Fluid ejection devices typically include a number of fluid chambers, or firing chambers, which are arranged in columns, with each column being disposed along a fluid slot, and with each fluid chamber being in fluid communication with and receiving fluid from the fluid slot via fluid passages. Typically, fluid chambers are one of two types, referred to generally as ejection chambers or non-ejection chambers. Ejection chambers, also referred to as “drop generators” or simply as “nozzles”, include a nozzle and a fluid ejector, such as a firing resistor, that, when energized, causes a drop of fluid to be ejected from the nozzle. Non-ejection chambers, also referred to as “recirculating pumps” or simply as “pumps”, also include a fluid ejector, but do not include a nozzle. When energized, the fluid ejector pumps or recirculates fluid through corresponding fluid passages from the fluid slot to keep associated nozzles supplied with fresh fluid. In some instances, there is a 1-to-1 relationship between nozzles and pumps (i.e., one pump associated with each nozzle).
In the following detailed description, reference is made to the accompanying drawings which form a part hereof, and in which is shown by way of illustration specific examples in which the disclosure may be practiced. It is to be understood that other examples may be utilized and structural or logical changes may be made without departing from the scope of the present disclosure. The following detailed description, therefore, is not to be taken in a limiting sense, and the scope of the present disclosure is defined by the appended claims. It is to be understood that features of the various examples described herein may be combined, in part or whole, with each other, unless specifically noted otherwise.
Fluid ejection devices typically include a number of fluid chambers, often arranged in columns, with each column being disposed along a fluid slot, and with each fluid chamber being in fluid communication with and receiving fluid from the fluid slot via fluid passages. Typically, fluid chambers are one of two types, referred to generally as ejection chambers and non-ejection chambers. Ejection chambers, also referred to as “drop generators” or simply as “nozzles”, include a nozzle and a fluid ejector, such as a firing resistor, for example, that, when energized, causes a drop of fluid to be ejected from the fluid chamber through the nozzle. Non-ejection chambers, also referred to as “recirculating pumps” or simply as “pumps”, also include a fluid ejector, but do not include a nozzle. When energized, the fluid ejector pumps or recirculates fluid through corresponding fluid passages from the fluid slot to keep nozzles supplied with fresh fluid. In some instances, there is a 1-to-1 relationship between nozzles and pumps (i.e., one pump associated with each nozzle).
Fluid ejection devices are typically maintained at a minimum or default temperature during operation (for example, at 55° C.). If a nozzle has been inactive for a predetermined time prior to ejecting fluid (e.g., ink), the pump (or pumps) associated with the nozzle is energized to recirculate fresh fluid to the nozzle prior to ejecting fluid. In some cases a pump may be “pumped” (e.g., a firing resistor is energized) up to 1,000 times prior to the nozzle ejecting fluid. Such pumping causes the fluid and adjacent portions of the fluid ejection device to increase in temperature.
If a group or zone of physically adjacent pumps are simultaneously pumping in preparation for ejection of fluid by associated nozzles, the given zone of heavy fluid recirculation of the column of fluid chambers will become elevated in temperature relative to other regions of the column. As a result of these thermal gradients, nozzles in the zone of heavy recirculation will eject larger fluid drops (i.e., having a larger volume) than nozzles in cooler zones of the column that are ejecting fluid without recirculation (e.g., a zone of nozzles that was previously recirculated and has been cooled by the ejection of fluid drops). In a case where the fluid ejection device is implemented as inkjet printhead, the difference in ink drop sizes being ejected from different zones of the column will produce an undesirable striping or banding effect in a printed image, with areas of the images produced by the warmer zones of the column of nozzles being darker than those produced by cooler zones of the column of nozzles.
Input logic 180 receives a series 231 of fire pulse groups (FPGs) 232, with each FPG 232 including warming data 242 having an enable value or a disable value and a series 236 of ejection or firing bits 244, each firing bit 244 corresponding to a different on the of the primitives P1 to PM and each having an ejecting or firing value (e.g., a value of “1”) and a non-ejecting or non-firing value (e.g., a value of “0”).
For each firing bit 244 of each FPG 232, when the warming data 242 has the enable value (e.g., a value of “1”), activation logic 210 provides a warming pulse 194 (see also
As will be described in greater detail below, by warming non-circulating pumps and/or non-ejecting fluid chambers 150 via warming data included in FPGs, in accordance with the present disclosure, thermal gradients across primitives 164 of fluid ejection device 114 are reduced and/or eliminated, thereby reducing variations in the volume of fluid drops ejected by fluid chambers 150. In a case where fluid ejection device 114 is implemented as an inkjet printhead 114, reducing or eliminating thermal gradients across inkjet printhead 114 reduces or eliminates banding in printed images.
In addition to fluid ejection assembly 102 and fluid ejection device 114, fluid ejection system 100 includes a fluid supply assembly 104 including fluid storage reservoir 107, a mounting assembly 106, a media transport assembly 108, an electronic controller 110, and at least one power supply 112 that provides power to the various electrical components of fluid ejection system 100.
Fluid ejection assembly 114, in accordance with the present disclosure, includes input logic 180 and activation logic 210, such as described above with reference to
While broadly described herein with regard to a fluid ejection system 100 employing a fluid ejection device 114, fluid ejection system 100 may be implemented as a drop-on-demand thermal inkjet printing system with inkjet printhead 114 being a thermal inkjet (TIJ) printhead 114, wherein a warming system and the inclusion of warming operations data together with energization data, according to the present disclosure, can be implemented in other printhead types as well, such wide array of TIJ printheads 114 and piezoelectric type printheads, for example. Furthermore, the warming system and inclusion of warming operations data together with energization data, in accordance with the present disclosure, is not limited to inkjet printing devices, but may be applied to any digital dispensing device, including 2D and 3D printheads (forming 3D articles), for example.
In operation, fluid typically flows from reservoir 107 to fluid ejection assembly 102, with fluid supply assembly 104 and fluid ejection assembly 102 forming either a one-way fluid delivery system or a recirculating fluid delivery system. In a one-way fluid delivery system, all of the fluid supplied to fluid ejection assembly 102 is consumed during fluid ejecting operations. However, in a recirculating fluid delivery system, only a portion of the fluid supplied to fluid ejection assembly 102 is consumed during fluid ejection operation, with fluid not consumed during fluid ejecting operation being returned to supply assembly 104. Reservoir 107 may be removed, replaced, and/or refilled.
In one example, fluid supply assembly 104 supplies fluid under positive pressure through a fluid conditioning assembly 11 to fluid ejection assembly 102 via an interface connection, such as a supply tube. Fluid supply assembly 104 includes, for example, a reservoir, pumps, and pressure regulators. Conditioning in the fluid conditioning assembly may include filtering, pre-heating, pressure surge absorption, and degassing, for example. Fluid is drawn under negative pressure from fluid ejection assembly 102 to the fluid supply assembly 104. The pressure difference between an inlet and an outlet to fluid ejection assembly 102 is selected to achieve correct backpressure at nozzles 116.
Mounting assembly 106 positions fluid ejection assembly 102 relative to media transport assembly 108, and media transport assembly 108 positions media 118 relative to fluid ejection assembly 102, so that an ejection zone 122 is defined adjacent to nozzles 116 in an area between fluid ejection assembly 102 and media 118. In one example, fluid ejection assembly 114 is implemented as an inkjet printhead assembly 102 and is a scanning type printhead assembly. According to such example, mounting assembly 106 includes a carriage for moving inkjet printhead assembly 102 relative to media transport assembly 108 to scan printhead 114 across media 118. In another example, inkjet printhead assembly 102 is a non-scanning type printhead assembly. According to such example, mounting assembly 106 maintains inkjet printhead assembly 102 at a fixed position relative to media transport assembly 108, with media transport assembly 108 positioning media 118 relative to inkjet printhead assembly 102.
Electronic controller 110 includes a processor (CPU) 138, a memory 140, firmware, software, and other electronics for communicating with and controlling fluid ejection assembly 102, mounting assembly 106, and media transport assembly 108. Memory 140 can include volatile (e.g. RAM) and nonvolatile (e.g. ROM, hard disk, floppy disk, CD-ROM, etc.) memory components including computer/processor readable media that provide for storage of computer/processor executable coded instructions, data structures, program modules, and other data for fluid ejection system 100.
In one example, electronic controller 110 receives data 124 from a host system, such as a computer, and temporarily stores data 124 in a memory. Typically, data 124 is sent to fluid ejection system 100 along an electronic, infrared, optical, or other information transfer path. In one example, when fluid ejection system 100 is implemented as an inkjet printing system 102, data 124 represents, for example, a document and/or file to be printed, where data 124 forms a print job for inkjet printing system 100 and includes one or more print job commands and/or command parameters.
In one implementation, electronic controller 110 controls fluid ejection assembly 102 for ejection of fluid drops from nozzles 116 of fluid ejection devices 114. Electronic controller 110 defines a pattern of ejected fluid drops to be ejected from nozzles 116, and which together, in a case when implemented as an inkjet printing system 100, form characters, symbols, and/or other graphics or images on print media 118 based on the print job commands and/or command parameters from data 124.
In one example of the present disclosure, as will be described in greater detail below, electronic controller 114 provides energization or firing data to fluid ejection assembly 102 in the form of a series of nozzle column groups (NCGs), with each NCG including a series of fire pulse groups (FPGs), and each FPG including ejection or firing data which controls the fluid ejectors (e.g., firing resistors) of pumping chambers and of nozzles 114 to eject a defined pattern of fluid drops. According to one example, as will be described in greater detail below, the PCGs include warming data to direct warming of fluid ejection assembly 102 in accordance with the present disclosure.
In one example, fluid chambers 150 of each column 152 are grouped to form a plurality of primitives 164, illustrated at primitives P1 to PM, with each primitive 164 receiving a same set of addresses 166, illustrated as addresses A1 to AN, with each fluid chamber 150 of each primitive 164 corresponding to one address of the set of addresses 166. In one example, each primitive 164 has a same number of pumps 156 as nozzles 158 (i.e., a 1-to-1 ratio), with pumps 156 corresponding to odd-numbered addresses (e.g., A1, A3 . . . AN−1) and nozzle corresponding to even-number addresses (e.g., A2, A4 . . . AN). In other examples, pumps 156 and nozzles 158 have a ratio other than 1-to-1 and are not assigned to odd and even addresses. Although each primitive is illustrated as having a same number, N, of fluid chambers 150, it is noted that the number of fluid chambers 150 can vary from primitive to primitive.
In one example, each column 162 has at least one corresponding temperature sensing element 168. In one case, temperature sensing element 168 extends the length of the column and provides an average temperature of the column 162 of fluid chambers 150. In one instance, sensing element 168 is a thermal resistor.
Fluid ejection device 114 includes a column of fluid chambers 150 grouped to form a number of primitives 162, illustrated as primitives P1 to PM. Each primitive includes a number of fluid chambers 150, including a number pumps 156 and a number of nozzles 158, with each pump 156 and nozzle 158 including a firing mechanism 160. In one case, firing mechanism 160 is a thermal firing mechanism, such as a firing resistor 160, for example. In the illustrated example, each primitive has same set of addresses 166, illustrated as addresses A1 to AN, with each fluid chamber 150 of each primitive corresponding to a different one of the addresses of the set of addresses.
Fluid ejection device 114 includes input logic 180 having an address encoder 182 which encodes addresses of the set of addresses 166 on an addresses bus 184, and a data buffer 184 which places energization data for firing mechanisms 160 received from electronic controller 110 in the form of NCGs (nozzle column groups and FPGs (fire pulse groups), see
A pulse generator 190 generates a fire pulse on a fire pulse line 192 and a warming pulse on a warming pulse line 194. As described below, a fire pulse causes a selected firing mechanism 160 to be energized for a duration that causes a fluid drop being ejected in the case of a nozzle 158 and fluid to be circulated in the case of a pump 156 (i.e., enables a drive bubble to form and collapse). In contrast, a warming pulse causes a selected fluid ejector to be energized for a duration that enables the fluid ejector (e.g., a firing resistor) to heat the corresponding fluid chamber, but without causing a fluid drop to be ejected in the case of a nozzle 158 or fluid to be circulated in the case of pump 156.
A warming controller 200 includes a temperature sensor 202 which is in electrical communication with temperature sensing element 168 corresponding to the column of fluid chambers 162. In one example, as described above, temperature sensing element 168 is a thermal resistor 168 extending a length of the column of fluid chambers 262. In one example, temperature sensor 202 provides a fixed current to temperature sensing element 168 and monitors a resulting voltage level to determine a current temperature 204 of the column of fluid chambers 162. In one example, as illustrated, the temperature represents an average temperature of the column of fluid chambers 162. In one example, temperature sensor 202 stores the current temperature 204 in a memory or register. In one example, as will be described in greater detail below, warming controller 200 further includes a default temperature setpoint 206 and a warming temperature setpoint 208. According to one example, as will be described in greater detail below, warming controller 200 provides a warming enable signal via a warming enable line 212.
Fluid ejection device 114 further includes activation logic 210 for energizing firing mechanisms 160 of the nozzles 158 and pumps 156 of the column of fluid chambers 162 based on address data on address bus 184, on firing data on the plurality of data lines D1 to DM, and on a state of the warming enable signal on warming signal line 212. In the illustrated example, each fluid chamber 150 of each primitive (i.e., pumps 156, nozzles 156) includes a firing resistor (illustrated as firing resistor 160-1 to 160-N) coupled between a power line 214 and a ground line 216 via a controllable switch 218, such as a field effect transistor (illustrated as FETs 218-1 to 218-N). Additionally, for each primitive P1 to PM, each pump 156 and nozzle 158 includes an address decoder 220 for the corresponding address (illustrated as address decoders 220-1 to 220-N), a multiplexer (MUX) 222 (illustrated as multiplexers 222-1 to 222-N), and an AND-gate 224 (illustrated as AND-gates 224-1 to 224-N).
For each pump 156 and nozzle 158, the corresponding address encoder 220 is coupled to address bus 184, with fire pulse line 192 and warming pulse line 194 being inputs to multiplexer 222, and with the corresponding data line 188 and warming enable line 212 being control inputs to multiplexer 222. The output of multiplexer 222 and the output of address decoder 220 serve as inputs to AND-gate 224, with the output of AND-gate 224 being connected to and controlling the gate of control switch 218.
In operation, according to one example, electronic controller 110 receives data 124 for an ejection job from a host (e.g., a computer), the data being representative of a desired image to be printed (e.g., a document or graphic). In one example, based on data 124, electronic controller 110 provides energization or firing data to fluid ejection device 114 in the form of a series NCGs (nozzle column groups) which cause the firing mechanisms of pumps 156 and nozzles 158 to function to eject a pattern of fluid drops to form the desired image (such as on a print media, for example). In one another case, electronic controller 110 receives the series of NCGs from the host device.
In one example, firing data portion 236 includes a series of firing bits 244, where each firing bit 244 corresponds to a different one of the primitives P1 to PM such that each firing bit 244 of the series of fire bits corresponds to a fluid chamber 150 at the address represented by address bits 240 in a different one of the primitives P1 to PM. In one example, each firing bit 244 has a firing value (e.g., a value of “1”) or a non-firing value (e.g., a value of “0”). As described in greater detail below, a firing bit 244 having a value of “1” causes the firing resistor 160 at the corresponding address in the corresponding primitive to be energized or “fired” to eject a fluid drop in the case of a nozzle 158 or fluid being recirculated in the case of a pump 156, while a value of “0” results in no energization of firing resistors.
Returning to
If the sum of current temperature 204 and offset temperature value 174 is less than the maximum temperature setpoint 172, warming monitor 170 analyzes the value of each firing bit 244 of each FPG 232 of each NCG 230 of the series NCGs 228 which corresponds to a pump 156 to determine a firing profile for each pump 156 (i.e., when the pumps will be pumping) for the given ejection job. In one example, based on such firing profiles, warming monitor 170 identifies pending zones of heavy recirculation of the column of fluid chambers 162 that will become elevated in temperature relative to other zones of the column of fluid chambers 162 during the ejection job and which will undesirably result in the ejection of fluid drops of different sizes.
According to one example, when generating FPGs 232 for an ejection job, a nozzle 158 is identified as requiring pumping by an associated pump 156 if the nozzle has been idle (i.e., has not ejected fluid) for a specified time period (e.g. 1 second), and if the nozzle is to eject fluid based on ejection data corresponding to the nozzle. When a nozzle 158 is identified as requiring pumping, firing bits for pump(s) 156 associated with the identified nozzle(s) 158 are set with the fire enable value (e.g., a value of “1”) so that the pump(s) 156 are “pumped” a predetermined number of times prior to when the associated nozzle 158 is to be fired to eject fluid drops. In one example, the pump(s) 156 are pumped a predetermined number of times, such as in a range from 100 to 1,000 times, for instance. In one example, a pump 156 is pumped 500 times, for instance.
In one example, warming monitor 170 defines a region of heavy recirculation as being a predetermined portion of the column of nozzles 162 (say ¼th of the column of fluid chambers 162, for example) where at least a predetermined percentage of pumps 156 in the predetermined portion (say 50% of pumps 156, for example) will be simultaneously pumping for a predetermined duration (say 500 consecutive NCGs 230, or 5 mS, for example). In one example, the predetermined portion of the column of nozzles 162 may be a number of physically adjacent primitives, such as three consecutive primitives, for instance. In one example, the predetermined portion of the column of nozzles 162 is a “sliding window” of a certain dimension, such as a sliding window having a width of ¼th a length of the column of nozzles 162, so that a pending zone of heavy recirculation may be any group of physically adjacent pumps 156 along the length of the column of nozzles 162. In one example, the sliding windows has a width equal to a number of primitives, such as 3 primitives for example, so that an identified pending zone of heavy recirculation may be any group of 3 consecutive primitives, for instance.
In one example, when warming monitor 170 identifies a pending zone of heavy recirculation of pumps 156, warming monitor 170 sets warming bit 242 to the enable value (e.g., a value of “1”) in selected PCGs 232 of NCGs 230 of the series of NCGs 228.
In one example, warming monitor 170 sets warming bit 242 to the enable value in each PCG 232 of a selected number of consecutive NCGs 230. In one example, the selected number of consecutive NCGs 230 in which warming monitor 170 sets the warming bit coincides with the consecutive NCGs 230 corresponding to the pending zone of heavy recirculation. In one example, the selected number of consecutive NCGs in which warming monitor 170 sets the warming bit is greater than the consecutive number of NCGs 258 of the pending zone of heavy recirculation and precedes and overlaps the NCGs 230 of the pending zone of heavy recirculation in the series of NCGs 228.
With reference to
In operation, input logic 180 receives the series of NCGs 228 and for each FPG 232 checks header 234 for the state of warming bit 242. In a first scenario, if warming bit 242 has the enable value (e.g., a value of “1”), input logic 192 provides warming operations data 241 to warming controller 200, such as via a data path 201. In one example, in response to receiving warming operations data at 201, warming controller 200 compares the current temperature 204 of the column of fluid chambers 162 to the warming setpoint temperature 208. In one example, when current temperature 204 is less than setpoint temperature 208 and at least equal to default temperature 206, warming controller 200 sets warming enable signal 212 to the enable value (e.g., a value of “1”). In contrast, when current temperature 204 is greater than setpoint temperature 208, warming controller 200 sets warming enable signal 212 to the disable value (e.g., a value of “0”). In one example, when warming operations data is not present at 201, warming controller 170 maintains warming signal 212 at the disable value.
Continuing with the above scenario, for each FPG 232, input logic 192 provides the address data associated with the FPG, such as address data 240 in header portion 234, to address encoder 182 which encodes the corresponding address onto address bus 184, and provides the firing bits 244 of firing data portion 236 to data buffer 186 which places each of the firing bits 244 onto its corresponding data line D1 to DM as indicated at 188.
The encoded address on address bus 184 is provided to each address decoder 220-1 to 220-N of each primitive P1 to PM, with each of the address decoders corresponding to the encoded address on address bus 184 providing an active output to the corresponding AND-gate 224. For example, if the encoded address from FPG 232 corresponds to address A1, address decoders 220-1 of each primitive will provide at active output to corresponding AND-gate 224-1.
Multiplexers 222-1 to 222-N of each primitive P1 to PM receive as inputs the fire pulse 192 and the warming pulse 194, and as control or select inputs warming enable signal 212 and the fire bit 244 on the corresponding one of the data lines D1 to DM. In one example, if firing data on the corresponding data line 188 has a firing value (e.g., has a value of “1”), multiplexer 222 outputs fire pulse 192 to the corresponding AND-gate 224 if the warming enable signal has either the enable value (e.g., a value of “1”) or the disable value (e.g., a value of “0”). In one example, if firing data on the corresponding data line 188 has a non-firing value (e.g., has a value of “0”), multiplexer 222 outputs warming pulse 194 to the corresponding AND-gate 224 if the warming enable signal has the enable value (e.g., a value of “1”) and provides no output to the corresponding AND-gate 224 if the warming enable signal has the disable value (e.g. a value of “0”).
In the above example, pulse generator 190 is described as providing separate fire pulse and warmings pulse signals 192 and 194 which are selected by multiplexers 222 based on selection inputs thereto (e.g. data input and warming enable signal).
In another example, as illustrated by
Returning to
In the above scenario, for each FPG 232 of each NCG 230 of the series of NCGs 228 for an ejection job, when warming bit 242 has an enable value (e.g., a value of “1”), a fire pulse 192 will be provided to each firing resistor 160 when the corresponding address is present on address bus 184 and when the firing bit 244 on the corresponding data line 188 has a firing value (e.g., a value of “1”), and a warming pulse 194 will be provided to each firing resistor 160 when the corresponding address is present on address bus 184, when the firing bit 244 on the corresponding data line 188 has a non-firing value (e.g. a value of “0”), and current temperature 204 of the column of fluid chambers 162 is less than warming setpoint temperature 208. It is noted that, regardless of the value of warming bit 242, when the firing bit 244 on the corresponding data line 188 has a firing value (e.g., a value of “1”), fire pulse 192 will be provided to the firing resistor 160.
In one example, warming pulse 194 will be provided to each such firing resistor 160 until current temperature 204 reaches warming setpoint temperature 208, at which point warming signal 212 will be set to have a disable value (e.g., a value of “0”) and thereby disable warming operations. In one example, warming pulse 194 will be provide to each such firing resistor 160 until current temperature 204 reaches warming setpoint temperature 208 or until the series of FPGs having the warming bit 242 set with the enable value (e.g., a value of “1”) has been processed by fluid ejection device 114.
In one example, both non-circulating pumps 156 and non-firing nozzles 158 receive warming pulse 194 as described above. In such case, while zones of the column of fluid chambers 162 outside of the identified pending zone of heavy recirculation will be warmed to warming set-point temperature 208, non-firing nozzles 158 included within the heavy zone of recirculation will also be warmed, thereby further warming the identified zone of heavy recirculation.
In one example, when a pending zone of heavy recirculation is identified by warming monitor 170, warming monitor 170 sets warming bit 242 to the enable value (e.g., a value of “1”) in only those FPGs 232 having addresses corresponding to pumps 156. For example, with reference to
In other examples, warming monitor 170 may set warming bits 242 to have the enable value in an alternating fashion between odd and even numbered addresses so that warming pulse 194 is alternatingly provided to non-circulating pumps 156 and non-ejecting nozzles 158 in order to more even out energy provided to such pumps and nozzles. Any number of scenarios may be employed depending on the arrangement of the pumps 156 and nozzles 158 on fluid ejection device 114.
With reference to
With reference to
As illustrated, in response to the warming bit being set to the enable value in PCGs with addresses corresponding to pumps 164, warming pulses 194 provided to firing resistors 160 of non-circulating pumps 156 warms zones 3 and 4 to the warming setpoint temperature of 65° C. While warming pulses 194 provided to non-circulating pumps 156 in zones 1 and 2 of heavy recirculation also raises the temperature of such zones, to 66° C., for instance, temperature gradients between zones 1-2 and zones 3-4 are greatly reduced, thereby substantially reducing or eliminating thermal banding in the printed image between such zones. After the ejection job is completed, or after the period of heavy recirculation has been processed, the column of fluid chambers 162 of fluid ejection device 114 are no longer warmed through the use of warming pulses 194 such that column 162 is maintained at default temperature 206 (e.g., 55° C.), such as by other warming means, for example.
Returning to
At 304, method 300 includes receiving series of FPGs, with each FPG corresponding to an address of the set of addresses and including a warming bit having a disable value and a series of firing bits, each firing bit corresponding to a different one of the primitives and having a firing value and a non-firing value, such as the series 230 of FPGs 232 corresponding to one of the addresses A1 to AN, with each FPG 232 including a warming bit 242 and a series of firing bits 244 with each firing bit 244 having a firing value (e.g., a value of “1”) and a non-firing value (e.g., a value of “0”), such as illustrated by
At 306, method 300 includes generating a firing profile for each pump of each primitive based on values of corresponding firing bits of corresponding fire pulse groups, such as warming monitor 170 generating a firing profile for each pump 156 of each primitive P1 to PM based on corresponding firing bits 244 of corresponding fire pulse groups 232 as described by
At 310, method 300 includes setting the warming bit to have an enable value in selected FPGs when a pending zone of heavy recirculation is identified, such as warming monitor 170 setting warming bit 242 of selected FPGs 232 to the enable value (e.g., a value of “1”) when a zone of heavy recirculation is defined as described with respect to
Although specific examples have been illustrated and described herein, a variety of alternate and/or equivalent implementations may be substituted for the specific examples shown and described without departing from the scope of the present disclosure. This application is intended to cover any adaptations or variations of the specific examples discussed herein. Therefore, it is intended that this disclosure be limited only by the claims and the equivalents thereof.
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PCT/US2016/058878 | 10/26/2016 | WO | 00 |
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WO2018/080480 | 5/3/2018 | WO | A |
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