axis, and by causing the position of the first end member to be adjusted along the second axis. For example, with reference to <FIG>, both first and second stacking members <NUM>, <NUM> may move inwards and towards each other, perpendicular to the transport direction, and the first end member <NUM> may move inwards and towards the second end member <NUM>, whereas the second end member <NUM> may remain stationary. In this example the substrates in the second batch have different length and width dimensions to the substrates in the first batch. By keeping the second end member <NUM> stationary, the batches can be aligned along their trailing edge. Again, this motion can be performed before the first stack is created, or once the first stack has been created.

A third stacking scheme may specify how batches of substrates are distinguished from other batches. Offsetting, which may also be known as "jog-offsetting" is a process whereby batches or print-jobs are laterally offset or displaced from each other. This allows each batch to be easily identifiable from other batches. <FIG> depicts a stack of substrates within which batches have been laterally offset from adjacent batches. A first batch <NUM> is shown offset from a second batch <NUM>, where the second batch <NUM> is located beneath the first batch <NUM>. Although <FIG> depicts the batches being offset along the first axis, such as perpendicular to a transport direction, it will be appreciated that the batches may be offset along the second axis, such as parallel to the transport direction.

To offset a second batch relative to a first batch, the example stacking system can move and/or position substrates being stacked by using one or more of the stacking members and/or one or more of the end members. For example, to offset the first batch <NUM> from the second batch <NUM>, the first stack of substrates being received on the first and second stacking members can be positioned relative to the second stack. This can be achieved by causing the position of one or both of the first and second stacking members to be adjusted along the first axis. For example, one or both of the first and second stacking members may move together in the same direction along the first axis, whereas the first and second end members may remain stationary. This motion can be performed before the first stack is created, or once the first stack has been created.

<FIG> depicts the example system <NUM> being controlled to create an offset. In this configuration, the first stacking member <NUM> (and therefore the first upright member <NUM>) has already been moved along the first axis, in a direction indicated by arrow <NUM>, such as perpendicular to a transport direction. Similarly, the second stacking member <NUM> (and therefore the second upright member <NUM>) has already been moved along the first axis, in a direction indicated by arrow <NUM>, such as perpendicular to a transport direction. The first stack <NUM>, which may make up a component of the first batch <NUM>, is therefore offset with respect to the second stack <NUM>. Once in position, the first stack can be deposited onto the second stack to achieve the offset, as depicted in <FIG>. This can be achieved by a controller being configured to adjust a position of at least one of the first and second stacking members along a first axis to offset the first stack from the second stack along the first axis. It will be appreciated that the first and second upright members may not need to be present to achieve this offset. The lateral position of the stack can be adjusted regardless of the presence of the upright members. Hence, in some examples, the first and second upright members are absent.

To achieve an offset along the second axis, such as in a direction parallel to a transport direction, the controller may be configured to adjust a position of at least one of the first and second end members <NUM>, <NUM> along the second axis to offset the first stack from the second stack along the second axis.

<FIG> is a flow diagram showing a method <NUM>. The method can be performed by the example systems <NUM>, <NUM>. At block <NUM> the method comprises sequentially receiving a plurality of printed substrates. At block <NUM> the method comprises stacking the plurality of printed substrates on a stacking member to create a first stack, the plurality of printed substrates partially supported by the stacking member. At block <NUM> the method comprises determining that the first stack satisfies a criterion. At block <NUM> the method comprises, responsive to determining that the criterion is satisfied, disengaging the stacking member from the first stack, thereby depositing the plurality of printed substrates on to a second stack, the second stack comprising previously stacked printed substrates.

The stacking member is a first stacking member, and the method further comprises stacking the plurality of printed substrates on the first stacking member and a second stacking member to create the first stack, the plurality of printed substrates partially supported by the first and second stacking members; and responsive to determining that the criterion is satisfied, disengaging the first stacking member and the second stacking member from the first stack.

In some example methods, the method may further comprise agitating the first stack to align the plurality of printed substrates. In some examples this comprise one or both of (i) agitating the first stack along a first axis to align the plurality of printed substrates along the first axis; and (ii) agitating the first stack along a second axis perpendicular to the first axis to align the plurality of printed substrates along the second axis.

In some example methods, agitating the first stack comprises at least one of: (i) vibrating one or more of the first and second stacking members along a first axis to align the plurality of substrates along the first axis; and (ii) vibrating one or more of a first end member and a second end member along a second axis perpendicular to the first axis to align the plurality of substrates along the second axis.

In some example methods, agitating the first stack along the first axis comprises: vibrating at least one of the first and second stacking members along the first axis; and agitating the plurality of printed substrates between first and second upright members arranged parallel to the second axis, the first and second upright members being spaced from and parallel to each other. Agitating the first stack along the second axis may comprise: keeping the first and second stacking members stationary; vibrating at least one of a first end member and a second end member along the second axis; and agitating the plurality of printed substrates between the first and second end members, the first and second end members being arranged parallel to the first axis, and being spaced from and parallel to each other.

According to the invention, the method further comprises partially supporting the first stack by the second stack. This is performed during stacking the plurality of printed substrates on a stacking member to create the first stack.

In some example methods, the method may further comprise offsetting the first stack from the second stack along a first axis by adjusting a position of at least one of the first and second stacking members along the first axis.

In some example methods, the method may further comprise offsetting the first stack from the second stack along a second axis by adjusting a position of at least one of a first end member and a second end member along the second axis, the first and second end members being spaced from and parallel to each other.

In some example methods, the method comprises monitoring at least one of: (i) a count of the plurality of printed substrates, and the criterion is satisfied when the count of the plurality of printed substrates reaches a predetermined threshold count; (ii) a height dimension of the plurality of printed substrates, and the criterion is satisfied when the height dimension of the plurality of printed substrates reaches a predetermined threshold height; and (iii) a mass of the plurality of printed substrates, and the criterion is satisfied when the mass of the plurality of printed substrates reaches a predetermined threshold mass.

Certain system components and methods described herein may be implemented by way of non-transitory computer program code that is storable on a non-transitory storage medium. In some examples, the controller <NUM> may comprise a non-transitory computer readable storage medium comprising a set of computer-readable instructions stored thereon. The controller <NUM> may further comprise one or more processors <NUM>. In some examples, control may be split or distributed between two or more controllers <NUM> which implement all or parts of the methods described herein.

<FIG> shows an example of such a non-transitory computer-readable storage medium <NUM> comprising a set of computer readable instructions <NUM> which, when executed by at least one processor <NUM>, cause the processor(s) <NUM> to perform a method according to examples described herein. The computer readable instructions <NUM> may be retrieved from a machine-readable media, e.g. any media that can contain, store, or maintain programs and data for use by or in connection with an instruction execution system. In this case, machine-readable media can comprise any one of many physical media such as, for example, electronic, magnetic, optical, electromagnetic, or semiconductor media. More specific examples of suitable machine-readable media include, but are not limited to, a hard drive, a random access memory (RAM), a read-only memory (ROM), an erasable programmable read-only memory, or a portable disc.

Claim 1:
A method (<NUM>) of stacking printed substrates (<NUM>, <NUM>), the method comprising:
sequentially receiving (<NUM>) a plurality of printed substrates;
stacking (<NUM>) the plurality of printed substrates on a first stacking member (<NUM>, <NUM>) and a second stacking member (<NUM>, <NUM>) to create a first stack (<NUM>, <NUM>), the plurality of printed substrates partially supported by the first and the second stacking members and partially supported by a second stack (<NUM>, <NUM>), the second stack comprising previously stacked printed substates;
determining (<NUM>) that the first stack satisfies a criterion; and
responsive to determining that the criterion is satisfied, disengaging (<NUM>) the first stacking member and the second stacking member from the first stack, thereby depositing the plurality of printed substrates on to the second stack.